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Category:Report
MONTHYEARML23192A4472023-07-31031 July 2023
Staff Assessment of Updated Seismic Hazards at TVA Sites Following the NRC Process for the Ongoing Assessment of Natural Hazards Information
ML23025A0752023-01-25025 January 2023
American Society of Mechanical Engineers, Section XI, Third 10 Year Inspection Interval, Inservice Inspection, System Pressure Test, Containment Inspection, and Repair and Replacement Programs, Owners Activity Report Cycle .
ML22363A3922022-12-28028 December 2022
Cycle 14 Mellla+ Eigenvalue Tracking Data
CNL-22-090, Request to Use a Later Edition of the American Society of Mechanical Engineers Operation and Maintenance Code and Alternative Requests for the Fifth Inservice Testing Interval2022-12-12012 December 2022
Request to Use a Later Edition of the American Society of Mechanical Engineers Operation and Maintenance Code and Alternative Requests for the Fifth Inservice Testing Interval
CNL-22-100, to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for Browns Ferry Nuclear Plant Units 1, 2, and 3,in Support of Atrium 11 Fuel Use at Browns Ferry (TS-535)2022-12-0909 December 2022
to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for Browns Ferry Nuclear Plant Units 1, 2, and 3,in Support of Atrium 11 Fuel Use at Browns Ferry (TS-535)
CNL-22-066, Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for in Support of Atrium 11 Fuel Use Supplement 3, Response to Request for Additional Information2022-07-18018 July 2022
Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for in Support of Atrium 11 Fuel Use Supplement 3, Response to Request for Additional Information
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Unit 3 Cycle 20 Mellla+ Eigenvalue Tracking Data
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to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 in Support of Atrium 11 Fuel Use
ML21277A1232021-10-0404 October 2021
Submittal of Browns Ferry Unit 2 Reactor Pressure Vessel Vertical Weld Flaw Evaluation
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Enclosufinal Ea/Fonsi for Tva'S Initial and Updated Triennial Decommissioning Funding Plans for Browns Ferry Nuclear Plant ISFSIs
ML21246A2952021-09-29029 September 2021
Memo to File
CNL-20-102, 10 CFR 71.95 Report for 3-60B Casks User2020-12-16016 December 2020
10 CFR 71.95 Report for 3-60B Casks User
ML20255A0002020-09-24024 September 2020
Staff Review of Seismic Probabilistic Risk Assessment Associated with Reevaluated Seismic Hazard Implementation of the Near Term Task Force Recommendation 2.1: Seismic
ML20112F4852020-05-0606 May 2020
Staff Assessment of Flooding Focused Evaluation
CNL-19-074, Extended Power Uprate - Flow Induced Vibration Summary Report2019-09-0404 September 2019
Extended Power Uprate - Flow Induced Vibration Summary Report
CNL-19-004, Tennessee Valley Authority, Browns Ferry Nuclear Plant, Unit 2, Completion of Required Action for NRC Order EA-13-109, Reliable Hardened Containment Vents Capable of Operation Under Severe Accident Conditions2019-06-0707 June 2019
Tennessee Valley Authority, Browns Ferry Nuclear Plant, Unit 2, Completion of Required Action for NRC Order EA-13-109, Reliable Hardened Containment Vents Capable of Operation Under Severe Accident Conditions
CNL-19-041, Extended Power Uprate - Unit 1 Flow Induced Vibration Summary Report2019-04-16016 April 2019
Extended Power Uprate - Unit 1 Flow Induced Vibration Summary Report
CNL-19-032, Proposed Technical Specifications (TS) Change TS-510 - Request for License Amendments - Maximum Extended Load Line Limit Analysis Plus - Supplement 8, Additional Operator Training Information2019-03-13013 March 2019
Proposed Technical Specifications (TS) Change TS-510 - Request for License Amendments - Maximum Extended Load Line Limit Analysis Plus - Supplement 8, Additional Operator Training Information
CNL-18-134, Extended Power Uprate - Replacement Steam Dryer Revised Analysis and Limit Curves Report2018-11-29029 November 2018
Extended Power Uprate - Replacement Steam Dryer Revised Analysis and Limit Curves Report
ML18283B5472018-10-10010 October 2018
Responding to Letter of 11/18/1977 from E. G. Case to G. Williams, Providing Environmental Qualification Information for Electrical Connectors in Reference of IE Bulletins 77-05 & 77-05A
CNL-18-112, Extended Power Uprate - Flow Induced Vibration Summary Report2018-09-13013 September 2018
Extended Power Uprate - Flow Induced Vibration Summary Report
CNL-18-060, Completion of Required Action for NRC Order EA-13-109, Reliable Hardened Containment Vents Capable of Operation Under Severe Accident Conditions2018-05-31031 May 2018
Completion of Required Action for NRC Order EA-13-109, Reliable Hardened Containment Vents Capable of Operation Under Severe Accident Conditions
ML18079B1402018-02-23023 February 2018
Browns Ferry Nuclear Plant, Units 1, 2, and 3: Proposed Technical Specifications (TS) Change TS-510 - Request for License Amendments - Maximum Extended Load Line Limit Analysis Plus
ML17222A3282017-09-0505 September 2017
Flood Hazard Mitigation Strategies Assessment
ML17170A0732017-06-15015 June 2017
Report Pursuant to 10 CFR 71.95 (a)(3) and (B) - Failure to Follow Conditions of TN-RAM Packaging Certificate of Compliance No. 9233
ML17114A3712017-04-20020 April 2017
Errata for BWRVIP-271NP: BWR Vessel and Internals Project, Testing and Evaluation of the Browns Ferry, Unit 2, 120 Degree Capsule
ML17033B1642017-02-0202 February 2017
American Society of Mechanical Engineers Section XI, Inservice Inspection, System Pressure Test, Containment Inservice Inspection, and Repair and Replacement - Cycle 11 Operation Programs
ML17024A0362016-12-31031 December 2016
Operating Data Report for 2016
CNL-16-169, Proposed Technical Specifications (TS) Change TS-505 - Request for License Amendments - Extended Power Uprate (EPU) - Supplement 35, Consolidated Power Uprate Safety Analysis Report Revision2016-10-28028 October 2016
Proposed Technical Specifications (TS) Change TS-505 - Request for License Amendments - Extended Power Uprate (EPU) - Supplement 35, Consolidated Power Uprate Safety Analysis Report Revision
ML16196A0882016-08-0505 August 2016
Staff Assessment of Response to 10 CFR 50.54(f) Information Request - Flood Causing Mechanism Reevaluation
ML16146A0182016-05-25025 May 2016
Special Report 296/2016-001 for Inoperable Post Accident Monitoring (PAM) Instrumentation
ML16028A2952016-01-29029 January 2016
10 CFR 71.95 Notification Associated with the Failure to Observe Certificate of Compliance Condition of the 8-120B Secondary Lid Test Port Configuration
ML16027A0592016-01-27027 January 2016
Snubbers Added to Lnservice Testing Program
ML15356A6542015-12-22022 December 2015
Submittal of 10 CFR 50.46 30-Day Report
CNL-15-056, Application to Modify Technical Specification 2.1.1.2, Reactor Core Minimum Critical Power Ratio Safety Limits (TS-506)2015-09-25025 September 2015
Application to Modify Technical Specification 2.1.1.2, Reactor Core Minimum Critical Power Ratio Safety Limits (TS-506)
NL-15-169, Non-Proprietary - Safety Analysis Report for Browns Ferry, Units 1, 2 and 3, Extended Power Uprate, Attachment 72015-09-21021 September 2015
Non-Proprietary - Safety Analysis Report for Browns Ferry, Units 1, 2 and 3, Extended Power Uprate, Attachment 7
ML15282A2392015-09-21021 September 2015
Flow Induced Vibration Analysis and Monitoring Program
ML15282A2402015-09-21021 September 2015
Startup Test Plan
NL-15-169, Browns Ferry Units 1, 2 and 3, Flow Induced Vibration Analysis and Monitoring Program2015-09-21021 September 2015
Browns Ferry Units 1, 2 and 3, Flow Induced Vibration Analysis and Monitoring Program
ML15282A1812015-09-21021 September 2015
Non-Proprietary - Safety Analysis Report for Browns Ferry, Units 1, 2 and 3, Extended Power Uprate, Attachment 7
NL-15-169, Browns Ferry, Units 1, 2, and 3, Startup Test Plan2015-09-21021 September 2015
Browns Ferry, Units 1, 2, and 3, Startup Test Plan
ML15254A5432015-09-11011 September 2015
Submittal of 10 CFR 72.48 Changes, Tests, and Experiments, Biennial Summary Report Associated with the Independent Spent Fuel Storage Installation
NL-15-169, ANP-3377NP, Browns Ferry Units 1, 2 and 3 LOCA Break Spectrum Analysis Atrium 10XM Fuel (Epu).2015-08-31031 August 2015
ANP-3377NP, Browns Ferry Units 1, 2 and 3 LOCA Break Spectrum Analysis Atrium 10XM Fuel (Epu).
ML15282A2362015-08-31031 August 2015
NEDO-33824, Revision 0, Engineering Report, Browns Ferry Replacement Steam Dryer Stress Analysis.
ML15282A1822015-08-31031 August 2015
ANP-3403NP, Revision 2, Fuel Uprate Safety Analysis Report for Browns Ferry Units 1, 2, and 3, Attachment 9
NL-15-169, NEDO-33824, Revision 0, Engineering Report, Browns Ferry Replacement Steam Dryer Stress Analysis.2015-08-31031 August 2015
NEDO-33824, Revision 0, Engineering Report, Browns Ferry Replacement Steam Dryer Stress Analysis.
ML15282A1842015-08-31031 August 2015
ANP-3377NP, Browns Ferry Units 1, 2 and 3 LOCA Break Spectrum Analysis Atrium 10XM Fuel (Epu).
ML15282A1852015-08-31031 August 2015
ANP-3378NP, Browns Ferry Units 1, 2 and 3, LOCA-ECCS Analysis MAPLHGR Limits for Atrium 10XM Fuel (Epu).
NL-15-169, ANP-3378NP, Browns Ferry Units 1, 2 and 3, LOCA-ECCS Analysis MAPLHGR Limits for Atrium 10XM Fuel (Epu).2015-08-31031 August 2015
ANP-3378NP, Browns Ferry Units 1, 2 and 3, LOCA-ECCS Analysis MAPLHGR Limits for Atrium 10XM Fuel (Epu).
NL-15-169, ANP-3403NP, Revision 2, Fuel Uprate Safety Analysis Report for Browns Ferry Units 1, 2, and 3, Attachment 92015-08-31031 August 2015
ANP-3403NP, Revision 2, Fuel Uprate Safety Analysis Report for Browns Ferry Units 1, 2, and 3, Attachment 9
2023-07-31
[Table view]
Category:Technical
MONTHYEARML23192A4472023-07-31031 July 2023
Staff Assessment of Updated Seismic Hazards at TVA Sites Following the NRC Process for the Ongoing Assessment of Natural Hazards Information
ML22363A3922022-12-28028 December 2022
Cycle 14 Mellla+ Eigenvalue Tracking Data
CNL-22-100, to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for Browns Ferry Nuclear Plant Units 1, 2, and 3,in Support of Atrium 11 Fuel Use at Browns Ferry (TS-535)2022-12-0909 December 2022
to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for Browns Ferry Nuclear Plant Units 1, 2, and 3,in Support of Atrium 11 Fuel Use at Browns Ferry (TS-535)
CNL-22-066, Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for in Support of Atrium 11 Fuel Use Supplement 3, Response to Request for Additional Information2022-07-18018 July 2022
Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 for in Support of Atrium 11 Fuel Use Supplement 3, Response to Request for Additional Information
ML22154A4042022-06-0303 June 2022
Unit 3 Cycle 20 Mellla+ Eigenvalue Tracking Data
CNL-22-057, to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 in Support of Atrium 11 Fuel Use2022-05-27027 May 2022
to Request for License Amendment Regarding Application of Advanced Framatome Methodologies, and Adoption of TSTF-564 Revision 2 in Support of Atrium 11 Fuel Use
ML21277A1232021-10-0404 October 2021
Submittal of Browns Ferry Unit 2 Reactor Pressure Vessel Vertical Weld Flaw Evaluation
CNL-20-102, 10 CFR 71.95 Report for 3-60B Casks User2020-12-16016 December 2020
10 CFR 71.95 Report for 3-60B Casks User
ML20255A0002020-09-24024 September 2020
Staff Review of Seismic Probabilistic Risk Assessment Associated with Reevaluated Seismic Hazard Implementation of the Near Term Task Force Recommendation 2.1: Seismic
ML20112F4852020-05-0606 May 2020
Staff Assessment of Flooding Focused Evaluation
CNL-19-074, Extended Power Uprate - Flow Induced Vibration Summary Report2019-09-0404 September 2019
Extended Power Uprate - Flow Induced Vibration Summary Report
CNL-19-004, Tennessee Valley Authority, Browns Ferry Nuclear Plant, Unit 2, Completion of Required Action for NRC Order EA-13-109, Reliable Hardened Containment Vents Capable of Operation Under Severe Accident Conditions2019-06-0707 June 2019
Tennessee Valley Authority, Browns Ferry Nuclear Plant, Unit 2, Completion of Required Action for NRC Order EA-13-109, Reliable Hardened Containment Vents Capable of Operation Under Severe Accident Conditions
CNL-19-041, Extended Power Uprate - Unit 1 Flow Induced Vibration Summary Report2019-04-16016 April 2019
Extended Power Uprate - Unit 1 Flow Induced Vibration Summary Report
CNL-19-032, Proposed Technical Specifications (TS) Change TS-510 - Request for License Amendments - Maximum Extended Load Line Limit Analysis Plus - Supplement 8, Additional Operator Training Information2019-03-13013 March 2019
Proposed Technical Specifications (TS) Change TS-510 - Request for License Amendments - Maximum Extended Load Line Limit Analysis Plus - Supplement 8, Additional Operator Training Information
CNL-18-134, Extended Power Uprate - Replacement Steam Dryer Revised Analysis and Limit Curves Report2018-11-29029 November 2018
Extended Power Uprate - Replacement Steam Dryer Revised Analysis and Limit Curves Report
ML18283B5472018-10-10010 October 2018
Responding to Letter of 11/18/1977 from E. G. Case to G. Williams, Providing Environmental Qualification Information for Electrical Connectors in Reference of IE Bulletins 77-05 & 77-05A
CNL-18-112, Extended Power Uprate - Flow Induced Vibration Summary Report2018-09-13013 September 2018
Extended Power Uprate - Flow Induced Vibration Summary Report
ML18079B1402018-02-23023 February 2018
Browns Ferry Nuclear Plant, Units 1, 2, and 3: Proposed Technical Specifications (TS) Change TS-510 - Request for License Amendments - Maximum Extended Load Line Limit Analysis Plus
ML17222A3282017-09-0505 September 2017
Flood Hazard Mitigation Strategies Assessment
ML17114A3712017-04-20020 April 2017
Errata for BWRVIP-271NP: BWR Vessel and Internals Project, Testing and Evaluation of the Browns Ferry, Unit 2, 120 Degree Capsule
CNL-16-169, Proposed Technical Specifications (TS) Change TS-505 - Request for License Amendments - Extended Power Uprate (EPU) - Supplement 35, Consolidated Power Uprate Safety Analysis Report Revision2016-10-28028 October 2016
Proposed Technical Specifications (TS) Change TS-505 - Request for License Amendments - Extended Power Uprate (EPU) - Supplement 35, Consolidated Power Uprate Safety Analysis Report Revision
ML16196A0882016-08-0505 August 2016
Staff Assessment of Response to 10 CFR 50.54(f) Information Request - Flood Causing Mechanism Reevaluation
ML16027A0592016-01-27027 January 2016
Snubbers Added to Lnservice Testing Program
CNL-15-056, Application to Modify Technical Specification 2.1.1.2, Reactor Core Minimum Critical Power Ratio Safety Limits (TS-506)2015-09-25025 September 2015
Application to Modify Technical Specification 2.1.1.2, Reactor Core Minimum Critical Power Ratio Safety Limits (TS-506)
ML15282A2402015-09-21021 September 2015
Startup Test Plan
ML15282A2392015-09-21021 September 2015
Flow Induced Vibration Analysis and Monitoring Program
NL-15-169, Non-Proprietary - Safety Analysis Report for Browns Ferry, Units 1, 2 and 3, Extended Power Uprate, Attachment 72015-09-21021 September 2015
Non-Proprietary - Safety Analysis Report for Browns Ferry, Units 1, 2 and 3, Extended Power Uprate, Attachment 7
NL-15-169, Browns Ferry, Units 1, 2, and 3, Startup Test Plan2015-09-21021 September 2015
Browns Ferry, Units 1, 2, and 3, Startup Test Plan
ML15282A1812015-09-21021 September 2015
Non-Proprietary - Safety Analysis Report for Browns Ferry, Units 1, 2 and 3, Extended Power Uprate, Attachment 7
NL-15-169, Browns Ferry Units 1, 2 and 3, Flow Induced Vibration Analysis and Monitoring Program2015-09-21021 September 2015
Browns Ferry Units 1, 2 and 3, Flow Induced Vibration Analysis and Monitoring Program
ML15282A1822015-08-31031 August 2015
ANP-3403NP, Revision 2, Fuel Uprate Safety Analysis Report for Browns Ferry Units 1, 2, and 3, Attachment 9
NL-15-169, ANP-3378NP, Browns Ferry Units 1, 2 and 3, LOCA-ECCS Analysis MAPLHGR Limits for Atrium 10XM Fuel (Epu).2015-08-31031 August 2015
ANP-3378NP, Browns Ferry Units 1, 2 and 3, LOCA-ECCS Analysis MAPLHGR Limits for Atrium 10XM Fuel (Epu).
NL-15-169, ANP-3377NP, Browns Ferry Units 1, 2 and 3 LOCA Break Spectrum Analysis Atrium 10XM Fuel (Epu).2015-08-31031 August 2015
ANP-3377NP, Browns Ferry Units 1, 2 and 3 LOCA Break Spectrum Analysis Atrium 10XM Fuel (Epu).
NL-15-169, ANP-3403NP, Revision 2, Fuel Uprate Safety Analysis Report for Browns Ferry Units 1, 2, and 3, Attachment 92015-08-31031 August 2015
ANP-3403NP, Revision 2, Fuel Uprate Safety Analysis Report for Browns Ferry Units 1, 2, and 3, Attachment 9
ML15282A2362015-08-31031 August 2015
NEDO-33824, Revision 0, Engineering Report, Browns Ferry Replacement Steam Dryer Stress Analysis.
ML15282A1842015-08-31031 August 2015
ANP-3377NP, Browns Ferry Units 1, 2 and 3 LOCA Break Spectrum Analysis Atrium 10XM Fuel (Epu).
ML15282A1852015-08-31031 August 2015
ANP-3378NP, Browns Ferry Units 1, 2 and 3, LOCA-ECCS Analysis MAPLHGR Limits for Atrium 10XM Fuel (Epu).
NL-15-169, NEDO-33824, Revision 0, Engineering Report, Browns Ferry Replacement Steam Dryer Stress Analysis.2015-08-31031 August 2015
NEDO-33824, Revision 0, Engineering Report, Browns Ferry Replacement Steam Dryer Stress Analysis.
CNL-15-143, the Tennessee Valley Authority (TVA) Nuclear Power Group Commercial Grade Dedication Recovery Project - Closure Report2015-07-31031 July 2015
the Tennessee Valley Authority (TVA) Nuclear Power Group Commercial Grade Dedication Recovery Project - Closure Report
CNL-15-085, Response to NRC Request for Additional Information Regarding Proposed Technical Specification Change to Modify Technical Proposed Technical Specification Change to Modify Technical2015-06-0303 June 2015
Response to NRC Request for Additional Information Regarding Proposed Technical Specification Change to Modify Technical Proposed Technical Specification Change to Modify Technical
CNL-14-208, Response to NRC Request for Additional Information Regarding the License Amendment Request to Adopt NFPA 805 Performance-Based Standard for Fire Protection for Light Water Reactor Electric Generating Plants for the Browns Ferry Nuclear Pl2014-12-17017 December 2014
Response to NRC Request for Additional Information Regarding the License Amendment Request to Adopt NFPA 805 Performance-Based Standard for Fire Protection for Light Water Reactor Electric Generating Plants for the Browns Ferry Nuclear Plan
CNL-14-089, (Bfn), Units 1, 2, and 3 - Application to Modify Technical Specification 2.1.1, Reactor Core Safety Limits (BFN-TS-492)2014-12-11011 December 2014
(Bfn), Units 1, 2, and 3 - Application to Modify Technical Specification 2.1.1, Reactor Core Safety Limits (BFN-TS-492)
ML14176A9612014-06-24024 June 2014
Submittal of Non-Proprietary BWROG Technical Product, BWROGTP-11-006 - ECCS Containment Walkdown Procedure, Rev 1 (January 2011), as Formally Requested During the Public Meeting Held on April 30, 2014
CNL-14-038, Tennessee Valley Authority'S Seismic Hazard & Screening Report (CEUS Sites), Response to NRC Request for Information Pursuant to 10 CFR 50.54(f) Recommendation 2.1 of Near-Term Task Force Review of Insights from the Fukushima Dai-ichi Acc2014-03-31031 March 2014
Tennessee Valley Authority'S Seismic Hazard & Screening Report (CEUS Sites), Response to NRC Request for Information Pursuant to 10 CFR 50.54(f) Recommendation 2.1 of Near-Term Task Force Review of Insights from the Fukushima Dai-ichi Accid
ML14077A0952014-01-30030 January 2014
BWROG-TP-14-001, Rev. 0, Containment Accident Pressure Committee (344) Task 1 - Cfd Report and Combined Npshr Uncertainty for Browns Ferry/ Peach Bottom Cvic RHR Pumps, Attachment 8
ML14077A0902013-12-31031 December 2013
BWROG-TP-13-021, Rev. 0, Containment Accident Pressure Committee (344) Task 4 - Operation in Maximum Erosion Rate Zone (Cvic Pump), Attachment 11
ML13225A5412013-12-19019 December 2013
Interim Staff Evaluation Relating to Overall Integrated Plan in Response to Order EA-12-049 (Mitigation Strategies)
ML13338A6342013-12-18018 December 2013
Mega-Tech Services, LLC, Technical Evaluation Report Regarding the Overall Integrated Plan for Browns Ferry Nuclear Plant, Units 1, 2, and 3, TAC Nos.: MF0902, MF0903, and MF0904
ML13276A0642013-09-30030 September 2013
ANP-3248NP, Revision 1, Areva RAI Responses for Browns Ferry Atrium 10XM Fuel Transition, Enclosure 3
ML13276A0662013-08-31031 August 2013
ANP-3153(NP), Revision 0, Browns Ferry Units 1, 2, and 3 LOCA-ECCS Analysis MAPLHGR Limit for Atrium Tm 1OXM Fuel, Enclosure 8
2023-07-31
[Table view] |
Text
Evaluation of Plankton Entrainment by the Intake of Brovns Ferry Nuclear Plant Tennessee Valley Authority Division of Environmental Planning Water Quality and Ecology Branch January 1978
ACKNOWLEDGEMENT This Technical Report is based on data from samples collected and processed by members of the Biology Department of the University of North Alabama under Tennessee Valley Authority contract number TV-46159A.
Staff members of the Biology Department who were responsible for the studies were Dr. Jack S. Brown, Dr. Robert W. Daly, and Dr. Arthur R.
Koch. The latter two individuals are especially acknowledged for their endless hours spent interpreting the data, writing drafts, and assisting with the preparation of the. final report.
-TABLE OF CONTENTS
~Pa e No.
LIST OF TABLES LIST OF FIGURES LIST OF APPENDICES viii INTRODUCTION MATERIALS AND METHODS 6 Entrainment Studies 6 Upstream Overbank and Channel Studies 9 Field Procedures 9 Laboratory Procedures 10 Phytopigments 10 Suspended Solids and Organic Content (Phytoplankton Biomass) 11 Zooplankton 12 Data Analysis 14 RESULTS AND DISCUSSION 16 General 16 Filter Corrections 16 Specific Water Masses 18 Water Masses, of May 18, 1977 18 Water Masses of June 7, 1977 25 Water Masses of June 8, 1977 30 Water Masses of June 9, 1977 35 Water Masses of July 5, 1977 38 Water Masses of July 19, 1977 47 Diel Study, July 20-21, 1977 50 First Water Mass of the Diel Study, July 20, 1977 50 Second Water Mass of the Diel Study, July 20-21, 1977 53 Third Water Mass'f the Diel Study, July 21, 1977 55 Fourth Water Mass of the Diel Study, July 21, 1977 58 Fifth Water Mass of the Diel Study, July 21, 1977 59 Sixth Water Mass of the Diel Study, July 21, 1977 63 Upstream Overbank and Channel Studies 67 General Discussion: Phytoplankton 73 General Discussion: Suspended Solids and Organic Content 75 General Discussion: Zooplankton 76 CONCLUSIONS 80
SUMMARY
LITERATURE CITED
LIST OF TABLES Title ~Pa e Ne.
Reservoir and Condenser Flow Rates, BFNP Cooling Modes, and Water Mass Sampling Times.
Filter Washing Loss Analysis. 17 Filter Volatilization Analysis. 17 Estimates of Percentages of Transported Zooplankton Biomass Entrained into Browns Ferry Nuclear Plant Cooling Water System. 22 Temperature Data Collected in the Intake Forebay of BFNP During Mixed and Closed Cooling Modes, July 5, 1977. 41
LIST OF FIGURES
~F< uae No. Title ~Pa e No.
4 Layout of Browns Ferry Nuclear Plant Location of Browns Ferry Nuclear Plant and place-ment of the upstieam overbank and channel study stations Front view of a skimmer wall gate at Browns Ferry Nuclear Plant Approximate initial sampling locations of boats for a water mass May 18, 1977. Water mass 1, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (CH) and zooplankton (Zoo) in mg/m . 19 May 18, 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m 23 June 7, 1977. Water mass 1, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) nnd zooplnnktnn (Z<<)) In mp/m June 7, 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch'J and zooplankton (Zoo) in mg/m . 28 June 8, 1977. Water mass 1, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 31 10 June 8, 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 34 June 9, 1977. Water mass 1, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Chf and zooplankton (Zoo) in mg/m 37 12 June 9, 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 39 13 July 5, 1977. Mater mass 1, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m 42
~Pl ure No. T1tle ~Pe e No.
,July 5, l977. Mnter mneH 2, suspended solids (SS) and organic content (OC) In g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m 45 15 July 19, 1977. Water mass 1, suspended solids (SS) and organic content (OC) Jn g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m 48
.Iul y 20, I 977, Wnt( r mne>> I, <<)tip< ader'cl .<<oJ'JPI>> (SS) and organic content (OC) ln g/m agd chlorophylL (Ch) and zooplankton (Zoo) in mg/m . 51 17 July 20, 1977. Mater mass 2, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 54 18 July 21, 1977. Water mass 1, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 56 19 July 21, 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll.
(Ch)- and zooplankton (Zoo) in mg/m . 59 20 July 21, 1977. Water mass 3, suspended solids (SS) and organic content (OC) in g/m a~d chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 61 21 July 21, 1977. Water mass 4, suspended solids (SS) and organic content (OC) in g/m agd chlorophyll (Ch) and zooplankton (Zoo) in mg/m . 64 22 Diel3Study 20-21 July 1977. Zooplankton Biomass mg/m . 66 23 Overbank versus channel study sgspenced solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) in mg/m . June 5, 1977 68 24 Overbank versus channel study suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) in mg/m . July 5, 1977 69 25 Overbank versus channel study suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) in mg/m . July 28, 1977 70
LIST OP APPENDICES
~Pa e'No.
Appendix A Computer Program for Chlorophyll Determinations Appendix B Computer Program for Student-Newman-Keuls Multiple Range Test Appendix l," Susp~ndcd Ail its a<<d '>tv<(il~ 4<<ti'V~tl lbts Appendix D Mean, Variance, and Coefficient of Variation among Chlorophyll a Concentrations, and Results of Application of the Student-Newman-Keuls Multiple Range Test to these Data Appendix E Mean, Variance, and Coefficient of Variation among Zooplankton Biomass Replicates, and Results of Application of the Student-Newman-Keuls Multiple Range Test to these Data Appendix F Concentrations of Chlorophylls a, b, and c; Raw Data Appendix G Pheophytin a Concentrations and Pheophytin Indices Appendix H Overbank vs. Channel Studies; Suspended Solids and Organic Content Data Appendix I Overbank vs. Channel Studies; Zooplankton Biomass Data Appendix J overbank vs. Channel Studies; Chlorophyll a Concentrtions Data Appendix K Overbank vs. Channel Studies; Pheophytin a Concentrations Data
~P1 oee No. Title ~Pe e No.
26 Over)ank vs. Channel Study. Zooplankton Biomass mg/m 5 June, 5 July, 28 July 1977.
72
INTRODUCTION The primary concern of this study is to assess the effects of the intake of the Browns Ferry Nuclear Plant (BFNP) on the plankton community found in Wheeler Reservoir in the vicinity of BFNP. The Browns Ferry Nuclear Plant is located on the north shore of Wheeler Reservoir at Tennessee River mile,(TRM) 294. The plant is composed of three electrical generation units and draws condenser cooling water from Wheeler Reservoir.
Condenser cooling water enters the intake structure of BFNP, passes through steam condensation units, and may be discharged directly into the reservoir, or may pass through six mechanical draft cooling towers before it is returned to the reservoir or recirculated through the plant (Figure 1).
The intake structure through which water enters BFNP from the reser-voir is located at TRM 294.2 at the end of an overbank (the floodplain of the Tennessee river submerged when Wheeler Reservoir was formed) that extends 14 miles (22.4 km) upstream to Decatur, Alabama (Figure 2).
The intake structure consists of a skimmer wall with three gates, an intake forebay, and nine intake pumps that draw water into BFNP. The skimmer wall gates are composed of doors that extend 9 feet (3 m) below normal pool level and may be opened or closed according to conditions
~ MECHANICAL DRAFT COOLING TOWERS SCALE 0 500 IOOO ft 0 IOO 200 500 m II II II II
/I DISC H ARGE (I CONTROI WEIR ( I
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INTAKE STRUCTURE r'rrr
'::,:,':,~ SIIIMMEFI WALI AND GATS S PIPES WHEELER RESERVOIR Figure 5: Layout of Browns Ferry Nuclear Plant
Round Island Creek BFNP ~ ~ ~ ~ ~ ~ 4 ~ ~ ~ ~ ~ ~
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Creek Fox Creek Sampling Location Q Channel Light x River Hile Figure 2~ Overbank vs. Channel Study, Sampling Locations
of the plant's operation (Figure 3).
The plant uses three different modes of cooling system operation.
In open mode, cooling water passes through the condensers and is discharged into the reservoir. In helper mode, cooling water passes through the condensers,, through mechanical draft cooling towers, and is returned to Wheeler Reservoir. In closed mode, water passes through the generation condensers, through the cooling towers, and is returned to the intake forebay for reuse. Under closed mode the only water taken into BFNP is water used to replace that lost by evaporation in the cooling towers or that discharged to the reservoir as blowdown to prevent"a buildup of dissolved solids in the cooling system. The plant may also operate with any combination of two of the three modes (mixed mode). Pure water per unit time is entrained from Wheeler Reservoir under open mode than in helper mode operation, and much less water is entrained in closed mode than in helper mode operation.
This report assesses the effects of the BFNP intake structure on the plankton community as the plankton is transported down both the navigation channel'nd the overbanks (particularly the north overbank adjacent to the plant) and passes the plant. Also included is an assessment of the quantities of channel and overbank plankton located further upstream that may become subject to entrainment by BFNP as they are transported downstream.
SKIMMER
'56 ft*
(169.5 m) 547 ft (166.7 m)
OPENING BOTTOM 523 ft (159.4 m)
Figure 3. Front View of'a skimmer wall gate at Browns Ferry Nuclear Plant**
- normal summer pool elevation
- information provided by Christopher Ungate, TVA, DMM, (personal com-munication, July, 1977)
MATERIALS AND METHODS Entrainment Studies Field studies of entrainment of plankton into BFNP were carried out when steady river flows were maintained, and when BFNP was operating under known conditions (Table 1). Studies on May 18, June 7, July 19,'nd July 20, 1977, were coordinated with dye studies (Volume 2) which were used in interpretation of water flow patterns in overbank water entering BFNP intake. Additional studies were conducted on June 8 and 9, and July 5 and 21, 1977. Sampling was done during daylight hours, except in the evening of July 20 and the early morning of July 21, 1977, during a diel study.
Studies were conducted on segments of water, designated as "water masses", that originated upstream of the intake structure of BFNP, and moved downstream past or were entrained by BFNP. Individual water masses were sampled both upstream of the intake structure, and opposite the intake skimmer wall. Initial sampling locations were determined by using velocity and directional data obtained from an ENDECO Type 110 current meter so that the time interval between the first and last samples was less than two hours. The upstream set of samples was taken by four aligned boats, two positioned on the overbank, 'and two positioned in the channel (Figure 4). The second set of samples was taken in line with the skimmer wall, and included sampling by two boats in the navigation channel, by two boats in the intake approach, and by a fifth boat in the intake forebay of BFNP (Figure 4).
Table l. Reservoir and Condenser Flow Rates, BFNP Cooling Modes, and Water Mass Sampling Times.
a b
~R qC Cooling Sampling Water Date ft s m s ft s m s Mode Time Mass May 18, 19?7 38,000 1,076 4,410 125 open 0900-1100 38,000 1,076 3,550 101 helper 1300-1500 June 7, 1977 36,000 1,019 3,550 101 helper 0900-1100 36,000 1,019 3,550 101 helper 1300-1500 June 8, 1977- 49,000 1,387 3,550 101 helper 1300-1500 49,000 1,387 4,410 125 open 1800-2000 June 9, 1977 5,550 157 4,410 125 open 0900-1000 7,400 210 4,410 125 open 1100-1200 July 5, 1977 18,000 510 1,200 34 mixed c 0900-1100 37,000 1,048 220 6 closed 1400-1600 d
July 19. 1977 8,000 227 3,550 101 mixed 0900-1100 d
July 20, 1977 45,000 1, 274 3,550 101 mixe dd 1900-2100 33,000 934 3,550 101 mixed 2300-0100 d
July 21, 1977 28,000 793 3%560 101 mixed d
0300-0500 .3 38,000 1,076 3s550 101 mixedd 0700-0900 4 36,000 1,019 3,550 101 mixedd 1100-1300 5 36,000 1,019 3,550 101 mixed 1600-1800 6 a - Reservoir flow rate b Condenser cooling flow rate c - Combination of helper and closed cooling modes (Q estimated) d - Combination of open and helper cooling modes
Intake Intake 4 Porebay Submerged bed of Round Island Creek Skimmer'-Wall 0 ~
Intake
~ ~
0 Approach Overbank Mason Island Light
~ e ~
~ ~
""0 ~ ~ ~ e ~ ~ ~
Channel TRM 295 Figure 4. Approximate initial sampling locations of boats, for a water mass.
Downstream progress of the water mass was observed by following movements of a subsurface drogue. The drogue consisted of weighted plywood vanes, suspended 1 m to 2 m beneath the water surface, buoyed by a plastic jug. Observation of drogue movement during dark hours of the diel study, July 20-21, was facilitated by placing an activated chemical lightstick inside the jug.
Sampling was initiated simultaneously by commands issued from a logistics boat (boat used for transporting samples to shore and coordi-nation) over 2-way band radios. For each water mass the logistics boat crew recorded dissolved oxygen concentrations (DO) with a YSI-51B Dissolved Oxygen analyzer and water temperature at various depths with the ENDECO current meter and/or the DO analyzer.
Upstream Overbank and Channel Studies The basic status of the plankton communities of the reservoir upstream of BFNP were documented on three occasions: June 5, July 5, and July 28, 1977. Zooplankton biomass, phytopigment, and suspended solids and organic content samples were simultaneously procurred from a right overbank and a channel station at TRM 295.4, TRH 296.9, and TRH 298.4 (Figure 2).
Field Procedures Triplicate water samples for phytopigments, suspended solids, and organic content determinations were collected at surface, 1 m, 3 m, and 5 m depths using two-liter Kemmerer and/or van Dorn samplers. Samples were placed in numbered, capped, plastic containers and transported to shore for immediate processing. 'I'ime I>otween initial sample collections and field phytopigment processing <Ifd nr>t exceed>>>>r hou> .
10 Five replicate samples for the determination of zooplankton biomass were collected by bottom-to-surface vertical tows with a half meter plankton net (820 mesh nitex, 80 micrometer square) equipped with a General Oceanics digital flow meter (Dycus and Wade, 1977). Each zoo-plankton sample was placed in a 150 ml capped, numbered, plastic bottle containing 3 ml of 40/ formaldehyde tinted red with a few drop's of food coloring.
On shore, 500 ml of each phytopigment water sample was filtered I
through a Millipore AP40 glass fiber filter using the Millipore fil-tering process (Millipore Corporation, Bedford, Mass.). The filter of each subsample was then folded, enclosed in a numbered Whatman No. 1 filter paper, and put into a desiccator which was stored on ice in the dark until transported to the laboratory. The remaining, unfiltered water of each sample was preserved with 50 ml thimerasol for later suspended solids and organic content (an estimate of phytoplankton biomass) analyses.
Laborator Procedures Phytopigment samples were frozen until extraction procedures began. All samples from each water mass were analyzed concurrently.
Each filter sample was placed into a numbered, aluminum-foil-covered 15 ml screw-capped centrifuge tube. Fifteen ml of 90K acetone, buffered with a saturated magnesium carbonate solution, were added to each tube. Each tube was agitated fo'r 30 sec and placed into the dark. in an explosion-proof refrigerator at 4 C for 24-30 hr. The extracted samples and pads were filtered through a 1.2 micron glass
fiber filter. The centrifuge tube was rinsed with 90/ buffered acetone and the rinse filtered and added to the sample filtrate.
Sufficient 90/ buffered acetone was added to the filtrate to make the volume 15 ml, and the resulting chlorophyll extract was stored in an aluminum-foil-covered centrifuge tube in the dark for 24 hr at4C.
Optical densities (OD) necessary for determination of con-centrations of chlorophylls a, b, and c were read for each extract at 750, 663, 645, and 630 nm from a double-beam Beckman spectro-photometer. All absorbance values were standardized against a 15 ml 90/ buffered acetone blank.
Optical densities for determination of pheophytin a and the pheophytin index were read after each sample was acidified with two drops of 0.1 N HC1. Optical densities were read at 750 and 663 nm after one minute but before two minutes after acidification.
All data, including sample numbers and absorbancies were recorded on IBM Fortran computer sheets and punched onto computer cards. Concentrations of chlorophyll a, chlorophyll b, chlorophyll c, pheophytin a, and the pheophytin index were calculated from absorbance values by a computer program (Appendix A) using the equations found in Weber (1973) for the glass fiber filter method of phytopigment determinations.
Suspended Solids and Or anic Content (Ph to lankton Biomass)
Replicate water samples were analyzed concurrently according
.to the methods in Standard Methods for the Examination of Water and Wastewater, 14 Bi., 1975. I'.~c h sample wns ngltnt<<d, nnd n 500 ml subsample filtered through a pre-weighed, pre-washed filter. Each
12 filter was oven-dried one hour at 100 + 5 C and weighed to within 0.0001 g. From this weight, the original pre-washed filter weight was subtracted to determine the total suspended solids (TSS) weight of the subsample.
Each subsample filter was placed into a 50 ml, constant weight cr'ucible and a combined weight obtained. The crucible and sub-sampl'e filter were heated at 575 + 25 C 20 min in a Thermolyne F-A1730 Muffle Fur'naceq removed from the furnace, and placed in a desiccatoi until they had cooled to room temperature. Their weight was 'determined to within 0.0001 g, and the difference in weight b'etween this quantity and TSS weight was designated organic content (OC). 'll weighings were made on a Mettler H72 analytical balance.
Package's 'of Millipore AP40 'glass fiber filters'ere randomly
'sampled for pos'sible washing and/or volatilization loss. All final values were adieu'st'ed for filter washing or volatilization loss and conver'ted to No./m 3 .
'Zo'o'plankt'o'n biomass was 'determined for each sample by using a multi=.density 'sucrose 'c'entrifugation technique which separates the zooplankt'on from 'the phytopXankton and detritus. For this pro-cc'dure zooplankton samples 'were poured through a Wisconsin bucket
'I 'v'I'I'I> '-'!> '4>'o'li 'c 'l'>.'I'Il, ln>>1 I II!. 'I>( t!I I'I'I Ia!
It'aterials wc r~ ~
rinsed with dis'tl1'led water and washed into a 50 ml centrifuge
't'ubeq such tha't 9.ess 'than 15 ml water was added to the tube. The
'tube 'was agi'ta'ted and a 3.5 'ml aliquot of red-colored sucrose
13 solution (specific gravity 1.3472, 943 g/1 of water) pipetted into the bottom of the centrifuge tube. A green-colored sucrose solu-tion (specific gravity 1.5518, 1552 g/1 of water) was then pipetted into the bottom of the tube. Slow addition of both sucrose solu-tions minimized mixing of layers of sucrose of different densities.
Samples were centrifuged at 10,000 RPM for ten minutes. After centrifugation, the supernatant was removed with a vacuum pipetting apparatus or by decantation. Supernatant removal for samples collected through June 9, 1977, was performed with the use of a vacuum pipetting apparatus; however, since small amounts of zoo-plankton were observed adhering to the sides of the glass tubing of the pipetting apparatus, supernatants for samples collected after June 9 were decanted. The sucrose was removed from the zooplankton by washing the sample with distilled water. The washed sample was poured onto a pre-weighed Millipore AP-40 glass fiber filter.
After filtration, the filter with the zooplankton sample was placed inl s' numl)uvi.'sl .P I umIInlllI I>'ln, nvclj 'II II.'fl s]I /!I() Il)'.
to a desiccator, and allowed to cool to room temper-I'ransferred ature. The cooled sample was weighed to 0.0001 g on a Mettler H-72 analytical balance. The difference between the filter weight and the total weight was designated as zooplankton weight. Zooplankton weight divided by the volume of water sampled (calculated from flow meter readings) was designated zooplankton biomass, and expressed 3
as mg/m .
14 Data Anal sis Data were analyzed according to standard statistical methods.
Mean values, variances, and coefficients of variation were calculated for all series of zooplankton, chlorophyll a, and organic content replicates. A Student-Newman-Keuls multiple range test was performed on means obtained for zooplankton replicates (of both upstream sampling and sampling done opposite the intake structure at BOP) of a single water mass to determine if sampling points were significantly different at the 5/ level. When four or five mean values were available, a Student-Newman-Keuls multiple range test was performed for mean values of chlorophyll a and organic content at each depth for, both upstream samples and samples taken opposite the BFNP intake structure. All statistical calculations were performed using an IBM System III computer at the University of North Alabama and a computer program modified from Sokal and Rohlf (1969) (Appendix B).
The percentage of zooplankton entrainment was calculated by dividing the rate of passage of total zooplankton biomass transported past BFNP by the rate of zooplankton biomass entrained by the pumps of BFNP.
The total rate of passage of transported zooplankton biomass was cal-culated by summing the rates of passage of zooplankton biomass in the channel and north and south overbanks at the initial sampling locations.
The rates of passage of zooplankton, biomass were determined by multi-plying the calculated river velocity by the cross sectional area (as determined from TVA Reservoir Silt Survey charts and corrected for reservoir pool elevation) by the averaged zooplankton biomasses of the
15 channel or the north overbank. In these calculations river velocities and zooplankton biomasses of the south overbank were assumed to equal those of the north overbank. The total rate of zooplankton biomass entrainment was calculated by multiplying the zooplankton biomass in the intake forebay by the flow rate of water through the intake pumps into BFNP.
16 RESULTS AND DISCUSSION General Sampling procedures were not adversely affected by weather conditions.
No thunderstorms were encountered, and displacement from drogue positions by wind and/or wave action was corrected by the use of boat motors.
HosL diurnal sampling was conducted on clear or partly cloudy days tl>pt 4rrr ln>t [ l2 t:), witt> n light wound (0-5 knots).
Reservoir temperature ranged from 22.5-32.0 C, with the maximum water temperature recorded in surface waters on June 5, 1977. No significant thermocline was present at any time, and temperature changes fro'm the 'suiface to 8 m (near bottom) were usually less than 2.0 C.
Dissolved oxygen concentrations were 5.0-12.4 mg/1 with the maximum cohcentration re'corded at the surface on June 8, 1977. Surface to bottom
'oxygen le'vels n'ormally varied 2.0 mg/1, and the usual range outside the inta'ke fo'rebay was 9.0-7.0 mg/1 for surface to 8 m samples. Supersatura-
'tion of di'ssolved 'oxygen was recorded for a few water masses. This indicated that sign'ificant phytoplankton phytosynthetic activity was
'occurring. Failure of "the dissolved oxygen probe on July 5, 1977, pre-vented collection of further dissolved oxygen data.
Barge traffic caused an increase in visual turbidity in a few cha'nnel samples, 'bu't for short time spans of less than 30 min. Uisual
'tu'rbidity in th'e intake 'foreb'ay and )ust outside the skimmer wall was always greate'r 'than i'n 'other "samples opposite BFNP intake.
Filteh,Corrections Fil'ters us'ed 'foi the determination of'weights of suspended solids and zooplankton showed an average filter washing loss of. 0.002 g/filter pad (Table 2'). This 'loss was considered negl fgfbl> ~
I>nd w>s ni>> luau li>d> d
Table 2. Filter Washing Loss Analysis.
Washed/
initial ( ).. Dried ( ) Dried ( ) Variation 0.1183 0.1183 0.1182 -0.0001
- 0. 1197 0.1194 0.1194 0.0000 0.1180 0.1180 0.1171 -0.0009 0.1182 0.1181 0.1181. -0.0001 0.1170 0.1170 0.1170 0.0000 0.1186 0.1184 0.1181 -0.0005 0.1207 0.1207 0.1201 -0.0006 0.1196 0.1196 0.1196 0.0000 0.1172 0.1172 0.1172 0.0000 0.1195 0.1194 0.1193 -0.0001 Mean: 0.0002 grams loss due to washing Table 3. Filter Volatilization Analysis.
Crucible Before After Filter No. Heatin Heatin Loss ( )
43 25.6577 25.6568 0. 0009 31 26.7302 26.7295 0. 0007 36 23.4182 23.4173 0. 0009 9 27.7722 27.7715 0.0007 20 27.0035 27.0027 0.0008 34 26.0934 26.0926 0-0008 17 25.2036 25.2026 0.0010 40 23.6997 23.6985 0.0012 41 23.4004 23.3991 0.0013 29 24.8852 24.8834 0.0018 Mean: 0.0010 grams loss due to volatilization.
18 in further calculations. When the same filter sets were heated, volatilization losses averaged 0.0010 g/filter (Table 3). This loss was considered important and was included As a constant value in all organic content calculations.
S ecific Water Masses Water Masses of Ha 18 1977 Oa May 18, 1977, two water masses were s~mpleg. 'j'l~p f ~ps(
wat,er mass was sampled between 0900 and 1100 hours0.0127 days <br />0.306 hours <br />0.00182 weeks <br />4.1855e-4 months <br />, with a river 3
flow of 1,076 m /s while BFNP was operating in open cooling mode (Table 1). The second water mass was sampled between 1300 and 1500 hours0.0174 days <br />0.417 hours <br />0.00248 weeks <br />5.7075e-4 months <br />, with a river flow of 1,076 m/s while BFNP was operating in helper cooling mode. Reservoir pool elevation was maintained at 169.36 m (555.64 ft.) msl whi] e both water masses were being sampled.
Upstream of BFNP, in the first water mass, concentrations of chlorophyll a, organic content and suspended solids (an estimate of phytoplankton biomass) and zooplankton biomass were higher in overbank than in channel samples (Figure 5). Host chlorophyll a was con-centrated in surface and 1 m samples, with lower chlorophyll a values in 3 m and 5 m samples. Organic content was evenly distributed throughout all water columns, with slightly greater concentrations in 1 m and 3 m samples. Suspended solids were greatest in 5 m samples.
Zooplankton biomass was lowest in the channel and highest on the overbank nearest the north shore.
Opposite the intake, chlorophyll a concentrations were highest in surface and 1 m samples, except in the intake forebay where they were greatest at 1 m and lowest in surface samples (Figure 5).
Organic content was highest in the intake approach nearest the
- 18. 2.4 2.6 19.4 2.5 3.6 34
- 8. 3~1 14
- 20. 6 .7 3.4 1 .3 33.8 4'
27
- 19. ~7 3.0 14.8 F 9 5.6 Ch Zoo
- 19. 1 3' 2.8 SS OC Ch Zoo
.0 9.2 8.3 2.5 0.9 12 2.3 2.9 8.2 .2 12.4 3.1 7.8 4 2.8 2.4
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6.0 2.5 6.2 9.5 1.9 ,0. 6
~ 7 5.7 2.5 .6 7.6 .5 0.5 4.9 2.0 3..7 18:
gh .
12.8 7.9 2.4 7.5 8.0 2.0 0.6 II SS OC Ch Zoo Surface 8. 1.2 52 16 1m 6.9 1.7 0.9
.SS OC Zog 5.0 1.8 3m 6~6 5.4 2.5 7.8 2.8 12.8 4' 1.6 3A %W 5 ' .0 4' 8 7 7.3 2,5 2:
7' 1.7 1.1 SS OC Ch I
Zoo ~
SS OC Ch Zoo Figure 5. May 18, 1977. Water mass 1, suspended solids (SS) and organic conte'= (OC) in g/m3 and chlorophyll (Ch) and zooplankton (Zoo) in'mg/m .
20 skimmer wall, high in the intake forebay, and slightly lower in channel samples (Figure 5). Suspended solids were high in 3 m and 5 m samples taken just outside the skimmer wall and at all"depths in the intake forebay (Figure 5). Zooplankton biomass was highest in the intake forebay, lower in intake approach, and lowest in channel samples (Figure 5).
Dye studies (Volume 2) conducted concurrently with this water mass showed that most of the surface water originating on the overbank bypassed BFNP because the overbank surface water was warmer than channel water. Comparison of chlorophyll a concentrations of the upstream overbank and the intake approach indicate that chlorophyll a (and therefore, phytoplankton} was localized in the top meter of the water column and most bypassed BFNP altogether.
Dye studies showed that 55 percent of the water entering the intake was from the north overbank. Vector velocity measurements (Volume
- 2) indicated that channel water from 3 m depths or greater near the north overbank was the source of the other 45 percent. The range of concentrations of chlorophyll a in the intake forebay (3.6-2.6 3
mg/m ) indicates the probable entrainment of phytoplankton located in water from the lower depths of the north overbank (5.6-0.6 8!c'. ',
'3 "IHlI PIIjI~I!.3!ll';6'~II I'iI.Ht~<j dh 8nH IiotriQ tIIfee IncIers 2n tIie 3
channel. (3.7-0.6 mg/m ) near the north overbank. The phytoplankton community of all areas sampled was physiologically healthy as was indicated by the general absence of pheophytin a (Appendix G). No relationship was evident between chlorophyll a and organic content concentrations. Suspended solids data were inconclusive because the 5 m channel samples were collected a considerable distance (3 m) above the reservoir bottom (Appendix C).
21 With a cross-sectional area of 2,600 m , 5,620 m , and 3,365 m ,
and velocities of 0.075 m/s, O.ill m/s, and 0.075 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained into BFNP was 23 percent (Table 4). lf the south oyerbank is excluded (values for this region were assumed to be identical to those of the north overbank since no quantitative data were collected) from the calculations, the transported zooplankton biomass entrained would be 34 percent.
C In the second water mass sampled on Nay 18, 1977, more chloro-phyll a was present in 1 m samples collected from both overbank and channel water upstream of BFNP than in samples from other depths (Figure 6). Chlorophyll a concentrations were lowest (0.6-1.9 mg/m )
3 at 5 m at all stations except the overbank station nearest the north shore which had a concentration of 5.4 mg/m 3 '(Appendix D).
Suspended solids and organic content were similar at surface and J
1 m depths in overbank and channel water and highest in 3 m and 5 m water on the overbank (Appendix C). No pheophytin a was found in any upstream samples (Appendix G). Zooplankton samples were destroyed through improper preservation, except for the overbank sample nearest the shore.
Opposite the intake structure, highest concentrations of chloro-phyll a and organic content were present in 1 m samples (Figure 6).
Chlorophyll a was present in large quantities in surface, 1 m, and 3 m intake approach and south channel samples, but was confined to the top meter of mid-channel water. In the intake forebay, chlorn-phyll a concentrations were less than outside the skimmer wall, but
Table-4. Estimates of Percentages of Transported Zooplankton Biomass Entrained into Bhowns Ferry Nuclear Plant Cooling Water System.
Reserv~ir Flow Inta)e Flow Percenta e Rntrained Date Water 1@ss (m /s) (m /s) Total Reservoir Cross-section Channel Ri ht Overbank Onl Hay 18, 1977 1,076 125 23 34 1,076 101 b b June 7, 1977 1 $ 019 101 12 16 1,019 101 22 28 June 8, 1977 1,387 101 14 19 1,387 125 17 22 June 9, 1977 157 125 210 125 c July 5, 1977 510 34 26 31 1,048 6 0.3 0.4 July ', 1977 227 99 56 69 Diel Study July 20-"1, 1977 1,274 101 18 25 934 101 14 17 793 101 17 23 1,076 101 16 22 1,019 101 8 11 1,019 101 30 37
- a. See Table 1 for time of day.
- b. S-mples not preserved.
c- ":ercentage entrained could not be determined because very low reservoir flows would not allow following and sampling a water mass; hence, sample sets along a transect inline with the intake were collected.
- 19. 2 '
19.4 3.6 ".3 19.6 3.2 4.4 5 1.4 8.6
~ 7 3.2 19.7 2' 5.9 C Ch ZOO 16.9 9.9 20.7 3.0 5.4 SS ZOO 6.1 .9 6.1 47 5.1 1.9 .0
- 14. 8 3.4 13.2 6.9 3.3 13.0
.3 2.7 9.4 11.3 2~0 7.2 Mason 30 ' 4.3 0.0 10. 9 2.5 0.6 2+ Zsland SS OC Ch a ~ ~
Light ZOO ZOO.
60 180 9.5 SS OC Ch
~
~ ~ ~
8,5 4 ' 17. 6 '
~ ~ ~ ~ ~ ~ ~
~
~ ~ ~
4' 2.2 8.5 8.2 2~0 9.5 16 7~0 2' 14.5 2.8 .5 6;6 1.5 SS gC~ 9'.1 8.4 2.9 10.6 8 ' 2.2 1.5 24 SS OC Ch ZOO Surface 8.1 1.9 0.5 lm 9.6 2.1 0;0 SS OC Ch ZOO 5~5 ~ 8 9.3
- 6. 2.6 9.7 7.6 2.2 9.4 3.8 14 '
17.8 Sm 5' 1.8 5.8 7.5 2.5 11.7
- sample damaged in field 15 8.1 0~8 1.9 processing 8.0 F 1 0.8 SS OC Ch ZOO SS OC Ch ZOO Figure 6. May 18, 1977. Water mass 2, suspended solids (SS) aud organic content (OC) in g/m3 and chlorophyll (CH) and zooplankton (Zoo) in mg/m3.
24 similar organic content, concentrations were inside the intake forebay and outside the skimmer wall. Suspended solids generally were P
highest in the intake forebay, and samples from just outside the skimmer wall had more suspended solids than other samples taken opposite the intake (Figure 6). Pheophytin a was present in small quantities at 1 m and 3 m inside the intake forebay (Appendix G).
Zooplankton biomass was significantly higher in the intake forebay than outside the skimmer wall (Appendix E). The second highest zooplankton biomass was collected just outside the skimmer wall.
Although dye studies were not conducted concurrently with this water mass, conditions were similar to those encountered during the morning when the dye studies were conducted. The only difference was that the plant was operating in a different cooling mode (Table 3
- 1) and was entraining less water (24f m s) than in the morning.
Although this difference would affect the near field currents, it would not appreciably affect the relative proportion of water coming into the intake from the overbank and channel. Since chlorophyll a concentrations for this water mass showed similar trends to those
~t for the water mass sampled during the morning, similar interpretations can be made. Additionally, thc phytoplankton community of this water mass was physiologically healthy.
The percentage of the transported zooplankton biomass entrained into BFNP cannot be determined because the upstream samples were not preserved except those collected by the crew in'he boat nearest the north shore.
25 Water Nasses of June 7, 1977 On June 7, 1977, two water masses were sampled with BFNP operating in helper cooling mode. The reservoir pool elevation was 169.35 m (555.60 ft) msl and the reservoir flow rate was 1,019 m 3
/s.
The first water mass was sampled between 0900 and 1100 hours0.0127 days <br />0.306 hours <br />0.00182 weeks <br />4.1855e-4 months <br />, and the second water mass was sampled between 1300 and 1500 hours0.0174 days <br />0.417 hours <br />0.00248 weeks <br />5.7075e-4 months <br /> (Table 1).
Significantly higher concentrations of chlorophyll a and higher
'levels of organic content and suspended solids were present in overbank than in channel samples upstream of BFNP (Figure 7).
Negligible amounts of chlorophyll a were present in channel samples.
Levels of suspended solids and organic content generally increased with depth in water columns sampled. Zooplankton samples were lowest in mid-channel and highest in south channel samples (Figure 7).
Pheophytin a was absent in overbank samples, but present in channel samples (Appendix G).
Opposite BFNL intake, concentrations of chlorophyll a, organic content, and suspended solids were higher in intake approach and intake forebay samples than in channel waters (Figure 7). Pheophytin a was present in small amounts in a few intake approach and channel samples (Appendix G). Forebay levels of suspended solids were higher than intake approach levels. Zooplankton biomasses were highest inside the intake forebay.
Dye studies (Volume 2) conducted concurrently with this water mass showed that most north overbank water was entrained into BRP constituted percent of the water entering the intake'he I'nd 63
22.9 4 7 2.4 23.2 4.6 2.3 15 ' 5.1 3.3 24,5 4.9 2.1 15.5 .4 3.2 56 24.2 5.1 2.2 Ch zoo 21 ~ 1 ~ 7 3.2 SS OC Ch Zoo
- 14. 4.5 .1 11.5 F 1 0.1 17.9 4.7 2.4 14. 5 4.1 0.5 ~ ~
17.1 4.3 1.7 29 15.7 4.1 0.5 Mason
- 27. 2 6.3 0~8 16.8 4.1 . ~ Island Ch Zoo SS OC Ch Zoo~ ~ ~
~ ~
Light 13.9 4.9 2.2 ~ ~
16.1 6~1 0.3 84 ~ ~ ~ ~ ~
~ i ~ ~
~ ~
9~2 2.9 0.0 15 ~ 2 6.7 ~ 2 10.4 2,5 .1
- 13. 6 3~9 1.9 11.2 3.9 0.0 29 SS Q C,
~ Ja 9'.3 56 8.0 4.0 o.9'.8 10. 8 4.0 0~ 5 SS OC Ch Zoo Surface 8. 3.5
- 14. 5 4.7 .7 3m SS OC Ch Zoo 12.1 3.8 0 8 8~ 3.3 1.2 12.9 2.0 9.7 ~ 1 1.0 5.5 -
113
- 13. 4.3 1.5 13.4 4.9 0.8
- no sample collected 14.2 2.8 3 '
- sample lost 16 ~ 4' 2.3 SS OC Ch Zoo SS OC Ch Zoo Figure 7. June 7 1977. )fater mass 1, suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) and zooplankton (Zoo) in mg/m3.
27 remaining 37 percent came from the area of the channel near the north overbank at depths of 3 m and below. The range of chlorophyll a 3
concentrations in the intake forebay (2.4-2.1 mg/m ) indicates the probable entrainment of most phytoplankton located in water from the north overbank (3.3-0.1 mg/m 3 ) and phytoplankton located at and 3
below 3 m in the channel water (3.4-0.0 mg/m ) near the north overbank.
Pheophytin a data indicate that some of the channel phytoplankton was not physiologically healthy.
With a c rove-a+i'I tni<<sl ~si ~ii ~il',, > I0 m and velocities of 0.071 m/s, 0.105 m/s, and 0.071 m/s for the north overbank, channel, and south overbank,, respectively, the percentage of transported zooplankton biomass entrained into BFNP was 12 percent (Table 4). If the south overbank is excluded from the calculations, the transported zooplankton biomass entrained would be 16 percent.
In the second water mass sampled on June 7, 1977, chlorophyll a concentrations were significantly higher on the upstream overbank nearest shore than they were in the channel or overbank adjacent to the channel in surface, 1 m, and 3 m samples (Appendix D).
Chlorophyll a, suspended solids, and organic content were generally higher in overbank than in channel samples at all depths (Figure 8).
Pheophytin a was present in most samples, except for some 5 m channel samples. Zooplankton biomasses were higher in the channel than on the overbank (Figure 8).
Opposite the intake of BFNP, the highest concentration of chloro-phyll a, suspended solids, and organic content were generally found in intake approach samples (Figure 8). Pheophytin a was absent in
21 5;.Z 3.6 109
'1.9 G., 0 3.6 13.8 4.0 8.6
- 16. 4.9 6.5 23.2 4..iG 4. 1 Ch Zoo 0~4 5~5 4.7
.A ..
SS OC C}1 Zoo 6.m 6.8', 12.1 14.6 5.5 6.3 0.6 1.0 ~ ~
- 2. 7;..9 1. 7 11. 2 37 4~7 1.6 Mason
- 17. 8 4 ' 2.1 island S OC Ch Zoo ~
Ch Zoo
~
Light
- 13. 2. 3.8 6.1 ~ ~ ~ ~
15.2 4.5 5.5 ~ ~ ~ ~
~ ~ ~ ~
- 13. 1 4.3 3.8 11.4 4.1 0~ 0 33 11 F 9 4.0 0~0 56 12.8 3' 0 '
12,8 4.2 0.0 M8 h
~ 7 01 3.3. 4.1 3.5 53 13 ~ 2 4.9 0 '
SS OC Zoo Surface 11. 0 5.2 2'
.Q'.4 4.6 2.6 SS C C Z oo 3m 11 F 1 4~6 . 2.9 9.8 3~5 0.6 11 ' 3~8 2 Q3 '50 11. 9 3.3 0.2 54 5m 14 ~ 1 3.9 3~ 0 11.9 4.1 0.3
~~* sample lost 14. 4.1 no sample collected 14. 4.3 5 3.4 SS OC Ch Zoo SS OC Ch Zoo Figure 8. June 77~ 1977. Water mass 2, suspended solids (SS) and organic content (0C) in g/aR and chlorophyll (Ch) and sooplankton (Zoo) in mg/m3 ~
29 several samples from gust outside the skimmer wall and also in the intake forebay (Appendix G). Zooplankton biomasses were highest in the intake forebay (Figure 8).
Although dye studies were not conducted concurrently with this water mass, conditions were similar to those encountered during the morning when the dye studies were conducted. Therefore, the relative proportion of water coming into the intake from the over-bank and channel would have been similar for the two water masses.
The range of chlorophyll ..c concentrations in the intake 'forebay 3
(5.4-3.6 mg/m ) indicates there may have been some problems with the samples collected upstream of BFNP. Even if all phytoplankton 3
in overbank water (8.6-0.6 mg/m ) and all phytoplankton located at 3
or below 3 m in the channel water (2.2-0.0 mg/m ) near the north overbank had been entrained, the chlorophyll a concentrations in the intake forebay could not have been obtained. Further evidence of problems with these upstream samples is the presence of pheophytin a and its absence in almost all of the intake forebay samples.
These results indicate a possible degradation of the samples after collection.
2 2 2 With a cross-sectional area of 2,590 m , 5,612 m , and 3,350 m and velocities of 0.071 m/s, 0.105 m/s, 0.071 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained into BFNP was 22 percent (Table 4). If the south overbank is excluded from the calculations, the transported zooplankton biomass entrained would be 28 percent.
30 Water Masses of June 8 1977 On June 8, 1977, with a river flow of 1,387 m/s and reservoir pool elevation of 169.39 m (555.73 ft) msl were sampled. The first water mass was sampled between 1300 nnd 1500 hours0.0174 days <br />0.417 hours <br />0.00248 weeks <br />5.7075e-4 months <br /> while BFNP was operating in helper cooling mode, and the second water mass was sampled between 1800 and 2000 hours0.0231 days <br />0.556 hours <br />0.00331 weeks <br />7.61e-4 months <br /> while BFNP was operating in an, open cooling mode.
Upstream oyerbank samples of the first water mass generally had greater concentrations of chlorophyll a, organic content, and suspended solids than did channel samples upstream of BFNP-at all depths (figure 9). Xn 3 m samples, chlorophyll a concentrations were significantly higher on the overbank than in the channel (Appendix D). Concentrations of chlorophyll a and suspended solids increased with depth in most upstream samples. Pheophytin a was absent except in two, 3 m overbank samples (Appendix G). The highest zooplankton biomass occurred in overbank samples ad)acent to the channel, and the lowest zooplankton biomass occurred in overbank samples obtained nearest the north shore (Figure 9).
Opposite the intake of BFNP, higher concentrations of chlorophyll a were present in intake approach and intake forebay samples than in channel samples at all depths. The lowest mean value of chlorophyll 3
a in intake forebay samples "was 1 mg/m greater than the highest mean concentration of chlorophy]1 n In chnnnc I samples (FiI;ure 9). Thc highest levels of suspended solids at surface, 1 m, and 3 m were found in the intake forebay. The highest levels of suspended solids at 5 m were found in the intake approach samples (Figure 9).
- 20. 8 ~ 7 .5 23.3 .8 6.0
- 23. 3.1 2.6 6.9 5.4 4.5 24.2 5.4 6.2 C Ch ZOO .0 12, 29 3.3 SS OC Ch -Zoo 6.6 .6 3.4 3.7 5.6 6.3 3.4 0.5 12.9 5.3 9,4 ~ ~
4' 5' 9.1 30 52 24.5 4.5 .5 Mason 28.2 6.4 4.1 Island C Zoo 2.2 4.8 SS OC h Zoo ~ Light 3 .6 2.6 ~
~ ~
~ ~
- 10. 6 ~ 8 5.9 ~
~ ~ ~
~ ~ ~ ~
- 10. 6 3.7 9.1 43 4' 2.3 0.0 3.9 3.3 0.3 23.4 4.1 7.
SS 0 Zfo 5.0 3.4 2.2
.0 44 5' 4.0 0.9 59 20.1 3.6 SSOC 2.1 Ch Zoo Surface 9.4 ~ 0 4.2
- 12. 3' 1.2 h Zoo 5.1 3.8 0.0 4.6 3.3 .1 6.2 2,9 1.4 6.f 3.1 i.a 71 9.2
- sample 7.2 3.8 2.2 4.3 1.9 35 lost 10.3 2.6 13.2 3.9 0.5 0.4 SS OC Ch SS OC Zoo 4J Ch Zoo Figure 9. June 8~ 1977. Water mass 1, suspended solids (SS) and organic in g/m and chlorophyll (Ch) and zooplankton (Zoo) in mg/m . content (OC)
32 Organic content in intake forebay samples was slightly higher than the organic content of the intake approach samples taken )ust outside
'the skimmer wall (Figure 9). .Pheophytin a was absent, except in two surface, intake approach samples (Appendix G). Highest zoo-plankton biomass was found in the intake forebay.
Dye studies were not conducted concurrently with this water mass, however, they were conducted the preceeding day. Plant operating conditions for this water mass were similar to those during the preceeding day, however, river flows were higher. It is probable that these higher flows wouldn't have affected the relative proportions of the water coming into the intake from the overbank and channel.
Therefore, it can be assumed that approximately 60 percent of the water in the intake forebay came from the north overbank (all depths) and. 40 percent from the channel (3 m and below). The range of chlorophyll a concentrations in the intake forebay (6.9-5.5 mg/m )
3 indicates that although the proportion of overbank vs channel water in the intake was 60:40 the overbank (12.2-0.5 mg/m 3 ) supplied most of the chlorophyll a since the channel had very little (2.2-0.0 3
mg/m )., The absence of pheophytin a in almost all samples .indicates that the phytoplankton community was physiologically healthy.
With a cross-sectional area of 2,620 m , 5,640 m , and 3,397 m and velocities of 0.097 m/s,,0..142 m/s, and 0.097 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported, zooplankton biomass entrained into BFNP was 14 percent (Table 4). If the south overbank is excluded from the calculations, the transported zooplankton biomass entrained would be 19 percent.
33 Significantly higher concentrations of chlorophyll a and higher concentrations of organic content and suspended solids were present in overbank samples upstream of BFNP intake than were present in channel samples in the second water mass sampled on June 8, 1977 (Figure 10). Except in overbank samples nearest the north shore, where similar concentrations of chlorophyll a were present at all depths, concentrations of chlorophyll a, suspended solids, and organic content increased with depth in the water columns sampled.
Pheophytin a was absent, except for a small amount found in one overbank sample (Appendix G). Zooplankton biomasses were highest in channel samples from near the north overbank (Figure 10).,
Opposite the intake of BFNP, higher concentrations of chloro-phyll a and suspended solids were found in intake approach and intake forebay samples than in channel samples at all depths (Figure 10).
Except in surface samples, organic content was greatest in intake approach and intake forebay than in channel samples (Figure 10). The smallest mean concentration of chlorophyll' in the intake forebay 3
was nearly 2 mg/m greater than the largest concentration of chloro-phyll. a in channel samples either opposite or upstream of BFNP intake.
Pheophytin a occurred in small amounts in one 5 m sample from the intake approach, and in one 5 m sample from the intake forebay (Appendix G). Zooplankton biomass was greatest in the intake forebay, and second highest biomass occurred in samples taken just outside of the skimmer wall (Figure 10).
Dye studies were not conducted concurrently with this water mass. Although there had been an increase in intake water demand of
16,5 3.9 10. 5
- 17. 0 4.9 9~2 115 4.5 .6 18.8 4.7 10. 5 15. 4.9 .8 18.1 5~1 8.8 15.1 4.8 0 53 Ch Zoo SS OC C}1 ZOO
- 12. ~ 5 11.6 3.4 3.9 1 .2 12.4 4.1 5 '
102 1&.6 5.2 13.1 16.8 5 ' 8.5 Mason Island
- 20. 7 5.3 12 ' '4'4 3 Light ZOO SS OC C}1 ZOO~
~
~
~
~
12 ~ 1 4 .5 3.9 '
\
~ ~
~
~
19.8 6.0 4~ ~ ~ ~ ~ ~
~ ~
6.0 2.5 0.5 17.6 5.6 12. 6.4 2.9 1.4 12 ' 4.9 2.9 SS OC Ch ZOO
- 10. 2 4.6 5.6 20.1 4.1 9.6 3.8 3.9 SS OC Ch ZOO Surface 11.4 4' 5.5 lm 11.3 7. 1 C ZOO 5.6 3.1 0.1 10 ' 3.8 4.2 6.0 3;4 0.8 11.2 4.0 4' 5m 9.8 .0 1.3 10.0 4.5 2.9
~* no sample collected 4.8 2.7 3~0 SS OC C}1 ZOO SS OC Ch ZOO Figure 10. June 8~ 1977. Mater mass 2, suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) and zooplankton (Zoo) in mg/m .
35 3
24 m /s (20/), the same assumptions can be made for this water mass as those made for the water mass sample during the morning of this day. The range of chlorophyll a values in the intake forebay 3
(10.5-8.8 mg/m ) shows similar trends to those found for the water mass sampled during the morning. That is, most chlorophyll a enrrained into the intake had come from the north overbank (9.8-3.9 3 3 mg/m ) instead of the channel (2.9-0.1 mg/m ). The absence of pheophytin a in almost all samples indicates that the phytoplankton community was physiologically healthy.
2 2 With a cross-sectional area of 2,620 m , 5,640 m , and 3,400 2
m and velocities of 0.097 m/s, 0.142 m/s, and 0.097 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained into BFNP was 17 percent (Table 4). If the south overbank is excluded from the calculations, the transported zooplankton biomass entrained would be 22 percent.
Water Masses of June 9 1977 On June 9, 1977, low reservoir flow conditions had been established in order that special sLudius rciaLcd to Lhu diftus<<r discharge sy'stem ol BFHP could bc Performed. This presented unusual conditions not encountered during the sampling of previous water masses. The very low velocities indicated by the ENDECO Current Meters showed that the low reservoir flows were not sufficient to provide con-ditions=for following and sampling a water mass within a 2-hour time frame. Therefore, boats were aligned in the same manner as those specified in the materials and methods section for the second set of samples of each water mass (i.e., in line with the intake).
36 This low flow condition existed between 0800 and 1200 ho<<ra
<I<<r fng wit l<'I< I Irht t,w<<<<<n<I<l <<t <<<<nmI<la>> <<< ~ I << w<<rr < ol I <<t'.I <<d. 'I'1<v I'I<'<<I <<et. w<<<<<<:<I Le<<t<< I ln t.w<.en 0900 and l000 hours with a reservoir I'l<<w of 157 m/s; whl le the se<:on<I was <<: il le<:toet'ween 1100 a<el 1200 h<n<<s wit,l< a flow of 2ltI m/s. R<.servoir elevat:ion was 169.32 m (555. 52 ft) msl during this period .
In the first sample set no significant differences in chlorophyll a concentrations were present among samples from any dept:h (Appendix D). Mid-channel samples (sampling location 2) were highest in chloro-phyll a concentrations (Figure ll). Suspended solids increased with depth in channel and ad)acent intake approach samples. Pheophytin a was absent, except in one 3 m channel sample, and in one 3 m and one 5 m intake forebay sample (Appendix G). The highest zooplankton biomass was found in the intake forebay (Figure 11).
Under these low flow conditions, the hydrological influence of the intake would extend further into the main channel and possibly included some water immediately downstream. It is likely that a greater proportion of water in the intake came from the channel rather than the north overbank because water in the channel had little downstream inertia. The chlorophyll a concentrations in the intake forebay (2.1-1.3 mg/m 3 )'compared .
to that at sampling locations 3
outside the skimmer wall (5.7-0.4 mg/m ) indicate that the chlorophyll a in the intake could have come from all outside sampling locations.
The absence of pheophytin a in almost all samples indicates that the phytoplankton community was physiologically healthy.
12.8 2.9 1.5 13.6 3.9 2.1
- 13. 3 4.9 1.8 54
- 13. 3 .5 1.3 Ch ZOO 3.7 ~ 4 4.6 2.8 ~ ~
5 7 3;7 Ifason Island SS OC Ch ZOO ~ ~ Light
~
4.5 3.3 .9 ~ ~ ~
~
4.9 3.2 2.5 ~ ~ ~ ~ ~ ~ ~ ~
~
6.7 3.5 2.1 27 10.4 3.8 0.8 SS OC Ch ZOO 6 ' 3.2 5.2 6' 4.5 5 7
--Surface 6.6 3.8 3.9 1m 25 9.1 3.6 3.7 ZOO 7.5 37 . 04 8, 2.9 1.2 11.6 3.4 1.4, 47
- sample lost 14.6 4.7 3.6 SS OC Ch ZOO
, Figure -11. June 9 1977. Water mass 1, suspended solids (SS)'and'organic content (OC) in g/m and chlorophyll (Ch) and zooplankton (Zoo) in mg/m3.
38 The percent'age of the transported zooplankton biomass entrained into BFNP could not be determined because of the low reservoir flow.
These data show the biomass in the intake forebay to be twice as much as that at all sampling locations except sampling location 1 where the biomass was similar to the intake (Figure ll). These data probably reflect the normal patchy distribution of the zooplankton.
In the second sample set, no significant differences in chlorophyll a were seen among sampling locations at any depth (Appendix D). The highest levels of suspended solids and organic content were found in the intake forebay at surface, 1 m, and 3 m (Figure 12). The next highest levels of suspended solids and organic content were found at surface, 1 m, and 3 m just outside the skimmer wall. At 5 m, highest levels of organic content and suspended solids were just outside the skimmer wall, with the second highest levels in the intake forebay. Pheophytin a was present in only one surface channel sample (Appendix G). Zooplankton biomasses were highest inside the intake forebay, and next highest just outside the skimmer~wall. Levels of organic content, suspended solids, and zooplankton were generally much less'n the outer intake approach and channel samples (Figure 12).
Similar comments may be made about the second water mass sampled on June 9, 1977, that *have already been made concerning the first water mass sampled on that date.
Water Masses of Jul 5 1977 On July 5, 1977, two water masses were sampled. The first water mass was sampled between 0900 and 1100 hours0.0127 days <br />0.306 hours <br />0.00182 weeks <br />4.1855e-4 months <br /> with a river flow
19.0 5.3 3.1
- 17. 3 5.1 3.3 108 20.4 5.3 2.6 16.4 C 4.0 2.2 OO
.3 5.4 7~ 4.3 7.7 63
- 12. 4.6 8.4 Mason
- 28. 0 6.3 7.0 island ZOO Light
~
~
6.1 3.7 1.8 ~ ~
~ ~
7.4 .8 1.4 ~ ~ ~ ~ ~
~ ~ ~ ~
5.4 0.1 16.0 3.7 0.1 SS OC Ch OO
- 6. .8 .1 6, 4~0 .8 2.
SIIr iaCe 5.6 2,9 4.0 28 7.1 OC 2 ' 2.3 ZOO 6' 4~4 5.0 6~ 4.0 6.1
- 6. 3.3 4.3 32 6~6 3.9 3.1 SS OC Ch ZOO Figure 12. June 9~ 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Qh) and zooplankton (Zoo)'in mg/m .
40 rate of 510 m/s while BFNP was operating in a mixed cooling mode (combination of helper and closed modes). The second water mass was sampled between 1400 and 1600 hours0.0185 days <br />0.444 hours <br />0.00265 weeks <br />6.088e-4 months <br /> while BFNP was operating in closed cooling mode and with a river flow rate of 1,040 m/s.
Reservoir pool elevation was 169.20 m (555.12 ft) msl during this period.
These plant operating conditions resulted in heated water at the sampling location in the intake forebay (Table 5). Under mixed mode (first water mass) this heated water was about two meters deep 0
and was 1-2 C warmer than ambient water at the other depths (2 m to bottom, 8 m). Under closed mode (second water mass) the heated water was about six meters deep and was 2-4 0 C warmer than ambient I
water at the lower depths (6 m to bottom, 8 m).
In samples of the first water mass upstream of BFNP, the highest concentration of chlorophyll a was present in the channel nearest the south overbank (Location 1), and lowest concentrations of chlorophyll a were present at the surface and 1 m in mid-channel (Figure 13)., Overbank and channel levels of organic content were
- ~lmllar (Figure L3). Pheophytin'a was present in only two channel samples (Appendix G). Zooplankton biomasses were highest in channel samples from near the north overbank (Figure 13).
In surface and 1 m samples taken opposite the BFNP intake, highest concentrations of chlorophyll a were present in channel samples from near the south overbank (Figure 13). Lowest concen-trations of chlorophyll a in surface and 1 m samples were obtained inside the intake forebay. Organic content was similar in all water columns sampled. Suspended solids were highest in intake
41 Table 5. Temperature Data Collected in the Intake Forebay of BFNP During Mixed and Closed Cooling Modes, July 5, 1977 Mixed Cooling Mode Closed Cooling Mode (Morning) (Afternoon)
Depth (m) Tem erature ( C) Temperature ( C)
Surface 31.9 33.0 2 30.5 32.9 3 28.5 32.9 4 28.5 32.5
,5 28.5 32.2 6 28.5 31.3 7 28;5 28.8 8 28.4 . 28.8 a Combination of helper and closed cooling modes
3.5 ~ 3 4~3
- 14. 2 4.1 13.4 4.1 5.8 151 ~ 5 6.1
.6 5~0 7.7 15.8 4.2 C
4.7 14. 1 4.6 4.8 40 Ch ZOO 6.6 SS OC Cjl ZOO 4.1 5 5~ .2 5 '
4.3 4.5 8.1 5.0 8.3 ~ ~
8.9 4' 5.8 12. 4~7 5 ' 27
)17
.0'ason 13 ' 4.3 502 6.1 Island ZOO SS OC ZOO ~
~ Light
- 5. 3a ~ 4.9 ~
e 7.7 4.8 8.4 ~ ~ ~ ~ '
~ ~ ~ ~
~
5 4.7 3.4 2.4 ll.7 5 1 8.2 5.0 3.3 2.7 4.E . 6.1 SS OC Ch 00 8.0 3.3 1.9 3~ 3.8 4.3 1.2 2.8 5.2 11 '
SS OC 3.7, 0.8 Ch ZOO Surface 5.6 ~ 3 3.3 lm 33
- 9. .6 2.1 S OC 5 '
Ch 5.1 ZOO 14 '
5~8 4.3 13. 8 7.5 4.7 19 ' 8~8 .6 17 ~ 3 Sm F 1 307 4 8 34
~ sample lost 5 1 3.3 3 '
26 3.4 4.2 3.3 1.5 3. 2.1 SS OC Ch ZOO SS OC ZOO Figure 13. July 5 1977. Water mass 1, suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) and zooplankton (Zoo) in mg/m3.
43 forebay samples (Figure 13). Pheophytin a was absent, except in four intake approach samples (Appendix G). Zooplankton biomass was lowest gust outside the skimmer wall, and highest inside the intake forebay (Figure 13).
Dye studies were not conducted concurrently with this water mass. However, the ratio of intake demand to reservoir flow (1:12) for this period was similar to that during the dye studies conducted on June 7, 1977, which had a ratio of 1:10. Therefore, it can be assumed that the relative proportion of water coming into the intake from the north overbank (approximately 63/) and channel (approximately 37/) were similar for the two periods.
Chlorophyll a concentrations in the intake forebay were strat-ified with lower concentrations in the heated water and higher concentrations in the ambient water. Chlorophyll a concentrations fn <he ambient water were similar tn ron< ant raL1ons whfql) wn>llcl l)~
expected to be in the entrained overbank water (all depths) and channel water (3 m and below). The presence of chlorophyll a in the heated water indicates that some phytoplankton had not been destroyed by passage through the plant's condenser system and cooling towers. The absence of pheophytin a in this heated water is unexpected and cannot be explained.
The stratification of water in the intake forebay possibly had an effect on the zooplankton biomass samples because the zooplank-ton net sampled water from near bottom to surface. Hence, the samples were composed of zooplankton from six meters of ambient
'4 water (bottom to 2 m) and two meters of heated water (2 m to surface).
Since the source of the zooplankton in the top two meters cannot be defined, these data must be interpreted with some caution. A lowering of biomass after passage through the plant's cooling system would be the expected effect. However, the biomass in the intake .
forebay was much higher than that at the other sampling locations.
This high biomass cannot be explained with the data at hand.
Therefore, even though the percentage of the transported biomass entrained has been calculated based on this unexplainable high bio-mass, this percentage cannot be used for conclusive purposes.
The percentage of the transported zooplankton biomass entrained under the existing conditions with cross-sectional areas of 2 2 2 2,485 m , 5,510 m , and 3,180 m and velocities of 0.036 m/s, 0.052 m/s, and 0.036 m/s for the north overbank, channel, and south overbank, respectively, was 26 percent (Table 4). IE the south ovcrbank is excluded from the calculations, the transported zoo-plankton biomass entrained would be 31 percent.
In the second water mass, upstream of BFNP, surface concen-trations of chlorophyll a were similar in channel and overbank samples (Figure 14). At 1 m, channel samples were significantly higher in chlorophyll a than overbank snmpLes. However, more chlorophyll a was present in 3 m overbank than in 3 m channel samples.
No pheophytin a was detected in any upstream samples (Appendix 0). The highest zooplankton i on< <<ntrat ion was present fn charm(.l samples near the south overbank (Figure 14).
19.8 4' 2~9 20.4 4.0 2.7
- 11. 7.7 .0 19.9 4 3.3 6' .2 ~ 3 25 23.1 4.6 ~ 9
- 10. 8 F 7 9~2 33 C Zoo 4 SS OC Ch Z oo
~ 4 7~4 5.3 5~7 1~8
.1 8.7 6.6 5.0 F 1 0
7.2 3.7 ,0'aso>>
13.8 9.3 .8 4.0 9~3 8.8 Zoo 30.
15.6 3 7.6 Ch Zoo ~
~ ~
l:s ~
L- @.=-.
j ~ ~
5.9 3.8 10.5 ~ ~
6.0 4.3 .6 ~ ~ ~ ~ ~ ~ ~
9' 7.2 12.1 7~6 4 ~4 2.9 7' ~ 3 4.9 14 ~ 7 '4.9 7.2 i-.~, 9 0
SS 0 C Zo 16 ' 6.5 6.1 k.g 5.6 5~5 18.2 7~2 70 SS OC Ch Zoo Surface 6.4 4~0 5.
lm 9.0 F 1 11.4 Zoo 3 4 3.4 9,9 3m 4.0 F 1 6~ 7~0 .8
- no sample collected 3~6 5~3
'7 4.7
~ 2 18 ~
- 13. 7'8.3 49
- 11. 3
~ 5 5
~ 8 4.4 4g9 SS OC Ch Zoo:
SS OC Ch Zoo Figure 14. July 5'- 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m and chlorophyll (Ch) and zooplankton (Zoo) in mg/m3.
46 In the intake forebay, uniformly high levels of suspended solids were present at all depths. Pheophytin a was present in some surface and 1 m samples (Appendix G). Concentration of chloro-phyll a and zooplankton biomass were much lower inside the intake forebay than opposite the skimmer wall (Figure 14).
Opposite the skimmer wall, more chlorophyll a was present in surface and 1 m samples in the channel than in the intake approach.
Similar levels of suspended solids were found at the surface and 1 m in channel and intake approach samples (Figure 14). Pheophytin a was present in two samples from the intake approach location near the channel (Appendix G). Zooplankton biomass was highest in the channel and adjacent intake approach.
Since the plant was operating in the closed cooling mode and temperature data showed that the heated water extended to a depth of six meters at the sampling location in the intake forebay (Table 5), all chlorophyll samples were collected from water that had passed through the plant's cooling system. The chlorophyll a concentration at all depths in the intake forebay were about three times lower than would be expected to be in the intake forebay if overbank water (all depths) and channel water (3 m and below) had been entrained. Pheophytin a was present in some intake forebay samples indicating degradation of some phytoplankton r
during passage through the plant's cooling system. 1 a
The zooplankton biomass in the intake forebay was much lower than at other sampling locations. This was probably because most
47 of the water sampled had circulated through the cooling system.
When these data are used to calculate the percentage of transported zooplankton biomass entrained into BFNP (cross-sectional areas of 2 2 2 2,485 m , 5,510 m , and 3,180 m and velocities of 0.073 m/s, 0.107 m/s, and 0;073 m/s for the north overbank, channel, and south overbank, respectively) they show only 0.3 percent entrainment, including or excluding the south overbank (Table 4).
Water Masses of Jul 19 1977 t
On July 19, 1977, low reservoir flow conditions were established in order for dye studies to be conducted (Vol. 2). These dye studies were designed to determine the proportion of overbank vs.
channel water coming into the intake under low flow conditions.
Since the dye was an easily visible means of following a water mass, a water mass was followed and sampled between 0900 and 1100 3
hours with a reservoir flow of 227 m /s (Table 1) and an elevation of 169.27 (555.34 ft) msl. The plant was operating with units 1 and 3 in helper mode and unit 2 in open mode.
Upstream of BFNP, significantly morc chlorophyll a was present in sII> I'!'!~, I !'!,:liI<! ) >!! !<VHIi!I!Ik shttlpl~s ht'H}Hst.ho I>ok't)I slibk'4 I:I!an in all other upstream sampling areas (Appendix D). As sampling began, a barge passed, and extremely high suspended solids (37.3 g/m 3 ), and slightly higher organic content were present in channel samples from near the north overbank (Figure 15). Pheophytin a was absent in all channel samples except for one 5 m channel sample, but was present in 1 m and 3 m samples from the north overbank (Appendix G). Zooplankton biomass was highest in the channel near the north overbank, with the second highest zooplankton biomass found in overbank water near the north shore (Figure 15).
11 ~ .4 .0 12.1 .2 .6
~ 4 3.7 12. 7 3~6 8.0 12 3~5 ~ 4
~ 0 3.8 Ch ZOO 13.5 .8 7 ' 47 SS OC Ch ZOO
.0" 4 6 7.8 3 1 1~9 4.6 2 3 7.4 4 1 1.4 9.6 4.5 .6 7.3 3.2 2.8 Mason 31 ,~
10.6 4.2 .2 ~
Island C C ZOO 8~2 SS OC 3~ 5 3.1 .
Light ZOO 2 .1 3.6 ~
4o ~ ~
~ ~
5~7 .3 3a4 ~ ~ ~ ~ ~ ~ ~ 0
~ ~
18 ~ 7 1 2.9 7.0 ~ 0 3.0 32 23. 2
~
.6 2.8 12.6 4 ~4 2.8.
SS OC Ch Zoo 28.0 4~8 2.8 7.1 3.7 1.9 7.9 4.1 2.1 72 37 3m 5~6 2.7 SS OC Ch ZOO Surface 8..8 3.6 .4 lm 9~8 3.2 2.3 SS C 'Ch 3m 6.5 2L 8 ZOO 2.3 5' 3.3 1.6 7.1 2 9 1.6 6 ' 3.7 1.2 Sm 6~ 2.5 7' F 7 1.1
]
6.4 4' 2' 9.1 3.3 1.8 SS OC Ch ZOO SS OC' Ch ZOO Figure 15. July 19, 1977. Water mass 1, suspended solids (SS) and organic in g/m3 and chlorophyZE (Ch) and zooplankton (Zoo) in content(OC) mg/m3.
Opposite the intake, no significant differences in levels of chlorophyll a or organic content were. found among samples at all depths. Both chlorophyll a and organic content varied similarly at all depths in the water columns sampled. Pheophytin a was absent in all but one 1 m channel sample, but was present in 1 m and 3 m samples in the intake forebay. Zooplankton biomass was highest (Figure 15) in channel water (sampling location 2).
Dye studies (Volume 2) conducted concurrently with the water mass sampled showed that all of the north overbank water was entrained by BFNP and constituted 53 percent of the water entering the intake.
The remaining 47 percent came from the area of the channel near the north overbank at depths 3 m and below'. The range of chlorophyll a 3
concentrations in the intake forebay (5.0-3.7 mg/m ) indicates the probable entrainment of phytoplankton located in water from the north 3
overbank (8.4-1.4 mg/m ) and phytoplankton located at and below three 3
meters in the channel (3.9-1.1 mg/m ) near the north overbank, with the north overbank supplying most of the phytoplankton in the intake forebay.
2 2 2 Mith a cross-sectional area of 2,533 m , 5,556 m , and 3,258 m and velocities of 0.016 m/s, 0.023 m/s and 0.016 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained into BFNP was 56 percent (Table 4). If the south overbank is excluded from these calculations, the transported zooplankton biomass entrained would be 69 percent.
The high percentage of entrainment was apparently related to the low reservoir flow conditions.
50 Diel Stud Jul 20-21, 1977 On July 20 and'21, 1977, a diel study was conducted to analyze possible diurnal and nocturnal fluctuations in entrainment of the plankton. The plant operated with units one and three in helper mode, and with unit two in open mode. River flow rates ranged between 1,275 3
and 765 m /s, with lowest rates from 0100 to 0600 hours0.00694 days <br />0.167 hours <br />9.920635e-4 weeks <br />2.283e-4 months <br />, July 21, 1977.
3 At other times, flow rates fluctuated between 1,275 and 1,019 m /s. The first water mass was sampled July 20 between 1900 and 2100 hours; the second water mass on July 20 and 21 between 2300 and 0100 hours; the third water mass on July 21 between 0300 and 0500 hours0.00579 days <br />0.139 hours <br />8.267196e-4 weeks <br />1.9025e-4 months <br />; the fourth water mass on July 21 between 0700 and 0900 hours0.0104 days <br />0.25 hours <br />0.00149 weeks <br />3.4245e-4 months <br />; the fifth water mass between 1100 and 1300 hours0.015 days <br />0.361 hours <br />0.00215 weeks <br />4.9465e-4 months <br />; and the sixth water mass on July 21 between 1600 and 1800 hours0.0208 days <br />0.5 hours <br />0.00298 weeks <br />6.849e-4 months <br />. Reservoir pool elevation was 169.38 m (555.70 ft) msl on July 20 and 169.40 m (555.79 ft) msl on July 21.
First Water Ness of the Diel Stud , Jul 20 1977
'I In the first water mass of the diel study, samples taken upstream of BF)1P, at all depths had significantly higher concentrations of chlorophyll a and higher levels of.suspended solids and organic content in overbank samples than in channel samples (Figure 16).
Pheophytin a was present in small amounts in 'three overbank samples, and was absent in channel samples (Appendix G). Zooplankton biomasses in overbank and channel water columns were similar (Figure 16).
In the intake approach and intake forebay, significantly higher concentrations of rh]orophyl1 a were found 4n surface, 1 m, and 5 m samples than were found in channel samples (Appendix D). The intake approach and intake forebay had higher concentrations of chlorophyll a at 3 m, and higher levels of organic content and suspended solids
j 0 l
I
~ ~
I
~ ~
J ~
~ ~
~ ~
~ ~
~ ~
~ ~
~ ~
)
I
'I
~ 0
~ ~
~ ~
~ 0
~,
~ ~
I ~ ~
~ ~
~ ~ ~ ~ ~ I '
~ ~ ~
~ I I I ~ Jl ' < I ~ ~ ~ '
~ ~ ~ ~ ~ ~ I ~ ~ ~ II + II
52 at. all depths than did channel water (Figure 16). Pheophytin a occurred only in surface, 1 m, and 3 m intake forebay samples
'I (Appendix G). Zooplankton biomasses were higher in the intake forebay than in the channel but less than in the intake'pproach samples (Figure 16).
4 Dye studies were not conducted concurrently with this water mass.
However, the,,ratio of intake demand to reservoir flow (1:13) for this period was similar to that during the dye studies conducted on June 7, 1977, which had a ratio of 1:10. Therefore, it can be assumed that the relative proportion of water coming into the intake from the north overbank (approximately 63/) and channel approximately 37/) were similar for the two periods.
Chlorophyll a concentrations in the intake forebay (13.9-12.0 mg/m 3 ) were higher than can be explained by the entrainment of phytoplankton located in water from the north overbank (13.0-2.1 3
mg/m ) and phytoplankton located at and below three meters in the channel (7.2-2.1 mg/m 3 ) near the north overbank. This additional chlorophyll a in the intake forebay cannot be explained with the data at hand.
2 2 2 With a cross-sectional a'rea of 2,613 m , 5,633 m , and 3,386 m and velocities of 0.089 m/s, 0.130 m/s, and 0.089 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass ent'rained by BFNP was 18 percent (Table 4). If the south overbank is excluded from these calculations, the transported zooplankton biomass entrained would be 25 percent.
Second Water Mass of the Diel Stud Jul 20-21 1977 No significant differences among overbank and channel samples of chlorophyll a, organic content, and zooplankton were present upstream of BFNP (Figure 17, Appendices C, D, and E). Overbank concentrations of chlorophyll a and organic content were slightly
'greater at, 3 m than at 1 m. Chlorophyll a and organic content varied similarly in all water sampled. Suspended solids increased with depth in both channel and overbank water and similar levels of suspended solids were found at all depths in both channel and over-bank samples (Figure 17). Pheophytin a was present at surface, 1 m, and 3 m in the channel samples near the north overbank and at 3 m in channel samples near the south overbank but was absent in overbank samples (Appendix G). Channel samples near the north overbank con-tained the highest zooplankton biomass.
Opposite the intake of BFNP, significantly higher concentrations of chlorophyll a were found in surface samples in the intake forebay than in all surface samples obtained outside the skimmer wall (Appendix'D). At 1 m and 3 m, significantly more chlorophyll a was found in the intake forebay and in samples obtained just outside the skimmer wall than in all other samples opposite the skimmer wall at these depths. No significant differences were found for chlorophyll a concentrations at 5 m. Pheophytin a was present in channel samples, in one 3 m sample just outside the skimmer wall, and in all 5 m samples in the intake forebay (Appendix G). Organic content and zooplankton biomass were lower in the intake forebay and intake approach just outside the skimmer wall than they were
9.3 2~9 9~ 7 2.8 9.3 79 3.2 4' 3~1 7.6 .0 .9 3~8 9.4 Po 2 7.4 ZOO 74 .8 53 SS OC ZOO 4.5 .5 .7 4.5 3.7 3.5 2.3 6.9 4' 3 ' 3~3 ~ ~
68 70 7.7 2' 9~2 .0 6.1 Mason
- 11. 7 2.5 7' 3 , ~
Island C ZOO SS OC Ch ZOO ~
~ Light 4.5 3~3 3. ~ 7 ~ ~
~ ~ ~ ~
9.9 3.1 3~7 '
~ ~ ~ ~
~ ~
~ ~
5.0 3.2 1.3 7~ 2.9 5~0
' 3.9 5 1.5
- 10. 4.3 9.2 6' 3.0 1.7 SS OC Ch ZOO 76 5.9 3~3 3.3
- 6. .6 3.3 5~6 3~9 90 SS OC Ch ZOO SurEace 6.9 3.2 3.3 6.7 3.0 3~2 S OC 3m 5.8 2.1 2.3 6' 3.6 3.7 6' 7 2.2 60 ~
55 7Q 4' 3.8 6~3 2.3 1.6
~ sample lost
~~'o sample collected 7~ 3.6 3.9 7.2 SS OC
.1 Ch ZOO SS OC Ch ZOO Figure 17. July 20, 1977. Water mass 2, suspended solids (SS) and organic content (OC) in g/m3 and chlorophyll (Lh) and zooplankton (Zoo) in mg/m3.
55 in channel samples or intake approach samples adjacent to the channel (Figure 17).
Dye studies were not conducted concurrently with this water mass. However, the ratio of intake demand to reservoir flow (1:9) for this period was similar to that during the dye studies conducted on May 18, 1977, which had a ratiofthm't of 1:9. Therefore, it can be assumed that the relative proportion of water coming into the intake I t t it t hatt tz"t t (~ " i t l1utlI. $ Ipptnxl(~ y 'i'iP'J ntg0 c taxanc,.l (:rpprnximately 45X) were similar for the two periods.
3 Chlorophyll a concentrations in the intake forebay (7.7-7.1 mg/m )
were higher than can be explained by the entrainment of phytoplankton 3
located in water from the north overbank (6.1-3.2 mg/m ) and phyto-plankton located at and below three meters in the channel (1.7-1.6 3
mg/m ) near the north overbank. This additional chlorophyll a in the intake forebay cannot be explained with the data at hand.
2 2 2 With a cross-sectional area of 2,633 m , 5,653 m , and 3,420 m and velocities of 0.065 m/s, 0.096 m/s, and 0.065 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained into BFNP was 14 percent (Table 4). If the south overbank is excluded from these calculations, the transported zooplankton biomass entrained woul'd be 17 percent.
Third Water Mass of the Diel Stud , Jul 21 1977 Samples from overbank water upstream of BFNP had slightly higher concentrations of chlorophyll a, and higher levels of organic content, suspended solids, and zooplankton than samples from upstream channel water (Figure 18). Pheophytin a was present in a few samples from both overbank and channel waters at all depths (Appendix G).
8.1 ~ 1 5.6 9 ' .4 .6 80 9.0 ' 9. 4.0 8.1 4 6.6 4.3 8.9 9' C6 6.3 C ZOO 16 ~ 5.2 9.1 69 SS OC Cjl ZOO
.9 a
'.6
- 10. 2 3.9 8~0 3.5 6.6 5.7 3~ 3 3~2 80 72
- 11. 0 3.4 8.6 11 6.6 Mason
- 11. 9 3.3 9.9 12.8 4~8 Island C ZOO SS OC Ch ZOO ~
~ Light 6.8 2.9 2.7 ~ ~
~ ~
7.0 3~2 ~ 8 ~ ~ ~ ~
19.2 100 9~ 3.5 2 7 4~7 3.2 9~0 3.0 2.2 15.3 3~6 3.1 65 SS OC 6'
Ch ZOO 6 ' 2.4 2.5
~ 1 .8 6' ~ 3 ~ 2 8~1 3~9 SS OC C}1 ZOO 5'J>> ace 8. .2 .8 46 8~
S OC 3~0 Ch 2.7 ZOQ 6~0 4.5 .2 7 0 ~ 3 2~5 5~7 3.7 ~ 7 9.2 ~ 2 1.9 58
- no sample collected 6~8 3~8 2.4 8 ' ~ 6 2.7
~ sample lost 7~0 3.9 2.9 9.
SS OC C}1 ZOO SS OC Cjl ZOO Figure 18. July 21, 1977. Water mass 3, suspended solids (SS) and organic content (OC) in g/m 3 and chlorophyll (Ch) and zooplankton (Zoo) in mg/m ~
57 As the water mass moved opposite the skimmer wall, significantly higher amounts of chlorophyll a were present in surface samples iri the intake forebay than in the intake approach, and higher in the intake approach than in the channel. However, at 1, 3, and 5 m the intake approach near the skimmer wall had the highest chlorophyll a concentrations with values in the intake forebay almost as high.
Pheophytin a was present in two surface channel samples, in two 4
surface samples of the intake forebay, in a single collection from a 5 m channel sample, in 5 m samples just outside the skimmer wall, and in 5 m samples in the intake forebay. Organic content was highest in channel samples and lowest in the intake forebay. Zooplankton biomass was highest in intake approach and intake forebay samples and lowest in channel samples.
Dye studies were not conducted concurrently with this water mass.
However, the ratio of intake demand to reservoir flow (1:8) for this period was similar to that during the dye studies conducted on May 18, I'0/, whit'h had n mt l<> <il I l. Th~rcil iit', It e'tuI he neinnilrd that the relative proportion of'water coming into the intake from the north overbank (approximately 55X) and channel (approximately 45/)
were similar for the two periods. The range of chlorophyll a con-3 centrations in the intake forebay (6.6-5.6 mg/m ) indicates the probable entrainment of phytoplankton located in water from the north 3
overbank (9.1-3.2 mg/m ) and phytoplankton located at and below three meters in the channel (2.7-2.5 mg/m 3 ) near the north overbank, with the north overbank supplying most of the phytoplankton in the intake forebay.
58 2 2 2 With a cross-sectional area of 2,633 m , 5,653 m , and 3,419 m and velocities of 0.055 m/s, 0.081 m/s, and 0.055 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained was 17 percent (Table 4). Xf the south overbank is excluded from these calculations, the transported zooplankton biomass entrained would be 23 percent.
Fourth Water Mass of the Diel Stud Jul 21 1977 Upstream of BFNP, significantly higher concentrations of chloro-phyll a and higher suspended solids and organic content were present in overbank samples than in channel samples (Appendix D, Figure 19).
Levels of chlorophyll a, suspended solids, and organic content varied only slightly with depth. Small amounts of pheophytin a were found in one channel and one overbank sample (Appendix G). Zooplankton biomass was low in all samples, although slightly more biomass was
'present in overbank than in channel samples (Figure 19).
Significantly higher concentrations of chlorophyll a were found in surface and 1 m samples in the intake forebay and just outside the skimmer wall than were found in other samples taken opposite and further away from the skimmer wall (Appendix D). No significant differences among chlorophyll a concentrations were found in samples ob'tained from 3 m and 5 m depths. Organic content and suspended
.solids were higher in the intake approach than in channel water (Figure 19). Pheophytin a was present in small amounts in a few surface and 1 m intake approach samples and 1 and 3 m channel samples
'(Appendix G).. Zooplankton biomasses were low and not significantly different; however, the highest concentration collected was in the intake forebay (Figure 19).
12;6 2 ' 5.7 13.6 F 7 7.0 13.4 3~8 .5 15.2 2.5 9.3
- 16. .1 9' 13.3 8 .6 17,0 .6 20 SS OC ZOO
- 18. 4~9 9.3 13.1 2' .9 23.5 6~1 9' 16. .1 8.4 ~ ~
11,4 4.7 8.3 20.6 2.7 29 Mason 15.2 5~0 7.2 12 3 -
~ Island SS OC Ch ZOO
~ ~ ~
~ Light 4.0 3.2 .8 4 ~ ~
7.2 3.7 ~ 3 ~ ~ ~ ~ ~
~ ~
i 7 5.8 2.9 1.2 7.3 3.5 6~7 3.4 0.9 18.7 5.3 SS C 7.2 3 1.3 3.4 %.2 i".7 15 6.6 K.4 1. 9 9' 2.3 2.2 I SS OC Ch Zoo Surface 6.4 ~ o2 7.5 I" 2' 3m Ga8>
6~
1.6
.4
'.2 1.4 5.8 6.3 ~ 3 1.0
.2 5m 6' ,2
- no sample collected 6' 2.1 1.8 is 23 6.9 2' 0.8 8~ 2.2 2.2 SS OC Ch g
ZOO Ln
';SS OC Ch ZOO Figure 19. July 21, 1977. Wetter mass 4, suspended solids (SS) and organic content (OC) in g/m3 and chloreqphyll (Ch) and zooplankton (Zoo) in mg/m3.
60 Dye studies were not conducted concurrently with this water mass.
However, the ratio of intake demand to reservoir flow (1:ll) for this period was similar to that during the dye studies conducted on June 7, 1977, which had a ratio of 1:10. Therefore, it can be assumed that the relative proportion of water coming into the intake from the north overbank (approximately 63%) and channel (approximately 37%) were similar for the two periods. The range of chlorophyll a 3
concentrations in the intake forebay (7.0-5.7 mg/m ) indicates the probable entrainment of phytoplankton located in water from the 3
north overbank (9.6-7.5 mg/m ) and phytoplankton located at and below 3
three meters in the channel (2.2-0.8 mg/m ) near the north overbank, with the north overbank supplying most of the phytoplankton in the intake forebay.
With a cross-sectional area of 2,633 m , 5,653 m , and 3,419 m and velocities of 0.075 m/s, 0.113 m/s, and 0.075 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained was 16 percent (Table 4). Xf the south overbank is excluded from these calculations, the transported zooplankton biomass entrained would be 22 percent.
Fifth Water Huss of tl)c 1)ic.l SLudy, .Iillg 2I,"I 1977 In upstream samples of the midday water mass, highest concen-trations of chlorophyll a were found at surface, 1 and 3 m on the overbank. Overbank and channel samples had similar chlorophyll a concentrations at 5 m (Appendix D). Suspended solids were highest in overbank water at 1 m and 3 m, and increased with depth in both overbank and channel water (Figure 20). Pheophytin a was present in
13.0 3.9 10 '
13.7 4.1 8.9 12 ' LJ ~ 7 10. 5 .2 2' 6.7 27 1 ~ 3.5 10.1 13.7 2.7 9 '
C Ch Zoo 17. 2 4 ' 12e9 35 SS OC Ch Zoo llew
.1 9' 2.8 1.9 .0
'.3 0.5 6.0 2.1 5.9 9.4 3.5 10 F 9 17.9 3.4 30 .~ Mason 16.0 3.6 %% 3 , ~ Island
- I.C Zoo SS OC Ch Zoo ~ Light
~
4.6 2.9 0~ 0 ~
~
5.8 3.5 0.9 ~ ~ ~ ~ ~ ~ ~ ~
~
'10 ~ 4 0 3. 0 1 .1 3.3 12. 0 6.7 4.0 2,9 17; 4.1 10.? I SS OC" Ch Zoo 7 ' 3.5 3e3 3~8 2~5 .5 21 5~0 2' 3.8 8~8 4.1 3.6 SS Oc Ch Zoo Surface 5. 2.0 4.5 lm
- 6. 2.2 5.4 S Oc C Zoo 5.1 2 3m ~ 1~7 4' 2.4 0;2 7' 3.6 1.6 6' 2. 3 2.-3 A Sm 5~7 2~2 2.5 6.5 3.1 1.9 28
~ no sample collected 23 115 t 36 25 7~5 2.7 SS OC Ch Zoo o SS OC Ch Zoo Ftsure 20. Jbxl7 21, 1977. rater mass S,.suspended solids (SS) and or~ante content ~00~
iin g/m3 and chlorophyll (Ch) and zooplankton (Zoo) in mg/m .
62 small amounts in one overbank and one channel surface sample, in two 1 m samples from overbank water nearest shore, and in five, 5 m samples from the channel. (Appendix 0). Zooplankton biomass in oyerbank samples was slightly higher than in channel samples (Figure 20).
Opposite the skimmer wall, significantly higher concentrations of chlorophyll a were found in the intake forebay and'n the intake approach than in the channel at surface, 1 m, and 3 m depths (Appen-dix D). The greatest concentration of chlorophyll a occurred in 3 m samples. At surface, 1 m, and 3 m, higher levels of suspended solids and organic content were present in the intake approach and in the intake forebay than in channel water (Figure 20). Pheophytin a was present in small amounts throughout the forebay water column, and at 3 m and 5 m in the intake approach (Appendix G). Zooplankton biomass was similar at all sampling locations (Figure 20).
Dye studies were not conducted concurrently with this water mass.
However, the ratio of intake demand to reservoir flow (1:10) for this period was similar to that during the dye studies conducted on June 7, 1977, which had a ratio of 1:10. Therefore, it can be assumed that the relat;ive proportion of water coming into the intake from the north overbank (approximately 63X) and channel (approximately 37/) were similar for the two periods. The range of chlorophyll a concentrations in the intake forebay (10.5-8.9 3 mg/m ) indicates the probable entrainment of, phytoplankton in water from the north over-bank (12.9-2.0 mg/m 3 ) and phytoplankton located at and below three mcLc>>> I>> ll>>> <'I>a>>>>el (3.6-I .9 mg/m ) near t.l>e north ovcrbank,
63 with the north overbank supplying most of the phytoplankton in the intake forebay. The concentrations of chlorophyll a in the intake forebay were slightly higher than would be expected from entrainment of north overbank and channel water, however, this difference was small and therefore not considered important. The presence nf
~llljri[itlgtli e Iu s le'w ~~vetbank and channel samples lntlicates that small amounts of phytoplankton in these areas were not physiologically healthy.
2 2 2 With a cross-sectional area of 2,633 m , 5,653 m , and 3,419 m and velocities of 0.071 m/s, 0.104 m/s, and 0.071 m/s for the north overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained was 8 percent (Table 4). If the south overbank is excluded from these calculations, the transported zooplankton biomass entrained would be 22 percent.
Sixth Water Mass of the Diel Stud , Jul 21 1977 In samples taken, upstream of BFNP, at all depths, higher levels of chlorophyll a, organic content, and suspended solids were found =
in overbank water than in channel water (Figure 21). Significantly higher concentrations of chlorophyll a and organic content were found in surface and 1 m overbank samples obtained nearest the shore.
Levels of suspended solids increased with depth in overbank samples, but were similar at all depths in channel samples. Pheophytin a was absent in all samples, except for small amounts in one surface and one 1 m channel sample (Appendix G). Zooplankton biomass was slightly higher in channel samples than in overbank samples (Figure 21).
%7.6 m..7 0.3 16.6 :is. 8 0.2 14.4 13. 5 8 4.2 24.2 51 1 4 5~3 27.7 Zi.8 11. 8 Ch 14 .6 14. 9 Zoo
'ecf ++
SS OC Ch ZOO
.21. 0 7.7 2.1 8~1 27 ~ 6 9.8 2.9 9.6 12 ~ 3 ~ ao 13 ' 13.8 3~6 ~ 5 Mason
'6.
16 7 4+3 Zoo SS OC Ch Zoo ~ ~ Light 7.:. 4 ~ 4. ~ ~
8.5.. 4.5 ~ ~ ~ ~ ~ ~
~ ~ ~ ~
- 7. ' 5.1 2.1 2.2 10.6 6' 2.6 4.4 2.6 7.0 5.6 SS OC Ch Zoo 2 ~4 3.6 4.3 2.5 2.8 6.4 3.8 6.1 6.2 2' SS OC Ch Zoo Surface 5. .8 .9 28 6.3 3.2 4.1 C Ch Zoo 3jjj 5. .8 .5 4.6 2 1 2.2 8.7 2.6 4.0 5jjl 7.1 '3. 3 6' 6.2 6. 2.4 3~0
- no sample collected 19 5. 2.5 6~8 .3 ~ 8 SS OC Ch Zoo SS OC Ch Zoo Figure 21. July. M1, 1977. Water mass 6, suspended solids (SS) and organic content (OC) in ggrrj3 and chlorophyll (Ch) and zooplankton (Zoo) in mg/m3.
Opposite the skimmer wall, chlorophyll a concentration at surface and 1 m were significantly higher in the intake approach near the skimmer wall than in the intake forebay or channel, and the intake forebay samples at these depths were significantly higher than those for tho channel. Concentrations of chlorophyll a at 3 m and 5 m were similar in the intake approach and intake forebay, while the concentration in the channel at these depths were lower (Appen-dix D). Pheophytin a was found only in two 5 m samples and two surface intake forebay samples (Appendix G). Zooplankton biomass was highest in the intake forebay (Figure 21).
Dye studies were not conducted concurrently with this water mass. However, the ratio of intake demand to reservoir flow (1:10) for this period was similar to that during the dye studies conducted on June 7, 1977, which had a ratio of 1:10. Therefore, it can be assumed that the relative proportion of water coming into the intake from I II<'orfII <<v< rl<ill<l< (I<I)pl'<lx Ill<<< I < I '/ 6 I/) <<II<I <'III<IIII< I
~
I<<I<I<I <<Y I mal <' '/
37%) were similar for the two periods. The range of chlorophyll 3
a concentrations in the intake forebay (13.4-10.2 mg/m ) indicates the probable entrainment of phytoplankton in water from the north 3
overbank (27.7-8.1 mg/m ) and phytoplankton located at and below 3
3 m in the channel (3.0-3.6 mg/m ) near the north overbank, with the north overbank supplying most of the phytoplankton in the intake forebay.
2 2 2 With a cross-sectional area of 2,633 m , 5,653 m , and 3,419 m and velocities of 0.071 m/s, 0.104 m/s, and 0.071 m/s for the north
69 84 79 80 32'5 40 2
70
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60 58 48 7-PM 11 3 7 AM ll 3 PM 23 23 7 11 3 7 11 3 PM AM PM Figure 22 Diel Study 20-21 July 1977. Zooplankton Momass mg/m (Times Are Approximate)
67 overbank, channel, and south overbank, respectively, the percentage of transported zooplankton biomass entrained was 30 percent (Table 4). If the south overbank is excluded from the calculations, the transported zooplankton biomass entrained would be 37 percent.
U stream Overbank and Channel Studies Sus3)ended solids and organ 3 c con I cut s1>owed s 3 i ght y hi gher 3 3 eve s 3
nl I and '3 m on the ovf rbank than in the channel at any depth sampled (Figures 23, 24, and 25). There was no trend toward increased or decreased suspended solids and organic content from the upstream to the downstream transect, Chlorophyll concentrations in both channel and overbank samples were consistently low at upstream transect 7 (TDf 298.4). The low values on all three sampling dates cannot be explained with the available data.
Chlorophyll concentrations increased from transect 7 to 6 to 9, sug-gesting that primary productivity increased as the water mass approached the intake. However, no consistent trends were noted for overbank versus channel chlorophyll concentrations. Surface and l m samples generally had the highest concentrations of chlorophyll a. Chlorophyll concentrations did not relate to organic matter levels, and neither of these was related to suspended solids values (Figures 23, 24, and 25).
f The low concentrations for pheophytin a in only a few of the samples indicated the phytoplankton communities were physiologiacally healthy (Appendix G).
Zooplankton biomass values showed a slight trend toward higher values for overbank samples when compared to channel samples
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73 (Figure 26). There was no trend toward increased or decreased zoo-plankton biomass from the upstream to the downstream transect (TRM
89 81 34 3I 68 45 59 16 66 f
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73 General Discussion: Ph to lankton Significantly more chlorophyll a occurred in overbank samples than in channel samples irmnediately upstream of the intake of BFNP. Higher chlorophyll a concentrations were found in water nearest the north shore than in overbank water adjacent to the channel. Therefore, most of the phytoplankton immediately upstream of the intake of BFNP was ll located in overbank water.
Further upstream at TRM 298.4 very low concentrations of chlorophyll a were found in both overbank and channel samples. As samples were obtained dhlwus) f>:ulg )
unlit.i:L<).s )I-(ulj.I
~ 'if cI( ) 4 ls')I) ~
I ) a ) hp f jg~~pl 4
)) bg)I( Qp~): j))I; and channel samples. The low values of chlorophyll a at TRM 298 .4 cannot be explained with the data at hand.
Most of the phytoplankton,entrained by BFNP originated on the over-bank. Intake concentrations of chlorophyll a and pheophytin a, while lower than those on the overbank were closer to overbank than to channel concentrations. Patterns of phytoplankton entrainment under various conditions (i.e., a range of reservoir flows, three unit plant operation, and open, helper, and mixed cooling modes) were similar in that almost all the phytoplankton in water coming off of'the north overbank in the vicinity of the plant was entrained. Exceptions to this entrainment pattern for phytoplankton were seen with May 18, 1977, samples in which phytoplankton in the top meter of overbank water passed by the intake of BFNP. This bypassing of plankton by the intake of BFNP was a result of the passage of a surface station of warmer overbank water over cooler overbank and channel water entering the intake. Phytoplankton entrained during mixed mode plant operation was similar to helper mode for the lower strata of intake forebay water (those strata not influenced by recirculation
24 of heated water), and most phytoplankton in the lower strata was derived from overbank water. Under closed mode operation phytoplankton entrain-ment was minimal.
As indicated by drogue studies, and vector velocity studies (Volume 2), most channel water (with its associated phytoplankton) entrained by BFNP was derived from lower channel strata. In most instances, only small amounts of chlorophyll a (and phytoplankton) were located in channel waters at these depths, so these strata contributed only a small amount of phytoplankton to that entrained in the intake.
A slight, but consistent, pattern of possible phytoplankton migration was seen in the diel study. Although phytoplankters, as indicated by chlorophyll a, were well distributed throughout the water columns sampled, slightly greater phytoplankton concentrations occurred in bottom overbank samples, than in surface or 1 m night samples. In the daylight hours of the dlel study, most phytoplankton were found in the top meter of overbank water. Reasons for the night time distribution pf chlorophyll a, and phytoplankton, in the water column are unclear.
Pheophytin a concentrations were often negative. These negative'oncentrations may be caused by the low absorbancies of chlorophyll a and pheophytin a present in water samples. Because over 1800 samples were processed during a short time frame (14 weeks) there was not enough time to concentrate the samples to absorbancies in excess of 0.2.
Additionally, concentration of samples might have resulted in excessive degrada'tion of chlorophylls to pheophytins before chlorophyll a content could be determined. Thc. constants un d fn dote rmfnat fo>> of phc.ophyc In n
75 concentration are based on the work of Lorenzen (1967). Lorenzen used sources of pigments for this derivations of coefficients. Whether extractions of these pigments and their degradation products would
'give constants equivalent to constants derived from Tennessee reservoir phytoplankton may be questionable.
Positive concentrations of pheophytin were infrequently collected in replicate samples except for those from the second water mass on June 7, 1977, when it was present in most samples collected. Assuming Lorenzen's constants are applicable to the aquatic system studied, the infrequent occurrence of pheophytin a shows that sample integrity was maintained from field collection through laboratory processing and that the phytoplankton communities entrained into BFNP were physiologically healthy.
General Discussion: Sus ended Solids and Or anic Content Suspended solids and organic content showed no trends of increasing or decreasing with water mass movement as related to river flow rates and plant cooling modes. Suspended solids and organic content data did not relate to chlorophyll a and/or zooplankton data.
Organic content varied very little with depth at any sampling location on the north overbank, channel, and opposite the skimmer wall in the channel and intake approach, except for the north overbank samples collected near bottom (3'-5 m) which probably contained detritus from the bottom. Intake forebay organic content was fairly uniform at all depths (surface to 5 m) and did not vary greatly from samples outside the skimmer wall.
76 Suspended solids levels tended to increase with depth at all sampling locations except in the intake forebay where they were fairly uniform from surface to 5 m. This uniformity of suspended solids and organic content in the intake forebay was due to mixing of the water column by the skimmer wall structure and intake flow rates. The highest suspended solids levels were usually collected at the deepest samples from the north overbank, 3-5 m (near bottom), and from the intake approach and channel samples at 3 and 5 m.
As water in the intake approach neared the skimmer wall, higher levels of suspended solids would appear in the 5 m samples, then in the 3 and 5 m samples collected next to the skimmer wall, and then in the intake forebay at all depths. This trend indicates that the high levels of suspended solids were coming from water at or near bottom from the north overbank as shown in some samples and probably from channel water below 5 m (not sampled). Barge passage which produced temporarily high channel suspended solids at all depths in one sample set (July 19, 1977, water mass 1) supports this assumption.
Due to the lack of trends and relationships to chlorophyll a and/or zooplankton data the suspended solids and organic content data were not emphasized U
in the discussion or in drawing conclusions, General Discussion: Zoo lankton Entrainment samples collected immediately upstream of BFNP showed neither the overbank nor channel to consistently have the highest or lowest zooplankton biomass. Samples from the upstream channel-overbnnk study showed there were no trends toward increased or decreased zooplankton
77 biomass from the upstream transect to the downstream transect. These data indicate there were no trends toward increased productivity in the vicinity of BFNP either in the channel or on the overbank.
Zooplankton biomass in the intake forebay was usually higher than that found in the overbank or channel portions of a water mass as it approached the intake. Since the biomass in the intake forebay was usually higher than either of the areas supplying the water in the intake, there appears to have been either biomass produced in the intake or an anomaly of the sampling method.
Production of biomass in the intake forebay is not likely because the velocity does not provide sufficient retention time for reproduction.
In addit'ion, as indicated from dye studies there are no extensive "dead areas" within the forehay for such reproduction to occur.
hn a>>orna I g i iiul<l l<av~ I)c.<<>> Jut <<>~Iud'~iiI liy I l>~ niuwIII lug m~l, luul, However, the anomaly is more likely involved with the channel samples than with tne intake fnrebay samples. The sampling method could have produced a lower biomass estimate if the heavier zooplankton species (e.g., the crustaceans) were concentrated in the lower depths of the water column.
The sampling device would integrate the more dense portions of the water column (i.e., the lower depths) with the less dense portions. This would be more significant for channel samples than for overbank samples because the channel was much deeper than the overbank. Since the water in the intake forebay was composed of approximately 55 percent north overbank water from .(
all depths and 45 percent channel water from the deeper strata it could have been rich in zooplankton biomass. That is, this mixture could have caused an additive effect for the zooplankton biomass rather than a diluting effect as with the phytoplankton.
78 Even if the aforementioned assumptions concerning the introduction of this anomaly are correct, the data should still provide a sound base for determining the percentage of the transported zooplankton biomass entrained into BFNP. The purpose of the sampling method was to provide an average zooplankton biomass for a water column, in order to estimate the total transported biomass (i.e., biomass x cross-sectional area x velocity).
Hence, the samples should provide valid data for deriving the transported biomass and t.he resultant percentage oi'ntrainment.
The percentage of the transported zooplankton biomass entrained ranged from 56 percent to 0.3 percent. Most data points fell within a range of 22 to 12 percent. Percentages out of this range were related to either closed cooling mode, low reservoir flows, or low zooplankton biomass. The closed cooling mode operation (July 5, water mass 2) resulted in an expected low percentage entrained (0.3%%u) because very little water was entrained. Low reservoir flows (July 19, water mass 3
1, 227 m /s) resulted in an expected high percentage entrained (56/)
because almost half the reservoir flow was entrained. Low zooplankton biomass value introduced more variability into the calculation as indicated by the larger range of percentages entrained (30 to 8 percent) if water masses (water mass 1, May 18, water masses 5 and 6, July 21) with a zooplankton biomass below approximately 30 mg/m 3 are included.
The data in the 22 to 12 percent range were collected under varying conditions: reserv'oir flows (other than low flow) from 1,388 to 790 3
m /s; time of day from daylight, dusk, dark, to dawn; and mode of cooling tower operation from open to helper to mixed (combination of helper and open). These results indicate that unless BFNP is in closed mode
coolirip, t'Iic i'c'sc'rvoir f3ov 4s Inv, ~r "'nopla6kton biomass i., $ ov, a relatively constant percentage of the transported zooplankton biomass vill be entrained.
80 CONCLUSION Almost all the phytoplankton of the north overbank is entrained into BFNP, except when solar heating of overbank water creates thermally stratified conditions that result in surface to 1 meter overbank water bypassing BFNP. Because of short phytoplankton generation times, such entrainment should not have a serious effect on the downstream phyto-plankton community, unless community composition is affected.
Tne percentage of th( transported zooplankton biomass entrained ranged from 56 percent to 0. 3 percent.. Host data points fell within a range of 22 to 12 percent. Percentages out of this range were related to either closed cooling mode (0.3/), low reservoir flow (56X), or low zooplankton biomass (30X, 23X, 8%). The data in the 22 to 12 percent range were collected under varying conditions: reservoir flow (other 3
than low flow) from 1,388 to 790 m /s; time of day from daylight, dusk, dark, to dawn; and mode of cooling from open to helper.'hese results indicate that unless BFNP t.s in closed mode cooling, the reservoir flow is low, or zooplankton biomass is low, a relatively constant percentage of the transported zooplankton biomass will be entrained.
The high entrainment percentage under low reservoir Slows would be of concern,,if such flows existed for extended periods, (24-12 hours). Nowever, the low flow conditions for this study were established
> ~
for specific study requirements. Under present operating guidelines for the upstream and downstream hydroelectric plants, low flows of this nature are nc expected to occur for extended periods.
The entrainment of 22-12 percent of the transported zooplankton biomass under normal reservoir flows and plant operating conditions is of potential concern because zooplankton are an essential link in the aquatic food chain. Although there i.s potential for this loss (22-12 percent) to influence the zooplankton commurity downstream of the Browns Ferry Nuclear Plant intake, the loss sh'ould not represent an impact to the aquatic community of Wheeler Reservoir.
81
SUMMARY
Introduction Intensive nonfisheries biological studies were conducted in May, June, and July 1977, to determine the effects of the BFNP intake structure on the plankton of Wheeler Reservoir in the vicinity of the plant. Since the plankton is the biotic community most readily affected by entrainmhnt into the condenser cooling water system of a power plant both phytoplankton (chlorophyll a and biomass as suspended solids and organic content) and zooplankton (biomass as mg/m 3 ) samples were included.
Studies were conducted on segments of water, designated as "water masses." Individual water masses were sampled both upstream of the intake structure, and opposite the intake skimmer wall. The upstream set of samples was taken by four aligned boats, two positioned on the-overbank, and two positioned in the channel. The second set of samples was taken in line with the skimmer wall, and included sampling by two boats in the navigation channel, by two boats in the intake approach (dredged channel to the intake), and by a fifth boat in the intake forebay of BFNP.
Downstream progress of the water mass was observed by following movements of a subsurface drogue.
Water masses were usually sampled during daylight hours under varying conditions of plant operation and reservoir flow (Table 1). On July 20 and 21, 1977, a diel study was conducted to analyze possible diurnel and nocturnal fluctuations in entrainment of the plankton.
82 On three occasions (June', July 5, and July 28) the status of the plankton community of the reservoir upstream of BFNP at TRM 295.4, 296.9, and 298.4 was documented by collecting samples from the right (north) overbank and channel. No attempt was made to follow water masses for these days.
Materials and Methods Field Procedures Triplicate water samples for phytopigments, suspended solids, and organic content were collected at surface, 1 m, 3 m, and 5 m depths at each sampling location using 2-liter Kemmerer or van Dorn samplers. The nonfilterable residue of a 500 ml subsample of each water sample was collected on glass fiber filters for later phyto-pigment analysis. The remaining, unfiltered water was preserved for later suspended solids and organic content analysis.
Five replicate samples for determination of zooplankton biomass
'ere collected at each sampling location by bottom-to-surface vertical .
tows with a half-meter plankton net equipped with a digital flowmeter.'ach zooplankton sample was preserved for later analysis.
> Laborator Procedures Each phytopigment filter sample was placed in a centrifuge tube, extracted in 90/ acetone, and analyzed with a recording spectophoto-meter.
Replicate water samples were analyzed for suspended solids and organic content by filtering a 500 ml subsample through a preweighed glass fiber filter, over dryed at 100 0 C, and reweighed for suspended solids. Fnrh suhsnmplr filter wns thon placed in s Muff lr
83 furnace (575 0 ) for 20 minutes, cooled, and reweighed to determine organic cont< nt.
Zooplankton samples were washed and then subjected to sucrose density gradient centrifugation in order to separate phytoplankton and detritus. Zooplankton samples were then washed and poured onto preweighed glass fiber filters. After filtration, the zooplankton samples wore oven dried (l00 (:) and, after cooling, wc.jp)~eg to determine zooplankton weight. Zooplankton weight was divided by the volume of water sampled and designated zooplankton biomass.
Data were analyzed according to standard statistical methods.
Mean values, variances, and coefficients of variation were calculated for all series of zooplankton, chlorophyll a, and organic content replicates. When four or five mean values were available, a Student-Newman-Keuls multiple range test was performed for mean values of chlorophyll a.
The percentage of zooplankton entrainment was calculated by Y
dividing the rate of passage of total zooplankton biomass transported past BFNP by the rate of zooplankton biomass entrained by the pumps of BFNP. The total rate of passage of transported zooplankton biomass was calculated by summing the rates of passage of zooplankton biomass in the channel and north and south overbanks at the initial sampling locations. The rates of passage of zooplankton biomass were determined by multiplying the calculated river velocity by the cross sectional area by the averaged zooplankton biomasses of the channel
84 or the north overbank. In these calculations river velocities and zooplankton biomasses of the south overbank were assumed to equal those of the north overbank. The total rate of zooplankton biomass entrainment was calculated by multiplying the zooplankton biomass in the intake forebay by the flow rate of water through the intake pumps into BFNP.
Results and Discussion Ph to lankton Significantly more chlorophyll a occurred in overbank samples than in channel samples immediately upstream of the intake of BFNP.
Higher chlorophyll a concentrations were found in water nearest the north shore than in overbank water adjacent to the channel. Therefore, most. of the phytoplankton immediately upstream of the intake of BFNP .
was located in overbank water.
Further upstream at TRM 298.4 very low concentration of chloro-phyll a were found in both overbank and channel samples. As samples were obtained downstream, concentrations of chlorophyll a increased in both overbank and channel samples. The low values of chlorophyll a at TRM 298.4 cannot be explained with the data at hand.
Most of the phytoplankton entrained by BFNP originated nn th>>
'"'i".".fil. ttii..":l:" c bHrhht rot.Cnns nt ehtnrbphyll a and phcoophytin a, while lower than those on the ovcrbank were closer to overbank than to channel concentrations. Patterns of phytoplankton entrainment under a wide range of river flow rates, and when all three units of'FNP were operating in open or helper cooling mode, were similar in that almost all the phytoplankton of the overbank was entrained.
Exceptions to this entrainment pattern fpr phytoplankton were seen with Hay 18, 1977, samples in which phytoplankton in the top meter of overbank water passed by the intake of BFNP when warmer surface overbank water passed over cooler overbank and channel water entering the intake. Phytoplankton entrainment during mixed mode plant operation was similar to helper mode for the lower strata of intake forebay water (those strata not influenced by recirculation of heated water),
and most phytoplankton in the lower strata was derived from overbank I
water. Under closed mode operation phytoplankton entrainment was minimal.
Most channel water (with its associated phytoplankton) entrained by BFNP was derived from lower channel strata. In most instances, only small amounts of chlorophyll a (and phytoplankton) were located in channel waters at these depths, so these strata contributed only a small amount of phytoplankton to that entrained in the intake.
Positive concentrations of pheophytin were infrequently collected in replicate samples except for those from the second water mass on- June 7, 1977, when it was present in most samples collected.
The infrequent occurrence of pheophytin a indicates that the phyto-plankton communities entrained into BFNP were physiologically healthy.
Suspected Solids and Or anic Content Suspended solids and organic content showed no trends of increasing or decreasing with water mass movement as related to river flow rates and plant cooling modes. Suspended solids and organic content data did not relate to chlorophyll a and/or zooplankton data.
86 Organic content varied very little with depth at any sampling location, except for the north overbank samples collected near bottom (3-5 m). Intake forebay organic content was fairly uniform at all depths (surface to 5 m} and did not vary greatly from samples outside the skimmer wall. Suspended solids levels tended to increase with depth at all sampling locations except in the intake forebay where they were fairly uniform from surface to 5 m.
As water neared the skimmer wall, higher levels of suspended solids would appear in the 5 m samples, then in the 3 and 5 m samples collected next to the skimmer wall, and then in the intake forebay at all depths. This trend indicates that the high levels of suspended solids were coming from water at or near bottom from the north overbank as shown in some samples and probably from channel water below 5 m (not sampled). Barge passage which produced temporarily high channel suspended solids at all depths in one sample set (July 19, 1977, water mass 1) supports this assumption.
Due to the lack of trends and relationships to chlorophyll a and/or zooplankton data the suspended solids and organic content data were not emphasized in the discussion or in drawing conclusions.
Zooplankton Entrainment samples collected immediately upstream of BFNP showed neither the overbank nor channel to consistently have the highest or lowest zooplankton biomass. Samples from the upstream channel-overbank study showed there were no trends toward increased or decreased Zooplankton biomass from the upstream transect to the downstream tranH<.r t . Tll<~
<<<'at<< la<If<'at< ill< t
~ ~ < w< ~ <'< n<< l,t'<!a<It< I<<w<<ld changes in productivity in the vicinity of BFNP either in the channel or the overbank.
Zooplankton biomass in the Intake forebay was usually higher tli>>ii t'h<il Found lii tli<<>vi'rl<<<<il<<ir <'h>n< I p<irt foiia of' wal.<.r m>>n>>
as it approaclied the intake. Since the biomass In the intake forebay was usually higher than either of the areas, supplying the water in the intake, there appears to have been either biomass produced in tlie intak<= Al'>> an<>f<<al j <<f I I<~ ~aliijil lt)f< (tl<.-f li<id.
Production of biomass in the intake forebay is not likely because the velocity does not provide sufficient retention time for repro-duction. In addition, as indicated from dye studies there are no extensive "dead areas" within the forebay for such reproduction to occur.
The sampling method could have produced a lower biomass estimate in channel samples if the heavier zooplankton species (e.g., the crustaceans) ve're concentrated in the lover depths of the water column.
The sampling device would integrate the more dense portions of the water column (i.e., the lower depths) with the less dense portions. f However, even if there was a sampling anomaly the data should still provide a sound base for determining 'the percentage of the transported zooplankton biomass entrained into BFNP. The purpose of the sampling method was to provide an average zooplankton biomass for a water column in order to estimate the total transported biomass (i.e.,
biomass x cross-sectional area x velocity). Hence, the samples should provide valid data for deriving the transported biomass and the resultant percentage of entrainment.
The percentage of the transp<irted zooplankton hl<imaas <ntrnf>><<<l ranged from 56 percent to 0.'5 p< r<<.:nt. Host d <to points fell. witliln a range of 22 to 12 percent. Percentages out of this range were related
t ti itJI'Jtet c JiisetJ i'titiJ Jttg ttttttlt', lttw t iitttit vtt Jt I'Jttwtt, tit'tiw ztttiJiJttttJtl till JI Jltlii.t 'lti, J Jii' J
~ ~ l. ~ ~
J c ~ >I ~
J tiit'ii ~
.J ~
ft
~ ~ i
~
il ti ii I
~ I Jit iI
~
'.,tt
,'i i >I I i i
ansi resulted Jn an expected low percentage entrained (0.3%) because very little water was entrained. Low reservoir flows (July 19, water 3
mass 1, 227 m /s) resulted in an expected high percentage entrained (56%) because almost half the reservoir flow was entrained. Low zooplankton biomass value introduced more variability into the calcu-lation as indicated by the larger range of percentages entrained (30 to 8 percent) if water masses (water mass 1, May 18, water masses 5 and 6, July 21) with a zooplankton biomass below approximately 3
30 mg/m are included. The data in the 22 to 12 percent range were collected under varying conditions: reservoir flows (other than 3
low flow) from 1,388 to 790 m /s; time of day from daylight, dusk, dark, to dawn; and mode of cooling tower operation from open to helper to mixed (combination of helper and open). These results indicate that unless BFNP is in closed mode cooling, the reservoir flow is low, or zooplankton biomass is low, a relatively constant percentage of the transported zooplankton biomass will be entrained.
Conclusion Almost all the phytoplankton of the north overbank is entrained into BFNP, except when solar heating of nverbank water creates thermally stratified condit fons tttrst resttl t. Jtt sttrfttt't tn J tttttter overbank water bypassing BFHP. Because of short phytoplankton generation times, the entrainment of almost all transported north overbank phytoplankton should not have a serious effect on the down-stream phytoplankton community, unless community composition is affected.
89 The percentage of the transported zooplankton biomass entrained ranged from 56 percent to 0.3 percent. Most'data points fell within a range of 22 to 12 percent. Percentages out of this range were related to either closed cooling mode (0.3/), low reservoir flow (56/), or low zooplankton biomass (30X, 23/, 8/). The data in the 22 to 12 percent range were collected under varying conditions:
reservoir flow (other than low flow) from 1,388 to 3 790 m /s; time of day from daylight, dusk, dark, to dawn; and mode of cooling from open'o helper to mixed (combination of helper and open). These results indicate that unless BFNP is in closed mode cooling, the reservoir flow is low, or zooplankton biomass is low, a relatively constant percentage of the transported zooplankton biomass will be entrained.
The high entrainment percentage under low reservoir flows would be of concern, if such flows existed for extended periods (24-12 hours). However, the low flow conditions for this study were established for specific study requirements. Under present operating guidelines for the upstream and downstream hydroelectric planes, low flows of this nature are not expected to occur for extended periods. "I'ho onlrninmont ol 22-12 por<<ont nf the trans-ported zooplankton biomass might affect the zooplankton community in the immediate vicinity of the plant and has the potential to affect the zooplankton community downstream.
90 LITERATURE CITED American Public Health Association. 1975. Standard Methods for the Examination of Water and Wastewater, 14th Ed. APHA-AMMA-MPCF, Washington, D. C., 1193 p.
Dycus, Donald L. and Donald C. Wade. 1977. A quantitative-qualitative zooplankton sampling method. J. Tenn. Acad. Sci. 52(1):2-5.
EPA. (Ed.). 1973. ~Diplo ical Field and ~faborator Methods for
~Measurdn the guu~lit r of Surface Vaters and Etfluents . EPA 67014-73-001, 1973 p.
Lorenzen, Carl J. 1967. Determination of chlorophyll and pheopigments:
spectrophotometric equations'. Limnol. and Oceanogr. 12(2):343-346.
Sokal, Robert R. and F. James Rohlf. 1969. ~Biometr . W. E. Freeman Co.,
San Francisco, 776 p'.
TVA. 1978m Volume II. "Analysis of Flow Patterns in the Vicinity of Browns Ferry Nuclear Plant Intake"
APPENDIX A COMPUTER PROGRAM FOR CHLOROPHYLL DETERMINATIONS
- Explanation of sample code used in Appendix A:
Example: sample // 1101185 1 1 0 118 5 abed,.e f a the first number refers to the sampling location; numbers 1 and 3 are upstream of BFNP, numbers 2 and 4 are opposite the intake.
/
b>>- the second numbers refers to the boat collecting the sample (See Figure 4).
c - the third number refers to the depth (in meters) sampled.
d the fourth number refers to the replicate.
e the fifth and sixth numbers refer to the day of the month sampling took place.
f the seventh number refers to the month of sample collection.
Sample 1101185 was collected (a) upstream of BFNP by (b) boat 8 1 from a (c) depth of 0 m, (d} first replicate, on the (e) 18th day of (f) May.
A-1 FDRTRAN Iv vFROS/Mnono rr pnlNT DLvlcE-.14o3
'>i // AEAD DEV 1 CC-1442>t:
4PnOCLSS BCu ~ LINK(T GLIB {F2) )
1 pnoGRAM cHLDET C
r r>noGRAM 1'oR cttLotlopt-tYLL Dt=TERMINAT IclNs C SAMLOC=SAMPLE LOCATION C SAMDAT=SAlvPLE DATE (DAY OF MONTHS MONTHS 1977)
C 0750= OPTICAL DENSITY AT 750 NM C 0563=OPTICAL DENSITY AT 663 NM C 0645=-OPllCAL DFNSITY AT 645 NM C De3o=or rlcnL DENSITY AT 630 Dh750=OPTICAL DENSITY AT 750 NM AFTER ACIDIFICATION C DAf>63=OPTICAL DCNSITY AT 663 NM AFTCR ACIDIF ICATIOt C Ch=ct{LOROPUYLL A IN MG/CUBIC METERS
.C CO=CHLOROPHYLL. 0 IN MG/CUBIC METER C CC=CttLOROPHYLL C IN MG/CUBIC MCTEA
-C 2 I t)Tt."GEA SAMLOC ~ SAMDAT 3 wulrE{3,5) 4 5 FORMAT{1X~ 13HSAMPLE NUMOER ~ IX ~ 13HCHLOROPHYLL Aalu 1:
1 1X 13ttCHLOROPHYLL C ~ 1X ~ 16HPHEOPHYT IN INDE>X 1 X ~ 26WPt 2CEN Tt)h T I AN )
5 00 30 J=1 ~ ?00
,e riEAD (9 12) SAVLOC SAMDAT D750. 0663 Df4.. 0630 7 12 FOnh1AT(14e13o24Xe5(F3 'y2X)oF3 ~ 3)
B IF(0750 't=. ~ ~ 900) GO TO, 33 9 112 CONTINUE 10 IF (0663 ~ GE o ~ 900') GO TO 35 11 13 CONT I NUE 12 IF (054 )eGE ~ e 900) GO TO 37 13 14 CONT INUt-'F 14 (0630 ~ GE ~ ~ 900 ) GO TO 39 15,. 15. CONT INUC 16 IF (DA750 ~ GF. ~ ~ 900) GO TO 41 17 16 CONT (NUE 18 If-'DA663 AGE ~ ~ 900) GO TO 43 19 17 CONTINUE 20 0563=D663-D750 21 D645=0645-D750 22 0630=D630-0750 0 h 6 6 3 = tl A 6 6 3 0 A 7!5 0 24 It. (D663 LEMON ) 0663--0 ~ 0 2 5>
26 IF (0645oLF F 0 '
I F ( t)630 ~ LE ~ 0 ~ ) ()630=0 ~ 0 D645=0a0
.27 IF (DA663.LC.O ~ ) DAe63=0.0 28 K=30 Ch=(11 64tj0663-2 1640645+0 ~ 1040630)4K
.30 31 CQ=( 3 '4 +0553+20 ~ 97+0645 3 '6>D630)+K CC=(-5 ~ 5340663 14 814 0645+54 ~ 22+0630) 4K 32 IF(CA ~ LEoo) CA=O ~ 0
,33 IF(CD ~ Lhoo) CB=O ~ 0 tr 34 If (cc.t.; .o) cc=o.o 3-> P I twDX =-(Jr>' 3/'DAbe 3 3(> r>ACONC= (.'6 ~ 1>t> ( 1 ~ 7>t>DA663-0663) ) 4K 37 wnl Tt-. ( 3." )) SANLOC, SAMOA T, CA,C('1, CC, r INtlx, Phc(ttt ltt '> >) I'r)t)MA I ( I ' I4 ~ I .1 i I OX ~ 2 (f 7~4 ~ 7X ) ~ ? (
1'" 7 o 4 ~ I ~)V ) ~
1' ~ 4 )
A-2 F t)R IR Att I V Vl=. It05/MOt)00 39 WR I TE (5 i 79) SAh!LOC ~ SAMOA T ~ CA ~ Ct3 o CC i P I Nt) X 40 79 FORMAT(14 13 4F7 ~ 4) 30 CONT I NUE.
...42 GO TO 60 4:$ 3.S I) 750=D7'>0- 1 ~
Q Gn TO 4b 35 D663=D663-Ii 46 Gt) TO 13 Q 47 37 l)645=0645-1 ~
4 IS GO TO 14 3>>) I) 6;30=06 So-
'Q 4 1 a
~
p qo GO TO 1'S
'a
...51 41 DA750=DA750-I ~
GO TO 16 Q)j 53 43 DA663=DA663 1 ~
- l. 54 GO TO 17 55 60 CON Z I NUI' Q 56 l Cl)NT I NUF 57 5 Tnl 5tS F Nl)
CRRORS FOR THIS COMPILATION STATEMCNT ERROR NUMt)gR ISN NUMf3ER SEVERITY FXPL ANAT ION
'I 61 97 4 STATFMENT Nt.
ool TUTAL l".RRORS FOR THIS COMP ILATI ON 4 WAS THE HIGHEST SEVER I T Y Q
0 Og Q>>z
APPENDIX B COMPUTER PROGRAM FOR STUDENT-NEWMAN-KEULS MULTIPLE RANGE, TEST
I t ~ /
// PI) "Ir I
O'PAOCI. Sb l)I: V I teCI3 ~ I. I r I I; (
l<<l) l I. I J I> h C K -I "
1 e I i~ ( I 2 ) ) ~
I I 'lit l>e>t Ath 'e) IV I'> I fill~> Il', I eiif I I lf I>(;e'i) Aiil I (,e>> I) >I Ife'i ') I >>I i)(i"i) ill), I,I, ii),
~ I ~ e ~ ~ >
I l Y in I, I, lht (;:ll I >. Iete I I >if>i e I II'hl)'ei WAVVhII
<< I I I nil l I~ ') I n e I III>I e I I I'nil' hvvn>e
~
I ii 'I" n I f i /
. I e e
~
i )
II ( ln I i)-Ii ) "II II) te It ( I h '. I) "e) 'el) IO .;2)
~
9 222 0 ( ) = el ') '1 >N) e'. ~
10 0( 3) =.5.6400 ll 0(4) =-n.on60 12 GO TO .3 5.3 223 0(2) =2 9!300 14 I'( 5 ) '=,I ~ 57>5!)
I>> 0I 4 ) =- 5 ~ ')Si)0 16,. () ( 5 ) = n .,'2 0 17 3;3;5 CO'I 1' "IU.":
Ib W"Cl rf ( I ~,5) IA ~ I TPA!45 ~ WAVVAfC
/
19 I-i)H><AT( ltI1/SX ~ HHS)4K Tf-ST ~ 15 I X ~ 2)5HMEA rls. TRAI4sFofcMA T IDN coDE =,
',ix i I OII>E')>)OR MS = o F 1 5 ~ 5)
I lt(RITE(3 20 (th.-:,0.<<) Go rn nn
? 1 IF ( I h ".0 ~ 5) GO TO 4 >
22 44 ~ 4 ) (0( I ) r 1=2+4) 2J 4 FOIIMAr(.1F10.4) 4 GO rO <>
45 Wlc I fl: (-1i >) (0( I ) ~ I'=2 ~ 5) 2t> I i)RMnr( iF IO.n) 2/ 6 C<ef'I f I NU'-
20 lf ( ICl)I)l.~l 0 I ) GO TO 1 r 29 CALL I'4PUT 30 ( () Tr) po 31 I 7 OI3 rr iCI- hO( ') ~ I 8) Il-AC0( I ) ~ YF)AR ( I )
33 ~
18 I- I)>CNlh r ( I n,f-10.5) 34 77 CO>4T I NU~
35 20 5TD=sop T ( wAvvAH )
-30 OO ? I 1=1 e Ih i 37 0( I )=0( I ) I !3fl>
I f)EO( I ) -- I FP" 0 ( I )
TAHI << ( I e I ) =I Thl;LE (1,2) = YL>AII( I )
TABLE ( I ~ .5 ) =F REO ( I )
42 21 .CONT I Niff=.
CALI 'CSOIC r ( TABLE s IA~ 2 )
<<4 wRITI=(3 30) ~
45 30 I-ORMAT(/2<<tl TAOLE OF MEANS,(SO% Tt-;0) /)X.6HSA><<PLt-. ~ <) X ~ 1HN 6X 4HME A I 1 X e 6)tNU>4> ll=.>2/ )
40 Ot) I? I =I o I A n7 )ee,'il )'i- (,3 31 ) TAOLF. ( I ~ I ) ~ TAI3LE( I e 3 ) ~ TAULE( I ~ 2) 48 I-'I)>)Mhr (SX,F In.O,F I O.O,F I 0.4) np .32 C>)ef I' 4(l" Nr)5-" >.'>
I AM I = In-I DO >~0 I=I ~ I hM I
I. Ol'4 I'i(AN I V Vt:I(0'>/Mri>>0>)
55 I AIUI I =. I h- I sn O(l '0 ll. II4ST=I. I I AST=II IRSf( IAMI I F ( N)4 5 ) n 0 e 4,0 ~ .3 5
)7 l)(l (H J = 1 ~ NNS>
I f. ( I I. I )' I - '45 5(I 59 60 57 Il'I 5(I C()>4 T I NUt h.if .'(51'(
f ( .I i I ) ) '((( ~,( 7 Js2) )50i50),l(>
> 37 TL'I> T 40 C I( I T=(1 ( I AM I + I ¹ S0 R T ( 0 "3 0 ( 1. /F REO( IF INST)+1 /FRFO (LAST) )
I I'
)
AllS ( YEAR (LAST ) Y(3AI(( IF IRST))-C(4IT)4 1 Nfif 5 I(;(4( t I C AN T
'0 F 50
)
f) J NN S--.NN'p t 1 64 '4 'I f ( N:4 5 i 1 ) = (F 1 R 5 es ~ ?)=LAST I'4ST(NNS g4 66 50 CONT I N(J!'
67 I- ( >4N S ) () 0 ~ 60 ~ 6 2 60 r)0 WQI Tl:,( 3,)i) )
69 () I I-(J(4MA T (//.35(4 ALL MI='A(45 S I GNIF ICANTLY () If FI:(4ENT )
70 (i(l TO 1 71 6? W(4 I TE ( 3 ~ 6:I )
7d 63, FORthh f (///3II4 MAX I MUM NUNS I GN IF I CANT RANGFS /4 X ~ 6HSUBSET 5X~'14HS I PI j:, >4UMI)t.-.l(S )
7.3 f)f) (>7 I = I > NNS 74 I i. =~45 T ( I > 1 )
73 IL=NS f ( I ~ 2) 76 Ii- IPS r= TAI'.L(:. ( IF, ) 1 77 LAG I = Th><LI. ( IL I ) ~
70 () (i WRI I'I". ( 3 06) ~ I ~ IF IRST ~ LAS I 79 66 rn)c~h T(."X, I ),112.sx ~ 1.3)
.00, () 7 CON T I t4U~
GO TU I
'-J 99 CON T I N(JI=
. ()J Si r()P (34 C ~~ID Er4RORS FOf4 rt(IS,CUSP ILAT ION STATEMENT ~
ERROR L.... NUMUEI4 I SN NUM(JE(4 SEVER I TY EXPLANATION 9(l UNOLF VAR NAME ~ INOICATEO fl 65 97 STATEMENT NUMBER IS UNREFER
)(t 002 TOTAL E(4f(()RS FOI( THIS CQMPILAT ION "ggcli I>.:
- 4. (NAS Tt(C HIGIIL-ST Sl-VEI41 TY
'4 OL I 00, I TNL Tii Thi. Cii'll: ill I.IJ llY NK TS T IS 131 I l)tC Ii<AL~
OL101 I Tiii= STAA I CllN T~~rlL ADI>AI-:SS OF TliI S Nnl>ULi I S 4100.
OL.I 04 I TOT AL i'il.J<tiCA Oi= L I tl'ICA~MY SI.=.C TOAS AE.OU I R1=.0 I S NA>t;-SNK 7'. I PA(.K-I.. HFPFI.'NI T-I-2 <1F T A IN-P L I ISHAAY-0 I ~ W
~ 'L I
l
~ ~
'>'p"";I-' INPUT SUAROUTINE e'I "2? 5 SUOI<OUT INE INPUT
~2'. DINENSIOII DATA(85) I( RF(25) ILDC(25 )e IDAT(25) 3 COMMI)'4 n< /0) ~ YBAll(20 ) ~ VAR(20) IA (CADE ~ ITRANS ~ 'WAVVAR 4, READ (5) 663) ( IF I>E ( I ) ~ I= I 6 I A) 5 6'Kg:
7<>4!'>" '0 2 FORMAT (5)11 )
WRITE (3e30)
FORMAT ( 1H I 3X 6HSAMPLE ~ 2X ~ 1HN ~ SX ~ 4HMI. AN 5 3X 5 8HVAR I ANCF ~ 3X 2 24HCOEFF. I,~"'5 ICIFNT tlF,VARIATION/4X<<6)!NU)IBER)
>> ~
0 SUNDF = 0 C CALCULATION OF MEANS ~ VAR I ANCESS SUM OF OF ANO 'WEIGHTED AVERAGE.
9 wnVVAN = 0.0 150~~5., DO 701= 1 ~ IA IFREQ = IFRE ( I )
Ig'2<<<< . I.REO: = (FRED l3! ., DF = FRED - I 1 4.y'<<. DO 29 J=l ~ I FREO 15
'O 1 6 "'(":...",
17RP~'~."P;;
18:TA 19 20
', READ (9 28) ILOC(
2 8 FORMAT ( I 4 e I a ~ 2 X e F 7 ~ 2 )
29, CONT I NUES 671 J= I, ~ IFREO lr- (IDAT(J).I=-n.850) GO rn 65as, I r. ( IDAT( J) .En. 7 oo) Go To 6544 J), (OAT/ J) .DATA( J) 21 IF ( IDAT( J) RLO6800) GO TO 6545 227IIP(+j'ii .,IF ( IDAI'(J) ~ EO ~ 000) 00 'TD'546 ~
~ <<(
5<<
2a.'+P~',"," "670 CONT I NUF 24'.'--" -'671 cnlcrlNur; 25 SLIM = 06 r.'(3 oo 4AJ = 16 lFpl 0 27 SI.IM=SU(vl + D,ATA ( J ) <<
28 40 CONT I
F /
NU?-'BART
= SUM FREO 50 YIIAR ( I ),=YBAAQ.
316 YARN = 0 ~
32 ( IFREO 1 ) 45 ~ 45e 49 ~
,l3 4b VAfCT = .0 ~
34 . GO TO 51 35"","". 49', Do 5oJ = I, Ir-REO "
36" VARM = YARN + (DATA(J) YBAR(t)))ll)l(2 a7 50 CONT,! NUE 38 V Alk T = VAAN / Dl=
59 COVAR=SORT(VART) 4100/YOART 40., ~
Sl VAI4 ( 1 ) = VART 41 SUMDF = SUMDI- + DF 42 "". 'RITE(3.60) I, IFREO, YOART, VAHT, COVAR 43 ~ 60 F (IR MA T ( / I 7, I 5, F 1 0~4 ~F1 2 4 ~F 1 2~4 )
44 DO 59 J=1 ~ IFkFO 45 ,,IA'R l,Tr ( 5,..3,'I), ILOC( J) IDAT ( J ) PATA< J )
46, 2(,",', 58 FORMAT(SX 14 ~ 13 ~ F I 0 2) 47:, 59 CON T I NUI:
48 WA VVAN = vfA VVAN + YARN 49 . 70 CONT I NUE 50 wA VVAR = WAVVAN / SUMDF WR)(0(3.6)) WAVV*R 52 (31 FORMA T (OX SF 10 ~ 4 )
53 GO TO 7111
~ ~
FOR I'hit I V Vt'>(<)'i/Mf)>)00 l>n l > ~> 4;I I I r h I' J ) '= 1 > I 5 GO I l) <>70 56 6'544 If)AT( J) =-0/6 T E I c>7 GO,T() l> 70 St) 6>>n'I [Oh I ( J ) =0>>(>
5 ) l (I TO 670
(>0 6'54t> I l)h f ( J) =-096 61 GO TO 670 62 71 1 1 CONTI NUE 63 nt-: rt)RN 64 F tl()
I" F>t JORS FOR Tl(IS COMP.I,L,AI. ION
',[
I 51'h TFM(='N f EHROR tJUM[lLft I SN NUMt)Ftt SEVEN [ TY EXPLANATIr3N UNut-I- VAR NAMP It 0 01 TUTAL C)JR(tfJS FO)t Ttl[S COtJPILAT ION n )fa THL HI )GALS I Sf='Vf R I TY l
OL1 03 Zt)T*L ~)U)4>)L ~! f)F L I (>>t AR Y S(!C 1'ORS ftt Otl [RED I S 10 Nh >"f - I tJf U IhCK-t . t't'? ~ U J I T l 2 ~ AE I'h [ N T ~ L I U)) ARY l' CATEGORY OL I 0'> I tll'llOf" Lt: N 'H OF 1NPUT IS I 5.> I Dt,C I MAL~
r
FOA rAAN I V Vr >>O- X<<OUnf)
~ >) PA(IC f' S> I'CI) ~ f))I Jt>C1 ( I ~ L 10 (F 7 ) )
SU)4>)OUT I N>= RSf)AT ( AAOLl; ~ I S ~ LP )
I) I M=NT I >3N ffht)LE(25 ~ 3)
~L....: 4 I Lt<<IT-I I tfA= I I>- I f)r) >i I -. I ~ 1 I4 6 IF (P AUL>. ( I ~ Lt>) -AAOLI= ( 1+ 1 ~ LP ) ) 5 ~ be 2 7 2 L IH I T-"P I) OO 4 TEI>IP=IRAOLI. ( I IN)
I0 ihr)LL> ( I . I N) =AAOLC ( I+I, t N)
I1 RAHLI: ( I + I ~ "I N ) = TEHP 1 2 COI'I T I I'IUI'.
3 CONT I Nlf'.
1 4 GO Tfl (I> ~ 1 ) ~ LI NI T 1 5 6 RETUAN 1 0 END, 000 TOTAL f-f)AORS t.OP f HI S COMP tLhl'ON I
OL103 I TOTAL NVf'O(..ff OF L I OAAAY SFCTOAS REQV IRFO I S 4 I 4 NAZI:-PSO:)T I'>ACK-F2f'2F2 ~ VNI T-F2 ~ AETA IN-T L IRPARY-R CATEGORY-020 OL I 0!i I I'Ilf <.f)lif-' f' TII Uf. ASOf)T I 34'3 T)f-:C I HAL ~
n f
APPENDIX C SUSPENDED SOLIDS AND ORGANIC CONTENT DATA
- Explanation of sample code used in Appendix C:
Example: sample /l 110185 1 1 0 18 5 a b c d e a - the first number refers to the sampling location; numbers 1 and 3 are upstream of BFNP, numbers 2 and 4 are opposite the intake.
b - the second number refers to the boat collecting the sample (See Figure 4).
c the third number refers to the depth (in meters) sampled.
d the fourth and fifth numbers refer to the day of the month sampling took place.
e the sixth number refers to the month of sample collection.
Number 110185 refers to the mean value of samples collected (a) upstream of BFNP by (b) boat // 1 from a (c) depth of 0 m, on the (d) 18th day of (e} May.
('
J 1
C-1 9 '. USI>I Nl?I:D SI71 IDS AND ORGANI C CARBON I
ALL MEAN VALUES ARE IN GRAMS/CUBIC HE TER Qi
...SAMRLC.. ...SUSPENDED..SOLIDS......,.. ORGA NIC CONTENT VAR I ANCE I 10 l05 4.966 1 ~ 833 Oe063 8 120105 5 966 2e499 O.S69
..,..., 130105....0 140105 Ae
~
~ JOO 266 2
3e066
'66 0 '63 Oe663 111105 5 '00 2 ~ 466 I~ 503
...121185- .. -. 5e.733 2 ~ 533 0 '63 ljll85 0 ~ I'66 3 '00 Oe630 I 4 I I Ub loe333 4e033 0 '73
"...1 13185 ....,.......... 4 ~ 866 ... .I ~ 633 0 ~ 163 123105 4 ~ 966 2 '33 0 ~ 123 >
13:3105 0 ~ 666 2el99 Oe 129
....... 143105 ............14 ~ 800 . 2 '33 O. ~ I 73 I I '.> I AS 7 ~ 300 ?. ~ 566 0 ~ 000 o 1251A3 I'J5 105 0 ~ 000
..........,...17 000....~
2 ~ 433 2 ~ 050 0 F 000 0 ~ 000 145185 I 9 ~ I 00 3 ~ 200 O.ooo 8 21'0105 6 '00 2 e2 33 0 '93
....2?0 I IIS....., .:.... 9~ 766,...... 2 e549 Oe005
>? .50 I 8'.i 0 ~ 100 I ~ r? 9') 0 ~ r> I l?
Q 84n I ale> 8 ~ ')J 5 >'. + 0 <) ) i nr>r) d ~ ~i 66 0@053
>' I I?5'> 7. AOO 2 ~ $ 3.3 5 0 '63 281 I 0'> 7 ~ 900 2 ~ 466 0 '23
... 2 3 1 1 05,...,.....:....,.8 e4 33.... . 2 ~ 499 0 ~ 129 241185 I 2 ~ '.366 2 e 39'? I ~ I 6r?
2r>l I I9e 433 2 ~ 5 9r? 2e280
... 213185.. 5 '33 2 '99 0 '69
?23105 8.e 233 I ~ 299 0 ~ 090 233185 9 '33 1 ~ 966 0 ~ 143,
....,24 J105 ............'... 19 ~ 20Q ......... ", ...., 3e199 O OO9 2531 II5 20 ~ 666 2 '00 0 ~ 090 215105 7 ~ 633 I ~ 733 0 ~ 203
..............225105....,... ...6e 900....,...,, I ~ 700 0 ~ 190 235185 7 650
~ '. 2 '49 0 ~ OOS 245I05 20 '00 2 '99 0 ~ '.1 29
..... 255105 . 19e533.. 2 '00 0 ~ ~370
.I I n I 85 5 ~ 56t) I 099~ 0 '09 3?0 Ut> 1 4e400 2 '49 0 '05
,J Jo l85 5 133. I e93 I I ~ 003
.540 I H5 5 ~ ?33 I ~ 499 0 '29 31118 ) 7 ~ 633 2 ~ 299 I 029
~
...J21 I 85................ 7e.000,. 2 '66 0 '63 331185 6 ~ 933 3e 599 0 F 010 34 I I 8!> 0 ~ 766 3 ~ ?. 99 0 ~ 490
...313105 ....... 5 ~ 433 .. 1 ~ 099 0 ~ 369 9
C-2 Su! I'>ENDED 5(IL ID'- ANI) ORGAN! C CAAHON ALL MEAN VALUES AISLE IN CA>>>MS/CUD I C ME TEA SUSPENDED SOL IDS O(IGANIC CONTENT VAR I ANCE 3r2 51 t! Si 6 '00 I ~ 433 0 ~ 163 35.1 I 0 Il 333 I ~ 999' 0>>4 30
'AMPLE ;In 31 tlS
'I I 'i I 05 16 '33
~
0 ~ I oo
~ .599 0 ~ 066 ?
I ~ 439 253
'32!i I 05 II ~ 03 3 2>>233 n. no.5 IS I '55 10>>966 2 566 0>>543 In's I tl'~ ?0>>700 3 '33 I >>743 it I t) I t! 'i 6 ~ 053' 2 ~ 633 0>> I?3 I nc" 01.05 6 ~ 266 2 ~ 166 0 ~ 363 it 30105 6 '66 I ~ 8 33 0 ~ 703 4<<0105 alon 2 ~ 9 9 t) n.n9O 450105 19 '66 ?. ~ 566 0 ~ 573 41110"i ).n66 3 '66 0 ~ 373 rtc'110> 8 ~ 100 2 ~ i)00 '?. ~ 4 20
'>.51105 R ~ 566 4>>noo n>> 129 44 I I t)5 ln>>066 3>>466 r> ~ 5 73 i> 51 105 I ') ~ 450 a.e~o 0 '05 n 1310;.. 7~ 566 2>>S '33 0 013 II 8'i 0 13:5 I>>966 0 ~ ?03 .>>
4 551)35 0 '00 2 ~ 053 0 ~ 573 nit 3 I AS 1 tl ~ 300 2 ~ 799 0 ~ .360 n.">31 e 3 ] 9 ~ (i 66 3 ~ 2<)9' 0>>neo 4 15>1 135 8>>066 ~ 1.3 3 O>>063 4 2!i 105 9 '00 2 ~ 199 0>>120 4 3'.i I F'> 6 '00 2 ~ 099 0 '69 4 r>!i 105 30>>233 4>>366 I ~ 053 rt '5>) I 0'> I 9>> 76(> 2 ~ 3 I3 ?>>1?3 110 76 12 ~ 133 3 ~ cI 6 6 O. ~ I 73 120 76 9>>266 2 999 0 520 Ill
~
130 76 533 4 '99 0 ~ 359 I no I!i>> 000 5 '99 n.+no I I I 7t> I r!>> '.) 3 3 5 !i~ 3:3 0 ~ 013 I c.' 76 I O. n66 2 '33 0 ~ 013 1 3 I /t> I nt ~ 466 4 ~ 133 0 ~ 253 14 I 7(I 15 ~ 5'33 6>>466 0 ~ 173 I 1.3 76 13 ~ 400 4 ~ ') 99 0 ~ 120 I?.3 76 I I ~ ?00 3>> 9~)t) n. 27r)
I ! 5 7~> I Si ~ 73 '3 4 ~ I >)9 0 ~ 0 ;I')
"I rt I I( c! I >> I I I 6>> 7'I 5 I ~ II c I I '.> 70 In'66 ?. >> >3(>6 0 ~ 0'i 3 Irc, 7 10>> 000 n>>066 I ~ 373 135 76 16 ~ I366 ., 4 ~ I;!3 0 ~ 09.3 210 76 0>> 000 3 ~ 599 o.nno 2r~o 7t> 7 266 3 ~ d 3:3 () ~ Old
?. do 7(> I:3 ~ 933 4 ~ c) 33 0 '73
C-3 V
..I SUS1)ENOEI) SOL IOS ANO ORGANIC CAROON MEAW VAI UES ARE IN GRAMS/CUBIC METCR
.SAM .SUSPENt)ED SOL' OS
- nnt;ANI C CON TED T VAR I ANCI
- n'0 '/6 14~ C>'00 4 ~ 53 0 '53
?'~0 7ti ?.?. ~ 900 4+799 0 ~ 000 211 7Q ') ~ 733 4 199 0 ~ 03<)
221 7t) 0 000 40000 0 ~ 040 231 7t) I.Ci ~ I 33 F 000 241 7C) I 7~ 93 3 799 Oa279
?vil 7 I) ?3 ~ 200 . 4 '6b 0+013 21 3 76 - 13 ~ 46i6 ha 3 53 0 ~ 013-.
')
3 76 8 933 3~533 0 '13 2J5 76 ,I r> o?.00 t> ~ 7') 9 0 ~ Oho 2 /I .5 76 17 ~ 100 n .:366 0 '43 253 76 24 533 4~933 0~213 0 '20 3)j i 15 7t> I b ~ 06b 4 ~ 799
.Il 7b 14 ~ 33 J 4 ~ 735 0 '73
')Nt<
V<> 2J5 'LC "71) 13 F 600 3 ~ 933 0 ~ 05:5 76 ?7 233 6:5 )9 3 ~ 07')
'40 hI 255 24 '66 '5 ~ 199 0
,.)J I 0 7'76 9 ~ Uoo 3 '99 0~000 320 7b Ileh6t) n 133 0 ~ 0');3 J.30 76 I 2 ~ I:33 5 '333 n. C 5.3 Jh0 7ti 13 F 000 4 ~ 000 00040 3 I'I 76 Ill 933 3 '99
'66 0 ~ 040
'93 3?. I 7t> I I a933 4 0 Iles 1 4 ~ 600. 6~399 Oa I 19 331. 7e 341 /t) I b. OOO 4 9<)9 0 ~ 040 313 76 I I ~ 9.53 4 ~ 199 0 ~ I I<)
J2J 7t) 12 F 000 na266 Oa093
.3 J3 7t) 11 ~ 266 4 ~ 7:53 4 ~ 09.'3 3/I 3 7t) 20 ~ 466 5 ~ 599 0, ~ 04< 0 315 7b .I 4 ~ 533 4~199 0 479 3<15 70 13 ~ 133 4 ~ 933 0+233 J.3.<> /t) 17 ~ 800 4 ~ 533 n. o I:3 II 10 '/t) 11 ~ 133 4 ~ 666 0 ~ 493 420 76 12 '66 3o 799 0 '79 450 76 13 '00 3 '66 0 '13 h.l I .76 000 3 '66 0 '13 7 C) 1.3. Obt) n.133 0~ 173 4 '3 l 76 15 '66 '4 ~ !i99 I) ~ 120 hhl 7t) 1 5 ~ 66t) 6o )33 I ~ 213 4 <) I 76 21 anno 'i. 399 0 ~ 3t)0 hl J 76 I4 133 3 ~ ') 33 n.093 423 7u I I ~ 06t> 5 266 0 ~ 49J 4 76 13 166 4 ~ 33.3 0 ~ 01:3 4 r< .'3 76 22 '66 7 ~ ') 99 I 'a 2 3')
/ISJ 7o 21 ~ <)3 J 5 '66 0 ~ 013 l
g V
jV
C-4 I
~ ')I(".)I>(r(s(SI (I 5)('.I..l,(35) At(i> (I(tGAN I C CA(tft(I(t hl I tt( All VAI I(I ss hl(l I (( rslsht) 's/( IIII ( (, (4(' I'(r ss'ht Il 'I I, !)Ir')I'I:ill>l' si(ll I I) 's lt>tish(l I r ( (Stl I >'tl I 14(s I hfl( I tl" I s> ~ ll >) I s (I r I 1 I r((((II I
)I s" I'>
s I ? ~ r> 0 fl h tint( I.nf t
> I s?>>UOO 3 ~ ('Inn r) ~ 00(t r> )') .ll > ?no r>.()t'sb n ~ 133 I I 0 I (!fs '.i>> I 3.5 3 Unn 0 ~ 000 I s) 01(36 4>> 400 r~ >>399 0 ~ 040 I '501 Hb 6~ 333 3 I> f)6 , 0 ~ 173 I n 01'Ho S>>53.5 3>> 199 0 ~ 040 I 11106 f) ~ .20 0 2 933 n>>013 I r' I c36 3 933 3.399 0 '20 I BI I Af) 14 11't36 lr".~ 93J 5 '33 O>>213 9 ~ 133 5 ~ 46() 0>>093 I I .I I (lc) F 200 4 ~ 399 n. 5I9 I ? .'5 I (I o 5 F 000 3 ~ non 0.4(sn I I {1>>S() 24 ~ 5'3.3 4 ~ 535 I 0)3 I n;I I 0(> 2n>>000 6>>066 0 013 Os I 151
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)S() 13 '66 ,3 ~ 9r) 9 0
~
~ 159 I 20 ~ 133 3 ~ 6fsf) n>>175 210 Gc) n;boo 3 ~ 5'(9 0 ~ I r,n 2 '>) (lu U~ 466 6 ~ Of)6 1.74 ~
)
? Sn 4 ~ snnn 3 ~ ()f () n ~ 571 24 0 U(> 6 ti 0'0 3>>h6f> 0>> n93 r"Jn )S b ?n ~ UOO 4. ~ 73 5 I ~ 973 2:I 'I 8'b () ~ 733 3>> I or) n ~ 040
??'I Ub .). noo 4 ~ o(in n ~ 213 s! .'l l Hci 'I '0 66 6 4 ~ ')3() o n ~ 21 3
~h I >36 6 '6b 5 ~ 7'3 'I n ~ 173
~".) I >S 6 2J ~ 333 4 ~ (36 ti I ~ 453 21 J t(6 r'! 2:3 06 7>>200 9 ~ '466 3 ~ rl6 6 0 '9J 4 ~ 0 6'6 I ~ 693
- > 33 0() 10>>boo I ~ 799 2>>919
?r> S !Sf) 4.400 '.) 99 0.2HO
- c. )3 Jb 23 F 066 S>>1 '55 0.25.5 I
? I 'i Of) in'33 2 ~ 666 0 ~ 173 2 2'.> (5 f) ;I'2 ~ 2 6 6 3 '66 I>>053 2 J'.) (36 2.( ~:40,0 n 199 n.5,19
.? 4 si scl) ? 0 ~ 2f>t) f) ~ r> (> 6 I ~ 373 slf> 2n.2 on ')>>466 I ~ 053
'I I 0 (lb ') ~ bn 0 3>> 19rt n. 7c>0.
Jr'0 Un 6>>'000 2 ~ 5:55 0 ~ 013 5.(n tsb I'I . bno 3 ~ 466 0>> 09'3 Ub .. 'I:3 ~ 466, 4 ~ 5:(3 0 ~,I 73 3 I 'I Hb t) ~ 06b 3 ~ ri(i6 0 ~ 05 'I Sa? I >Sc) 6>> 46() ? F 999 n;nno s I II Of> 12 ~ 4'00 4 ~ I 'l3 0>>57:I O
C-5 SUSI>I)NI)EI) OL I DS AND ORGANI C CARI)ON ALL AN VALUES ARI: I N GRAMS/CUII I C HI: TFR SAMPLf'. SI)sf>>:II()rl) SOL II)S ORGANIC CONTI-.NT Vhlt I ANCI
$ <<1 P. ('i 15 ~ 600 4 ~ ').33 n.n53 313 Ut> 9 ~ v00 << ~ 06 () 0 ~ 0 r>:I 325 Uu I 2 ~ 733 <<+933 0 ~ 093
.35 3 Hs 16 ~ 800 5 ~ r)nn 0 120 34:I 0(> ISal33 4 i8f)6 0 '93 315 US 13 '66 4 '66 0+4 Id 3i'> Rr> 20. 133 4 199 0 '39
<<10 U00 .3 ~ 8 6C) 0 a '333
<<20 )IG 10 ~ 266 4 ~ 6 sf> 0 ~ 05.$
<<$ 0 86 I? ~ 13 3 4 5 0 ~ 3/ I
<<<<I) (f4 I2 ~ onr) << ~ .') I I I) ~ I /1
<< ')fl >$ 4 Ini II I I~ 'i I .I I) ~ Jj
<< I I nli I I i 2(>(> r) .Oon I'.d<<O
') i! I lli> ') e f)00 I ~ c)00 0 F 000
<<Jl 19 066 Ci. Oer> r) ~ 57 J
<<<< I Oe I I a 33.'I 5 '66 0 ~ 573 8 t.i I 7 ~ 000 4 <)33 0 '53 I 413 86 I 0~ 06(> 4 ~ 533 0 ~ 09:I 42'I (36 I I ~ 400 4 ~ 066 OaOI J
<< .3.$ 06 I '/a 666 s. 4eci 0 ~ 013
<<<<J 18 ~ fif>6 S ~ 266 0 '5J 453 U6 18 F 800 ~ 799 0 '40 415 )36
<<c!5 UG 11
<<a800
~ 3J3 4
2 4
'33 e<<66 0
0
'ld
'93
<<>IS .U4 PO ~ 733 5 ~ 399 0 ~ 0<<0
<<rg<) Uf) 18.1$ 5 ~ I 99 0 ~ )20 10 94 7 ~ '.)3 3 3 '33 0 053 220 913 6 ~ 64(> 3 '66 Oo09J 230 4 ~ 4J5 3r333 0%493 2<<0. f> a 200 3 '99 0 '59 250 94 12 ~ Use 2 9')9 0 12O 211 9(i 'I ~ 200 2 ~ 933 0 ~ 253 221 94 6 ~ 466 <<.59>> 0 ~ 040 2JI 9G 4 '33 3i 2c)6 0 ~ I /,I 2<< I 96 6 266
~ <<.cise 0.09d 251 9(> 13 '66 3 ~ 933 0 '93 2 I:I g(i 2i>3 9(i Ill600 c) ~
666 3 ~ 4 GC) 3 ~ 8() 6 0 ~ (31 3 I ~ 121 2.$ J 94 r> ~ 733 3 '99 0 ~ 0<<'0 2<<.$ ~)4 5 '33 I ~ 799 I o 191 c'53 1'33 4 ~ n99 0 F 000 215>, 96 14.&600 4 ~ 799 0 '20 2 )L) 9 f> 9 133 3 '66 0 ~ 09;I I .I'i 9() 10 '66 5 ~ (3/)6 0 '93 I 2,D.) 96 I 3 ~ .333 << ~ 533 0 r)'.3 I Q
C-6
, e .iU;C>t(>II)I-.I) SOL I O., AN)) OI(GAN1C CA>toON ALL Mt:AW VALUE'S AAC IN C;AAMS/CUHIC MFTE:lt Sat~&'Lh SUSPKNDL)0 SOLIOS ORGAN?C CCNThNT VAR I ANC n lu 9t. 6 ~ 06 t> 4 ~ 4h6 0 F 013 4 lr)n t) ~ non 3 ~ 8()6 I ~ 055 4 .IO no 6 ~ 1.$ 3 3 ~ 733 0 ~ 173 r>40 96 ') ~ 400 4 ~ 399 I ~ 079 r> rin 9t> 1 9 06() 5 ~ 399 I ~ 920 4 I I '7 () 6 '66 4 ~ 000 0 ~ 040 nr! I 96 6 '33 , n.ooo 0 ~ oon 31 9(> 7 400 3oAh6 0 '33 r> 4 I 9(> 7 ~ 400 4 ~ 199 0 ~ 51>)
- 45) I 9t) 17 '66 5 ~ 199 0+280 ni3 t) ~ On t> 3+331 0 ~ 0 I:I
>70 5 ~ C) 6(> 2 O.ono r> 'I,t ')6 5 ~ noo 3 ~ I nn 0 nno
'>4 i 9fr 12 3.J 3 4 ~ bhh I 053 9 zoa466 5 ~ 399 0 ~ hno 4 I 'i )t) 6 '66 3 ~ 933 Oo093 42 ) 9(> 7~ 133 ?. ~ r)() 6 0 '93 4,5 9() 16 ~ 06t> 3 '33 .0 ~ I 73 r> 4 '> rjt ?EIo 066 6 '99 0 ~ I 5Z) rt t> I t> ~ 400 F 066 0 ~ 053 I I 0 57 5 ~ 800 4 ~ 3 3.l 0 ~ 0') 3 I ZO '17 n.7OO 3.nno I +61 )
I in '57 'i ~ 700 '1 ~ ? t>6 0 ~ 013 I r>O 57 '5 ~ Ho 0 4 ~ >,)r)>7 0 ~ ?. 7r)
I I I )7 EI >300 5 +66h n. ?5:I I '! I r57 5.'nno 3 ~ .199 0 ~ I?0 I ll 57 8. ion 5 '66 0 ~ 4 r) 3 7~ 600 5 ~ nt>t) e' I 14 I 5>7 113 57 4 ~ 100 3 ~ 73 'I (7 a I 7 5 0 ~ 653 I r.' 5 7 EI ~ "000 3 ~ 3>7<) n.ono 133 57 I za 100 4 7S5 0~173 lr> I in. Ioo- 4 ~ 6t>6 n.653 I I:-i 'i7 ') izoo 3 ~ 466 n~?13 I r' 57 :1 I ~ 500 3 7:33 0 F 173 210 57 "5. ~ ? 00 5 ~ I nr) n ~ 5)zo 220 57 3.200 3 '66 0 ~ 4 r)3 23u 5>7 5 '00 3 ~ 7.13 0.093 zno !)7 8 F 000 n. 133 0 ~ 013 2'.)0 '57 I ) ~ 300 4 ~ 39r) 0 119
? I.l 57 ./, ~ 500 4 '33 ?,'613
~r> c' 'r) 7 lazno z.noo 0.120 231 57 7"e 700 4 '66 Oo373 5 7 <C) o,'200 4 '99 0 ~ 000 r.t!I I '5 7 I >4 ~',200 n. I 79 0 +in 39
?. I S ')7 '5 ~,I 00 .3 a 3'3'7 0 ~ 520
C>>7
'SVLNOI=D SOLIDS AND ORGANIC CARISDN ALL MEAN VALUES ARE IN GRAMS/CUOIC METER snrnr)LE SUSPENDLD SQL I DS CIRGANI C CONTENT ~
VAR I AN(
2? S;i7 5~ 600 3 ~ 333 0 ~ I 7 2S3 57 I I~ 700 5 F 199 O ~ 20(
24.$ !3' > 900 4 ~ 333 O ~ 05:
?.i I sf 13 400 4 ~ 199 n. I I<
r) I) 4 200 3.nee O>>37.
bf 9 300 3 ~ 666 0 ~ 37' r?:Ss 5 f 11 400 4 ~ 133 ~ Ol 57 13.nOQ 4 ~ 399 0 ~ I 5<
5( 15 F 000 4 '66 0 ~ 0)P,
'.oh:-
- $ 10 57 3>>400 3.466 320 !)'f 4>> (S0 0 7 ~ ?. 66 3 ~ 29 J30 5 5~ 300 5 ~ f <)<) ~ 20(.
4$ $ 5 f i'$
ll ~ 000 7 79") 56C
.$ 11 57 7 ~ OOQ 5 ~ P f)6 1>>O I.:
Jc? I 'if 4 '00 0 ~ J3;I I ~ I /7 J31 57 6 ~ 600, !i ~ 066 0 ~ I fJ 34$ 5f () ~ 200 S.?66 2~0 I:S
.'$13 5 f 12 ~ 300 6 ~ 2C)6 0 ~ 333
'3 c',I 5'f I ()>> 400 6 ~ 533 0~ ill J J J'S 'i7 3(S 500 7>>266 I >> ($ 5.5
.In s >7 10 ~ 000 4 ~ 799 Q.ono
) I < 57 I I ~ 300 6>>533 0 ~ 01:S
.$ ?5 )7 I(ST 200 7 ~ 266 ? ~ 413
.5 J'i 5'f 15>>600 7 ~ C) 00 O.OOO 4 I (I 4 F 000 4 ~ I 9> 0.$ <)
nr?(I 'i f Ci ~ I QQ 4 0.09 I 430 57 5 ~ <) 0 Q F 066 0 ~ 09J 440 sf ') ~ 200 4 ~ nC)h O>>053 450 57 19>>000 4 ~ 333 0 '93 nl I 57 ~ " 3 '00 4 ~ 733 0 '13 421 5) f 5 '00 5 ~ 5:SJ 0 ~ 05.$
4 $ 1 57 6 F 000 4 '99 0 ~ 03')
nnl 57 5 ~ 200 4 ~ 133 O>>013 4!') I !i 7 20>>400 4>>066 O>>053 413 57 !i ~ 300 4 ~ 266 0 '73 f)2 J 57 6>> 400 n.oee O.O13
'!i 7 F 600 n.aee O>> 09r(
44J 57 9 ~ .$ 00 4 ~ Cs 66 0 .013 57 I9 ~ 900 4 ~ 466 O 253 4 I '.) 57 4 '00 ? ~ 73 S 0>> 173 n25 57 F 000 4 ~ 133 0 ~ 013 435 57 14 '00.... 4 0 ~ 173 44') 5 7 13>>BOO 4 F 000 0 '40 4 ss !i7 23 F 100 , 4.()'66 0'>> 01 3 I 101'$7 5 '00 3 ~ J.S J 0 ~ 053
C;8 SI)SI)I;Nf)I=.D SOL ll)S AND OI)GANLC ChuHaN nI.L MEAN VALUI:S AI)C I N GRAMS/CUD 'I C MI) TCS<
5>AHt>LL' SUSPI-".NDL)D SGL LDS OIIGAN I C CIINTCN 7 VAR I AN(
c'i) I <) c> 1)S ~ 733 ti ~ I;I '3 0<
f> :3 ~ I )<) ~ 12(
Lno I')7 I2 ~
'7 33 .I ~ ef>6 t) ~ 09:
I I I lc)r f) ~ c> 3.3 3 ~ 7 3.3 0 ~ OO I'21 I ')7 c).3 ~ 2(>6 4 <<bf>6 O 33.
I Sl I')/ 7 ~ nf>t> << I SS nip I I'il i( I I ~ -'.I>I) 0: kV.
I I Si )7 7 ~ c'Ab Slr 3 5 C): UV:.
I .'.I I <) 7 P0. 06(> 4 <<)Sf>f> 0 ~ 0<) '
I .S.5197 7 ~ 33.3 ;3 ~ 266 ~ 373 I <<,I I')7 . 13 ~ 5 5.3 2 ($ 00 O. 2)30 I I b I ') 7 9 ~ 13:I 3 ~ 39-') 0 ~ 2(SO I c!3197 37 ~ .3.3 3 5i. fief I ~ 49:I 33 1 c)7 !3<< 2t)6 3 ~ )') 9 2<<51 <I
<<I Ol c)r
<<201:) 7 6 ~ 5'3 133 I I ~ (I f) Ci 0 '53 7 ~ 3 ~ 733 n.O13 2 301')7 933 2 ~ 133 0 '53 2<<i 0197 7 ~ 733 4 ~ 066 0 ~ 093
<<501'1 7 11 5>3 4 ~ <<66 0 ~ 25 I c" IL I )7 7+13 I I ~ <) 3 'J n ~ o 1.3
<. I ') / / ')55
~ ti ~ I qq 0 253 i':I I I ') '/ 5 ~ 733 :3 ~ .5') 9 0.52O 2<< I I 97 t) ~ (300 n.f 6f) O<<493
<<.' I I97 i~1.31 <) 7 12 ~ 133 n., c.f, 0 '13
(> ~ 2 ~ <<no 0 ~ I j>0
<<'! c).S I ') 7 66'3
~ 000 :5 ~ f> f) 6 n. o'<) 3 c"..S.S I ') 7 '7 ~ 06 6 599 0 ~ 120
- ! 4 .'3 I 9 / 9 ~ 600 4 ~ 59') O ~ 279 2 )31')7 LL ~ 600 4 f)f) 0 ~ 333 151<) 7 () ~ 4 f)6 399 Oe 759
~ I c) 7
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I 2 ~ t)f>t) 3 <<<~66 0 '53 Saq 4 466 O~ 0') 3 2<<>197 10 ~ t)00 4 ~ 199 0 ~ 519
")51 ) 7 I I ~ 066 OC)C) O ~ 21.3 LLO<<07 n.ooo 2 ~ 933 0 '53 120<<'07 1.50207
<<.oee 400 2 '33 0 ~ 053
- 5) 3 ~ 333 os 053 140207 111207 7 ~ 400 5 F 200 4 ~ << 66 0 '53 3 133 0 ~ 3'7 3 121207 5 '00 ~
2 ~666 0 ~ 09;5 1.51207 F 000 3 a 73'3 I ~ 213, 1<<i 1207 11 3207 tS ~
6<<866 733, 4 ~ 133 2<<533 0 '53 n<<053
,123<<07 7 ~ .) 33 3 ~ Ot)6 0'<<4 I 3 13 3<! 07 LV.OOO 3 ~ 9') <) 0 ~ I It)
C-9 Si)S<>LNDI:<) QL IDS AND OAGANl C CARBON Atoll ALL MI. AN VALUES Al)E 1 N GRAMS/CUI) I C MFTF<e 5 >L<: SUSP<..t<OP I) S>OL I I)S ORGANIC Cf)NTLNT v n<e I Are f I <<.I20 / I ') ~ nf)f) 3eOOO Oo 16<.
11520,/ / ~ 2f>v 2 ~ 39') 0 ~ I sc.
I 25.0 7 9 100 ? o bf>6 0 ~ Oc) 210207 5 ~ 533 2 oc)'33 '
'o?5 220207 4 ~ <)00 2 ~ 5.3 3 2.50a07 6 ~ 133 .5 ~ (166
'5'aOS:I
?40?O/ 7 ~ c'00 J ~ 3c)9 0~040
? ri >) c> 0 7 SHE 400 5 ~ 066 0 ~ I /.I
- I I c?07 5 '3J 3 > 1.3;3 0 ~ 0 ');S
?21207 4 ~ 3;3 J 5 ~ 2<i6 0 ~ 05:I c!;<1207 12 ~ 900 ~ n (I ~ 0 I ()
2ci 1207 9~ 066 733 0+05 I 2~) 120 / 19 F 200 4 ~ .<9c) 0 ~ 039 iI Sl,!)/ (> ~ a, 6() 2+.S9 ) 0.040 2 "c.'.Sc."0 '/ 6 ~ 266 :3 ~ I:5 3 0 ~ I /.I c! J3207 Q~ I 3'3 3 ~ 666 0 ~ 09,5 24320'/ 9e400 4 ~ 199 0 ~ 159 253207, 25 2OO no )J3 2 ~ 25?
c.! I '.)a.'0 7 0 ~ J33 2 ~ 7 S;3 0 ~ 6') 'I c'21)c'.f) 7 7 ~ 933 J 466 0. 0 I.S 2.1l) c.'0 7 I 4 a 46<) .'3 ~ 4 66 0+093 2<<5 "o 7 12 ~ POO ni ~ I '.3.5 0 ~ 25J 255207 I 9 ~ ?00 3 ~ 9.'3.3 0 ~ 05 '3
.510207 4 ~ 533 2~399 0 3,'Po
.<201! 0 7 5 ~ 066 I ~ 4'f>6 ') ~ 05'3 I JOc'07 4 ~ 5 J.3 3%73 3 0 ~ 57'.I 3<<0207, << F 000 3 ~ 26K> 0 ~ 2)J
,'I I I eo 7 6 F 466 2 ~ 73 3 0 ~ 05.5
.I I! I C! 0 7 ,5 o 533 3 ~ 9.3 5 0 37'3
.331
.541do 207 7
4 533 f; ~ 000 3+466
.3.~) I'3 0 '5J 0 ~ 4 I ."I
.'I I 320 / <i ~ .53 J 2 Oao I3 Jl..<20'/ 6 ~ 06f> :I ~ O0 0 Oo I>f)0 S I Sc'0/ ') ~ ?.00 4 ~ 0 f) 6 n. 09.5 I ci 3207 / 4f)6
~ .3 ~ )5 6 f) 0 ~ f>53
.I 15207 / ~ 200 J ~ 199 0 F 040 S?5?0 / 5 ~ f)f)o 3 ~ ') ') ') () ~ 35) c
<< I <>./ () / >i ~ !So(. n.ono 0 ~ <)ci <)
>> c') <) / c '> ~ ').I I 'I ~ I 9') (i ~ ? <i 0
<<>>sn 0/ 4 ~ s>JJ .I ~ 3 S.'S <) ~ 0<) 3 n<<02o/ n. S)3:I 2 ~ 59() n.27 )
ci 5)0207 9 '33 2 93J 0 173
<<11207 6 '66 3 ~ 600 0
~
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<<?.1207 6 ~ Ooo 3 ~ ci f) f> 0'. <ll):I
<<J1207 4 ~ 93.5 3 ~ 199 0 F 040
SIJ"PI'."NI)HS) SOL I PS ANO DAGANI C CAHHCN AL!. Pl'AII VAI UI:5 hf)L< I g GAAHS/CUIJ I C MF TCA
>AISS<Lh
<<<<1/07 USPI=NDL<C) SOL I C) S ri 71$
OOGANlC CON 'I I'.N 2 ~ 3 1'3 I'AAn.e9. I AN(
<<120/ ') ~ 66 6 2 ~ $ 366 000<) .
<< I 32!I j'2
?r 733 4 ~ I <)9 0 ~ 0 3'.
3207 gj ~ 933 3 ~ 266 0 ~ .'3 3 4 3 .S I! I) 7 7 ~ DOO 2+999 0 ~ ?. 79
<<!i,32/ ( 7 ~ 733 2 ~ !i 66 0 ~ 413
<< "i jg'0/ <) ~ .3 33 .5 ~ I <)n 0 ~ ?.JSC
<< I ic.'07 7 ~ 600 3 ~ <1 66 0 ~ fs91 4 c'!320 / 6o 733 '] ~ 066 0 '53 4 '3'j<, 07 ~
1P ~ I$ 61i 4 19O 0 ~ <<.7')
4 45 j,'0? I I ~ "/53 ?ob35 0 '93
<<r.520$ 9 ~ <<6b 3 ~ 266 0 '53 110?17 7+000 ? o 19') 0 '59 I 20@ 17 ng <) 53 1 ~ 5') 9 3~0 5<)
I:$ 0<.' 7 I0 e 200 .1.9 rn O ~ 4 7<)
I <<i 0?.17 9 ~ 006 4 ~ 066 0 ~ 013 11121 / 9 ~ 266 3 '66 0 ~ 6 5.5 12121? 9 '66 3 ~ 0fi6 ,O ~ 257 I 1121? 5 ~ 7.3 3 .1 ~ 3 11 0 ~ 373 I <<IZI 7 11 o200 <<+333 0 ~ 173 I I 521? IIp $300 2e666 O ~ 37 3.
12 $ 21? 6 ~ POO 2 '66 0 ~ 09.3 I 3.321? I I ~ 266 3 '66 0~013 I i.3217 16 ~ 666 5 i26fi I +011 I I'5? I 7 9 ~ Of) 6 2 ~ 799 O.O<<O I ~!iz I / l3,e I:33 3 ~ 999 I ~ I I ')
I <<5<. I 7 I? ~ 000 <<.VOO I ~ OBO
? 1021/ 6 ~ 000 4 ~ !i 33 Oo 013 "'
2?021 7 6 '00 3 199 ~ 159 2.50e I / 6 i'f$ 66 2 e <) .I 'I 0 ~ 09 I
<<i<)? I / 4 ~ 9JJ 2 ~ <)JS II ~ 0I
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P?121? <'i ~ 200 ."5 ~ .5 $ 3 0 '93 2.1121 7 ? ~ 000 3 '66 n. I?3 2<< I +17 9,600 3 !i99 0 ~ 5?.0
?512 I,,/ 9 ~ 066 ? ~ 4 f)6. 000I3
? I 321?, Ci 066 3 afi()6 Os?53
?? 21 $ 7 0 ~ POO 3 +266 0+333 23.'52 I / 19 ~ 200 4 ~ 733 0 '31 24 gd 1? 11 F 000 3 466 ne573 25'.I? 1 I.'i21
- 7. 9 '66 2 ~ <<66 O ~ 173 2 7 F 000 3 933 0 ~ Or) 3 22'i2 I7 t3 ~ 3 3.3 3 ~ Of) 6 0 ~ 233 2:I'5? I / I "i ~ 33 J 3 fifi6 0 ~ 33 '3
SUSI)rill)l-:I) SOL I I).> AND fSRGAN I C CARAON ALL I4L'AN VALUES ARF I N GRAhISrrCUB I C hsE TEA Shhls>LE IISPENDED SOL I DS ORGAN IC CONTENT VARI AN(
"i>5217 I I ~ c133 3 ~ 333 0 ~ OS; r'>5!)2 I 7 9a200 ? ~ Gf>6 n 21 J 1 021 7 5 ~ J>G C) 2 ~ 33:I 0 ~ 09:.
$ ?nr. I 7 5 ~:$ 00 P l.$ 3 0 25>.'
J.snc I / 13 ~ 133 2 ~ 4 f)c)
J<<021'/
r.'17 1'00 2a599
~ 21'~
160 I I I 6 3;33 c' .'3 33 n.OI I
- Ir. I?17 6 ~ 733
- 3 ~ 4 66 0 ~ 09:I 551217 16 F 600 3~ I 3!5 0+053 3<<121 7 I I> ~ it 66 4 13J Oo I 7.3
- 31.$ 217 6.000 2 ~ ?66 0 ~ 21;3
.$ 2 J21 7 7 ~ 200 2 ~ 399 0 ~ 040 J.$ 3? I 7 20 600 2 ~ 70') 0 nit 0
.sit .$ c! I '/ 17e06f> 3 ~ it 66 0 ~ ?'5;5 J I sg I 7 6 '33 2.ueG 0 OSJ 325217 10217 9 ~ C)66 5.066 2 ~ 33.3 0 '53 4 I ~ 666 0 ~ 053
<<2021 7 6 '6b 3 ~ 266 O.niJ it 30 c! I 7 Iles n.066 '.I ~ 266 0.09~
i>40? I / ld 733 n.c)or) no120 it Soi' / 12 ~ 600 2 ~ 933 0 ~ 0!i 3
<<11 17 I) 0 600 I ~ it 66 n.o I i:
it 2 I 2 I 7 6 '66 3 ~ 466 0 '53
<<31217 7 '00 3 '33 0 ~ 093 4 it 1 r! I7 23 ~ 4 C>6 6 F 133 0 ~ 053 4:) I? I / 13 '00 3 ~ 7:53 0 ~ 173
'$15217 6 '66 lsd'00 2 ~ 1 3J 0 ~ 093
<<'!3217 (> ~ 400 3 266 0~413 it3321/ 7 ~ 33.3 3 ~ 53 3 0 ~ 093 4<<3217.
'>.Ii' 7 '00 400 4 '33 0 ~ it 13 4 13 3 IIGf> 0+ 093
<< I >21 7 OeP6G ? ~ 0 f>G 0~093 it c '~.? I / / ~ 53 5 3 ~ ? I) 6 0 ~ 053 I IS ~ 733 5 ~ 355 0 ~ il 7:5
<<<<521/ ) 066 0 ~ 17:5
<<"-~d I / 13 333 3 ~ I$ 6f) 0 ~ 253
',) I t)r I / 5 I 3.$ 20n
~ 3 ~ t) 5 r,'0
!i:;oc I 7 << ~ 000 I ~ ll f) 6 o.n'i 3
! Jttr! I / r" o f$ 00 I ~ 'ass lt ~ 0 >l
'><<tlr17 ii ~ pno ~ c> tl rl 160
'.} I lrl 7 7 ~ 4 t>t>
p.
3 ~ 6f>t> n. it I:$
sc'121 7 6 ~ 73J 4 +066 0 ~ 0!l 3
'> ll? I / I) ~ Ooe P ~ I '5,l 0 ~ I 3.3
)4 12 I '/ li.2no 3 ~ .'>3 3 0+2$ 3 6$ Ja I 7 6> ~ 53 J 3 ~ 197 0 ~ 270
.>U5>l>LWOI'.0 SC)I 105 AND OAGAN I C CAPOUN ALL NEAN VAI-UC5 hAE IN GCIAMS/CUB I C MF TO'll
!Shtll>l I.. 5u r CNO~n SaL IOS OACANL C CONTI>NT VAHLANCI
'ir Sc.' / 7 ~ t30 0 3 ~ 5 5.5 I) ~ 253
!i 3 1217 ~ 17 ~ 9JJ 3 ~ 400 Oe 160
'>4 Iz I / I7~ 266 4 46f) 0 093 Ill
~ ~
5I i217 53J 3 '66 '0 ~ 013
!id521 / 0 ~ IIO0 4 '33 0 '93 610217 4.6 66 2 466 0 '53 t)?O? I / 5 ~ 800
'66 2 ~ 5 53 "0
0 '9J I) 50<. I 7 4 2 999 F 120 t)4021 7 4 '3J 3 ~ 133 0 ~ 0 1.5 I>'i021 7 I 3 ~ 000 3 ~ 933 O~ 093 t>1 1217 Ge 200 2 e33l n.n9l
(>21217 5 '66 2 ~ 466 0 ~ 25.1 f).11 2 I 7 5 ~ >JO0 3 ~ 533 0 ~ 49'5
)>I) 121 7 7 ~ 333 .5 399 F 119 fri I ? I 7 13 ~ '/3 5 I:13 n ~ 173 t> I '521 7 5~ 733 2e266 Oeoll 68 5c' 7 5e 9$ '3 2 ~ Ont> 0 ~ 093 6 3321 7 I 0 ~ 066 3 ~ 33;5 0 ~ 413 61)3~1/
'i.ll? 17 9~ 400 3 ~ .'i I 3 0 '9J t ~ I 2e <SC)f) 2 733 n. 05:I 61521 7 7 ~ >.'33 2 ~ '/ 53 0 '93 625217 f> e 200 ? ~ 266 0 ~ 0 I;s t)li217 17 ~ 133 4el99 Oel19 645217 635217 16 ~ 000 I Je 733 3 et>f>6 0 '93 2 ~ 7 I3 0 ~ 01.1
/10217 5 '33 tlt",6 Oe013
/?Or I '/ 5 '33 2 ~ 199 0 '40 7.502 I 7 7 '33 2 ~ 133 n.? 13 740?. 1,7 0 ~ 7.50 4 2f)f) 0 e09'5 71 121 7" 0 ~ 730 2 ~ 600 '.ooo
/."? I c.' 7 6 ~ fi66 2.666 0 '93
/:5121 7 9e 330 ' 2 ~ 9'5 J 0 ~ 173 74121 7 0 ~ 4ti6 5 ~ .599 0 ~ 160 7138 I7 C) ~ t500 2 ~ 46fi 0 ~ ?. I 5 7>'.'521 / 5 '00 2 ~ 4C)Ci 0 ~ 0<)3 7.5 5r. I 7 13 F 866 3 ~ 6C) 6 0 ~ 213 7<) 3817 14 30 4 666 0 col:5 7 I 5c', l.7 ~> ~ 666 2 599 0 039
/c?521 7 6~ 266 2 ~ 2 6f) 0 ~ 01 '5 I> I or 17 4 ~ 600 2 ~ 199 0 ~ 120 02021'/ 4 '33 2e533 n.093
)I 'Oc.'
040217
/ ..........,7 ~ 466 4 '66 0~ 173 7 ~ 133 4 ~ OC) 6 n~ 053 0->n:.17 17 F 600 3 733 0'e 213 y IS I I i'I 7 '/ ~ I:53 3 ~ 33 I 0 '93 D
SUSPI= NDEO SQL I DS AND ORGAN I C CAR RON ALL MEAN VALUES APL IN GRAMS/CUUI C METFR SAMPLI: SUSPENDED SOL IDS ORGANIC CONTFNT VAR I ANC Uc' c! I / 6 ~ 400 3 ~ f)OO 0 ~ 160 0 51217 8 ~ 533 ~ Sc) 9 0 ~ 2/9 f!4 121 / I 0 ~ 533 5 ~ 13 3 0~49J
$ 1'i 2 1 1 7 16 600 3 ob66 0+093 013217 6r260 Iles 2 ~ 33 3 0 ~ 05J 0232 I '/ 5o 666 2oA66 0+013 0 5.521 / '/ ~ I 33 2+5:53 Oa053
>~4 321 7 12 '66 3 ~ >')') 0 ~ 2 )50 155:52 I 7 14 '66 3 ~ 59') Oa040 I! I '>21 / F 000 2 ~ 933 0 '73
!'2!i21 7 6 '33 3+266 0 ~ 41 I OJS)217 200 2 +600 0 F 000 f! 4'>21 7 I Oi ~ 73.5 3 ~ AOO 0 ~ 04 ()
f"i')c'. I 7 1 4 ~ 666 .I e H6/) 0 ~ 09 1 I
I 4h
APPENDIX D MEAN, VARIANCE, AND COEFFICIENT OF VARIATION AMONG CHLOROPHYLL a CONCENTRATION, AND RESULTS OF APPLICATION OF THE STUDENT-NEWHAN-KEULS MULTIPLE RANGE TEST TO THESE DATA
- Explanation of sample code used in Appendix D:
Example: sample f! 1101185 1 1 0 1 18 5 a b c d e f a the first number refers to the sampling location; numbers 1 and 3 are upstream of BFNP, numbers 2 and 4 are opposite the intake.
b the second number refers to the boat collecting the sample (See Figure 4).
c the third number refers to the depth (in meters) sampled.
d the fourth number refers to the replicate.
e the fifth and sixth numbers refer to the day of the month sampling took place.
f the seventh number refers to the month of sample collection.
Sample 1101185 was collected (a) upstream of BFNP by (b) boat 8 1 from a (c) depth of 0 m, (d) first replicate, on the (e) 18th day of (f) May.
Interpretation of the Student-Newman-Keuls Test The input parameters are reproduced in the output, and a table of sample means sorted by ascending magnitude is also produced. The numeri-cal identification of the means is assigned automatically by the program corresponding to the order in which the means are entered into the computer. Following this are given the maximum non-significant range of means. These subsets are sequentially numbered and list the identi-fying numbers of the two means constituting the end points of the range.
Thus, if the numbers listed under subset, sample, and numbers are respectively 1, 1, and 4, the subset considered is subset 1 and the range of non-significant differences is bounded by means 1 and 4.
(after Sokal and Rohlf, 1969, p. 689)
%1 D-1 Chlorophyll a (III'/m )
SNK TcST 4 MF ANS ~ TRANSFORMA I ION COOK = 0
<<ltIII,IR MS 0 F 00000 3 ~ 2610 4 '410 4 '290 SA III>LE N MCAN YAR l ANCE COtFF 1 C LFNT OF VAR I AT 1 ON NUI 'llI=. 9 I t3 ~ 3678 25 '917 60 ~ 1005 I 101 1 tl5 3 '22<<
110 13.4766 I 1031 85 t3 2044 6 '066 2 '6?6 2<< ~ 3138 I?01105 7 '000 I?02ItIS 4.5456 1203185 6 '142 3 3 . 10 ~ ')282 1 ~ 7822" 12m? 16'1 I 30 I 185 I 0 ~ 9302 I:IO? I 05 9 ~ '.)922 I 503185 It ~ 2622 3 14 ~ 0308 0 '908 4 '557
<<01185 I<< ~ 360<<
<<02 I tI'i I << ~ 4222
<<0 3185 I 3 ~ 3098 7 <<519 TAOL.". OF MI. ANS ( SOR TFO )
SAMVLE N MFAN tdUM".>E R 2 ~ '0 ~ 6. ~ 1 86E'i 1 ~ 0 ~ 8 ~ 367H 0 ' 10 '28c' 4 ~ ' 14 '308 I
T, MAX I MUM NONS I GN SUII Sc IF I CANT RANGI=S SAMPLI= QIJMRI=AS 2 4
(
Ql
D-2 Chlorophyll I) ()118/In )
~ .. Ii. rn.'r n M!:.ANS. TIIANSFnTIMAT II)N Cope ~ o
<. P!e!)il 85 O.ooooo
.I ~ ?C> I 0 4 ~ On I 0 4 ~ 52c)0 bAH!~L! N Mehn) VA)I I ANCF. CDeFF I C I F NT OF V AA I AT ION 0 SuV>c" I=A I (i ~ ') i)P i) 4 '420 :I I ~ I II!>n I) I I lc) i F. ')? gP I 11/ I t)5 n.)ISlo oj I I I I 31!15 <) ~ I A7?.
i ?. 6~ i'i 74 o.nl 5 cp ~ 7')4 I 1?111')'i (c o ') I I c'.
I .? I ~~ I I3 5 <) ~ "1?
I? I 5'I 31 0!i I 59
.I .'3 I ? ~ .3 6? 0 o ?048 4 '97?
I 1I 1 I ~') c I c.' c)(j hf>
I $ )?IH5 I 2 ~ ? 0.34 I I I,31)IS I I ~ '4 I oo 3 33 ~ 7 7 7c3 I 4 5 ~ 4 U)33 a5;70 )n I nl I II)5 c'.0 ~ On 96 I 4 I H I I) 'i ~ 6070 I 4 I .31 t)5 4 c? ~ 0 76SI l7 7J4
~ 4 TAI)Le I)F MeAN5 ( SAR Tt;0 )
5AnIT'Le MI= AN MuMOeA
? ~ 0~ 6 ~ s'i7n I ~ 0~ 6 ~ c) I32 c) i3 ~ 0~ I ?. c l C> 20 4 ~ Oc 33 '778 MAXI '1I)<<n)ON51 GWIFI CANT RANGERS
~I)1c 5!' SAMPL'f 'nIIJMOI:A'b "I ~P 4 IQ i
'0
D-8 Chlorophyll a (mg/rtt 3 )
'.i, IK I'4 5 I Ml: h:4', I ltANGF (3(4MA I' (li4 COI)F. = 0
> '35(I.IQ th S o.normo
.3. 2r. I n nn I o /i ~ .3290
~ h Mi'I...".: t4 M='A(4 VAA [ANCE COI=FF I C 1 FN T OF VAIL I n T I OW rtttt~tSI 4 ~
'3 I .3 ~ I 4 n '5 0 1 I ~ 1042 I 1.51 I (55 3 ~ 142(3 I I 321 (55 s. n 0<.~0 I I 'I;I I US 7'496 2 '3 ~ trod I 0~ 5519 FO iae6 I" 521 3'i 3 ~ I /5? Pi 12 3 I I c35 n ~ 19:sn 3;2 I .S.SP I (35 2
~ /i/5 4/i 4/i 4 /i 0~ 0000 o oooo I <5 SIISS 2. /innn
/i '3 ~ bn I fS 2 ~ 7 9 or) 2v 651J I /i 3119'> 7. 1<<7(5 I /i '.321 15'5 .5 ~ R412 I /(15.5 I (35 b ~ 9:364 I e 0(isa TA(S ~ tIF M~A!I I .,('lit Tt-.f) )
.i A t tf ~l. r't I/t(=.A tt I If tf'll I(
- 5) ~ p.nnnn 0 ~ "I ~ I nn<<
8 ~ no ;S ~ () (3A I 4 ~ 0 ~ 5 ~ 641(I MA X I M I i 'I V i) (4 5 I i,s V I F I C A "4 T le A 9 rp!: ~~
bUI) St. I Sh(APLI-: i'(IMMI)l-(I ~a I 3 I
Q
Chlorophyll a-(mg/m 3 )
SNI'c S n vL>>A)ts, TAANsFoRMATtoN cADE = 0 Ms I'-iltttllt 0.00000 3 '610 4 ~ 04 10, n ~ 5P.OO I
SA MILLI. N hIEAV Vgtt I A'4C~ COEFF I C I CNT OF >I A!I I AT tOI'I I N U I~i I I L' I I 3 2 ~ Oorl? 0 ~ rtsn 6 <<n.0600 I I 'i I I 0!i 1 ~ 0506 1
115211)5 2 444<<
} I I!>31 tls ?~ 7996 I
0 ~ "i 020 oe 520<< I ?4 ~ 8')99 0 ~ 0000 0 ~ .In )2 I ~ 3968 3 0 ~ 5030 1 ~ 0197 173 ?OSO I I'>> I I tt >> 0 ~ 0000 I 152185 1 ~ 7<<')0 I IS)I Us 0 ~ 0000 4 I 2 ~ 7544 2.1003 53 '280 I nn I 105 I ~ 04 7S>>
In<<2 I v';. 5 ~ <<920 I 'l 4 3 I 0'.i 3 ~ 723h I+1502 Of. hler A,NS ( SOW T":O)
SAhIVLC N MF.AN
~II)@II}.;}(
2q t) t (} . It fl 2 f}
t' ~ r} C SIUI}
}' 0 2'b082
~ 0~ 2 ~ 7.l34 4 I@AX I MU~I NQNS 1 t.>>9 tF I CART RAtlC>>F S st)I)Sr: I'>>AMPt r Ntlhtot; Rs I 4
D-5 Chlorophyll 3 a (mg/ttt )
t',)><<4t) t MS
- I ~ I '> I 0 T A t>t>LI>
VUtnA titt r<SI N
.3 ~ t$ 7 70 tt' tAi: Ahl ts, 0 ~ 00000.
- n. s27o VAR I A)4CF.,
Tr>ANsF()t4Mn T I oN coDI: =
ci54o t)
COEFF I C I FI4T t)F VAR I AT I ON
'I 1 <<' <) I )0 O. 5407 20'e2043
..' t) I I 0 5 ? '<<095?
?:in;31 t3;I 3 ~ I 42t?
<< ;3 0 ~ 3l)? 4 6+22?2 ?6 ~ 6432
<<101105 1 1 ~ 93:30
? 10<<>105 <<).; 46t)
? 10 5105 6i ~ 'J2 02 2
i:3 "0 I I t35 ~
I 2 ~ 75I)4 I c' <<6'>c.
'776 3 ~ .3053
?.>0? I i?6 I 3 ~ 025>4
<<'?0 3105 I p ~ r>60' 4 3 11.07nn 2 '200 In.6405
<<" 3() I 10:i <<) ~ 4.$ 1 4
<<" 5036
<<'0 31 >$ 5> 1 2 ~ t)7.32 9<< I'770 0 ~ 71 I:I 9.1900
? >)01 I t5,i 9 ~ 079?
? 4 t)'2 I 85 I 0 ~ Or>50
? n 0.$ 1 t$ 5 tt ~ 306r$
2 '254 TAtt) < Tri 3 )
SAMr)l I- hl MF.AN VUhtt)Ek le 0~ 2 ~ 6190 5 ~ 0~ <<)' 'I 770 2 ~ 0~ <<> ~ .$ 624 4~ 0~ 1 I ~ n744 3~ Oo 12.7son MA X I 'AU i) 'VOX, 5 I 6ht I I- I C A V T I A t4G;. 5
<<) 0:$ 5)-.'.' SAMI>LF Nltt4rll:t)5 I I 3
D-6
'hlorophyll
..i',lh, i')ll!I!1 S. I
<>A VPLE
'U'IIII-.ff I
c a (mg/I!I )
8:i
.>!0,3. 0 770 N MF AN
>< v.J i Or00000 4
~
'270
<w iissws VAIL I AI4Cf:
aeaw 4
~ ri ~
'540 a ON CO!)C COLFF I C I E<VT Of-0 V AH I AT, I OQ
~
3 I? !3266
~ H. 029'3 22 ~ 092.5 211 I II)5 1 1 ~ 7.30~>
21 I? 18:3 1 0 ~ 704 f>
211 3105 16.0446 7 ~ 'I? 'I '3 2 ~ 8 >94 ?2r 4')94
~
2 113.3S ') ~ .3100
?. r. I 2 1 I'.5 7 ~ 331>2
?21 31u!i ~i ~ <) 3<) 4 3 10 ~ 17i0 <> ~ 197T> 1 4 ~
? 31110!> 11 11!if> 2>l'3'3
?. 3 I r! 1 0':> 1 I ~ 34 1 2
? .I I 'I 1 <50 0 ~ 66<32 12 ')000 1 ~ 7701 1 0 ~ 307?
"4 I 110<i 14 ~ 4 192
? 4 1 7 1 II'I I 1 ~ ')1 30 241 I I f53 1? ~ .'5') I II 3 -5.f n04 1 ~ 991 7 39 ~ 1 10<3
"'>1 1 11b 2r0952
<"> I 81 0 i 3 04 I?
~
2'i 3105 1 n. I!0<fJfk 1 f' I SAMPLF MF.A il NUM!5C, f)
)~ 0 ~ 3 ~ 60 c34
?r 0 ~ 7 r!1? !3!3 3 ~ 0 ~ 10r 3700 1 ~ 0 ~ 12 ~ f526'>
4 ~ Or 12 '0RO
'AX 1 MLI n NOiVw I C>N 1 F' C A'V I H AN C> I S iUN0+ T 5 AI<! f>LF.. IUMHI'Aa 1 1 4
3 D-7 Chlorophyll a (mg/t4 )
SNK f >'ST 5 >~! n.ts. TRANSFORMATION COI)E = 0
- = >'clti.l t Ms. 0 F 00000
.I ~ I >10 3 ~ f3770 4 '270 4 '540 Snw@LE MFAN vnA lnwcF coEFF1c lENT 0F vnRlAT loN NUM f:-.:It I 3 4.4'2 0 ~ 2045 12 F 05')4 2 I:$ 1 10~ I ~ t341 2 2 I 5 2 I 13~i 4 ~ f50 t5 (I
?. I 333(3~ 4 ~ 5:3 96 2 .5 ~ 7, 3<50 4 ~ .3f399 no.oooo
?::51 105 :3 ~ 1420 22 321 t3:) .> ~ 2300 223'3 l >35 7 ~ .53 3?
3 .3 O. '> 020 0 ~ 0!)06 34 ~ 64 10 7 .I '5 I I 85 0. >39i54
? 3,3 .? I c! 'i
. 0~ 34 92 2 3353 35 0 ~ 0 9t34 4 3 7 ~ >300f3 c? ~ 1734 1,8 ~ 6901 24 Il I 0 i 9 ~ n.Inn 74 Idl tls 7 ~ 5 '3.32 "4 I Il tt"i 6 ~ 6 "I!t1'3 I~ t'>(i 0. 2f54 5 . III320
'. i;I I I t5 i 3. n )?o
'>'I>. I t3!i. 3 ~ tin 12
'i I I I b5 ? ~ 79:5>3 I ~ 424t>
TAO L '". of hIE ANS I 5() fk TEII )
'inMPLf: N t IF AI4 VUMi)EH
- 5 ~ 0 ~ 0 ~ 5532 0 b ~ 0 ~ 3 ~ 3750 0~ 4 ~ 4? 3?
2 ~ 0~ 5 ~ 2.380 no 0~ 7 ~ 000!5 MnxlMuM .V()N IGVIF ICANT HnNGES SU!ISFT 'AMPLE NU5IHERS I '3 4
.~
D-8 Chlorophyll tt (tits/z )
sNx r-sr wt:A ts. rRANsF OR<A r I oN cnoF. = 0
~ ftnttR hfs 0 ~ 00000 I
.4 ~ 1510 3 ~ f37 70 4 ~ 3270, 4 '540 SAhtPLL N HF AN VARIANCE COt:FFI C Ihltr AF VAR I AT ION I hittiMrll ft I 3 I 0476 Oo 3t)SI3 57 ':$ 50 r'lsllr35 0 69'34
. 215'05 I . 74 60 215 31 c35 0 ~ 6984 3 0 ~ 9312 0~ 7723 94~3729 132'i 1 18S 1 ~ 7460 a2sat'e5 o.oooo 2253113S I~ 047ti 3 3 0 '656 0~ 6503 I 7 t ~ 2050 23ti I 10,5 I ~ 3968 2.352 1 S Oo 0000 2 3'.i.31 c15 oa0000 n ~ 4444 0 ~ 1219 14 't357 Pn st tfs 1 2 '444 2452 1 i35 2~0952 a~ 4 5 I I tt 5 2e 7936 I) 3 3~ 0264 0 '406 .6 ~ 661 7
?'551 I t35 3~ 1420
,2'.i 52 145 ii 7936 2'~'5 3 I f35 3 ~ 142ll n..i to2 TAQLf, OF SCANS (SOQTFQ.)
'e SAhIPLE ht @IF. AN tUMIILrt) 3' O 4656 2 ~ '0 ~ 0 '9312
'I o 0~ I ~ '04 76
'4 ~ 0~ 2+4444
'5 ~ 0~ 3e0264 it,
- .hfAX I'MOht Sttf)'Sl=. T "iUNS'I GW'IF I CA'N'I 'RANGt'."S
'5'Ah\I .I 'F 'NUHIIFR S 3 '5 l
~;
D-9 Chlorophyll a (mg/m 3 )
S).')K Tc 5 I':
MLA IS, TrtANSFO-th)n TlON COOI: = 0.
(C!N IA MS 0 F 000'00 s.; c ln n. 0410 4 ~ 52)>0 SA))PLI! N Mt': AN Y Alt I ANCF. COI=FF 1 C t FNT TIF VAR I AT I ON Nt JMlll:4 I 9 ~ .5304 I '9 ~ 0525 ne.7817 3 I 0 I I tl!) I') ~f)3 4 H 5 I 021)55 9900 3 1 031 t3S I4 ~ .5()64 2 3 t) ~ 52 f0 0 '016 3 ~ 73d 7 3ao I I tl5) 0 ~ A.'350 I t55 '20?
)3. 1984 320 31 05 tl ~ 54 7e 3 3 ~ Ve0() 0~ 5326 Id'265
.I, l 0 I I tl 5 I 'I 3n 33 0? I I I 5 4 ~ ') 4 5!)
5 '3031 05 l~ I 4?.P 4 3 tt ~ 55? )3 '4 ~ 7e4 I 25 '?01 340116 > rl ~ 7.3 30 34021fl5 I 0 ~ f) 3')!3 3403 I I35 6 ~ '213!)6 C) ~ I 127 TAI3Lc Ol'4IFANS (!)Ok T)=.O )
SAIAPLC: hlE AN
'4UMIIHk
- 3 ~ n. 3 ~ 91) Oe 2 ~ 0~ 0 ~ 5?? 0 4 ~ 0~ )3 e 55)HH I ~ 0~ 9 '304 MAXIUN NON."IGNIF I CANT naNGCS Sill l5i'. T 5 h M I) L L 'ilU ) I U C 8 S I I
D-10 Chlorophyll a (ms/m )
I bl 4 M! A'JS ~ TIJANSFO>?MAT I ON COOC = 0
- .!iAI)H 0 F 00000
- I ~ c'.J) I 0 4 ~ 0 I< 10 4 !)290
<,n~)i L< Mf: A'J vnR 1 ANC~ C<3f:FF I C I >:v f OF v AIJ I AT ION.
VU)III'f I I4 o f)2'i:! 2 ~ 4173 10 ~ 6 30'5
'I I I I I <5'.i I2 ~ 9<I<5M
'3 I I 2 3 c'I b I > ~ Of) I >3 511 310b I 5 ~ 01 ~)0 I> '3 In.nl to I'~ 9102 e. 5~))n
.5i' I I !35 I f) ~ <)44 9 3 2 I ..' H 'i I 'i 62 7f')
- 521 31 f>5 <5 f> 06 3 3 I <? ~ ')!5154 6 ~ 4107 I <J a 4 'P
'I 'I I I I <'. 5 I 4 ~ h I 92 3'll <<tc!!) Ih nflt0
~
5 31,51J>5 . 10. Oo'50 3 16 7726 I A~ 6800 f> <364
.In I I 1 f)5, 11 o 0130, 5~ 12tuS I)) 35<34 541 31 Oa 20 ~ 10'ih
- 7. 116<3 TAULf: OF MCANS ( SOfJTI=IO) 9 A Mf'LL) JJ M/AI'J
'MUMfs!-'
I ~ n. I c' '>f3'I 4 2 ~ 0 ~ I4>4l l0 Is I) a I fl ~ f3 V.!3~)
4 ~ 0 ~ 16 ~ 792f>
Mnx I MUM 'JONS I CN 1 F I CANT QANGF S SIJ<5GC T SAMf)LL) MUMI3LAS I .5 4
D-11 Chlorophyll a (!>I@/I!I3 )
',))VI'".5 I >> I AVS ~ I'IRANSFT)rt!IAT I ON COI>L ): 0 r: I Pl'l,l M!I n.oonoo I~ >'>>10 4 ~ 0 ft I II fr ~ !'>5'90
.,Ah!I>LI: N I):. AN V AW t ANCE. C 0 EF fr I C I f=w T OF V AA l h T t TIN
('ll rh(r lt )3
~
I .3 ".) ~ f31) 30 0 ~ 0407 .3 ~ 462 7 II 3 I I >I') 'i 'i 9>)(!
~
II I(' >>~i '~.'I lr 4 I I I I! i<<) i) /474 3 I ~ ~> I C)(~ 0 'f)50 ) 7~ 6\359 I c' I I )! ') I ~ 3(7br
.32.521 r55 2.4444 32 331 Qc) 0 ~ 7074
.3 3 7 '962 tS ~ 6850 40 '526 3 3.31 I d5 A~ .300tl 3 I S(f) I r'5 9~ IC) C)f) 3 4.'3 I I!I'5 .3o (34 12 3 9~ AC) (53 5 ~ 1692 2 3~ 0369
'54,31 I t55 o..)n34
'34.52 I s.l') 12 SA 30 331 f35 7 ~ '4720 a.CC4 7 This~i Of-'!I=AVS ( S.)HTB0) 5 A hl I') L F. hlF. AN VV')F. It 2 ~ n. I ~ 5160 I ~ 0~ 5 ~ 13230 3 ~ 0~ 7 ~ 196)2 f) ~ 0~ 9 ~ CIC) 8;I rhhx I >4Uh)'ows I I-vIF ICANT wANGES SUI::Sa T Shhll~LF NUHflLAS I n I
Q'
D-'12 Chloropliyl.l a (III8/III3 )
'IK TCST Mf:A>IS, TiIANSFORMAT 1QN CI.'ll)t:
- >I IIIIII M 5 0 ~ 00000
- 5.?olo n.o 410 h,5290 h aA hsl>LZ N !5L nN vna I AI<CF. COFFF I C IFNT OF VAA f AT llfN NI JMI3FII I 3 I flfi24 0 '7?3 4 f~ I obh 5 I ':i I I v! i I ~ !In 76 I I ':i? I Is'3 I ~ 7460 I
O 'i I I 5'.51 ISS ? ~ 7'l I>>
I, 3 I ~ 4 700 0 o 4>IRh 46 ~ 0671
'll"iI I U>i I . 7nbo I c"> c' I's I ~ II> >0 I
I 3?5 51 u5 n. 6s).ln' I
I 3 ~ '.ill?0 0.04nr -14.6n,f o I I;il I US 0. '54 >2
'I 5 3? I iJ5 0.!>904 5,I!I 11 il5 0 ~ 6 )II4 ni 3 5 ~ .3564 3 ~ 94 94 '37 ~ I 01 i
'34'.i I I I5'5 . 6 ~ 9I570
.I 4 '>2 I ls 5 '> '9394 345i 5115S 3o 14?>I I .305r'.
TAIILF. IJI-'S=AN 5 ( SOII Tf=.f) h! E A N
)'AMPLf:-
~
MUMf ILIA 3 ~ Oi Oa5020 2 ~ o. 1.4 rno i ~ I ~ 0 ~ I ~ 8624 4 ~ 0 ~ Sa 3564 unX I IAUM WOWS I G>a IF I C nN T fIAIIGF5 SU Ibi".T SAMI>LL '4UMHh!I S I 5
%r
D 13 Chlorophyll a (mg/m )
FO
>;!>R>) I bio 0 F 00000
- I ~ I i I 0 3 ~ (l 7 70 4 ~ .i2 70 4 ~ 6540 5 A<>PL- '
Mt'.AN VAIlI ANCF C()EFI- I C ILNT Ol- V %I I '3 ~
) s <)570 ? ~ 2s> 20 I 5 ~ 5070
<<103 I Ii (3. no 7(>
'> I 02105 Io.ov20 4103305 <y ~ !)h I 4>
4:!0 I I t,l
>3 ~
'i 7300
.300<3 12 '599 42m?O70
~
n 702 I tl5 7 s, (324
<<Os' I tl'5 I2~ 2220
,3 3 <) ~ 5448 0 ~ Os> 06 2o 1123 s>:301 I ti;i ) ~ <<7>)s>
<<!021 05 ') ~ 42Hh s> 3(> 31 Hri <) ~ 7 7 7(i
'3 O ~ 052 >3 0 ~ 7 72.3 I h ~ 5 I,(39 s> '! 0 I I t!!i 5o 2.'380 s> s> 0? 1135 ('. <)040 s> 4 0 .I I (15 !3 ~ <).364 3 !i ~ 1216 0 ~ 2 (34!3 10 ~ 4149 4:>01 I d<> 4 ~ S.3 n(i s> 'i 0!" I 05 5..".~on s> '.! 0 3 I 0!i 5 ~ 5<377 3 ~ I t.OO TAI!L ~
UF h'EANS ( <SO(I TI:.f) )
!ihhll>3 c: MF.AN VUMIIEII 5 ~ n. 5> ~ I 21(i 4 ~ 0~ 6 ~ 05? II 2~ 0~ 0 ~ '3(30r, 3~ n. <) ~ !ih t3s>
I ~ n. ') ~ ti570 Mhx ih'Is"I v(>>3'. I t)N lr- I cnNr:cnI<<ES Sl)l>S'.> f SAM(>LI NI)h>(IF.H S I< Ii I I
39
Chlorophyll a (mg/m )
5'lf TI= 5 T 5 t1)'4> IS TT'ANSFO)4MAT ION COI)C = 0
(". It>>() ) O.oonno I~ I'i)0 3 I'5770 4 ~ 3270 4 6540 N'T'/LV ~ ~
~
- I '~t'>I Q VAP I ANCF. COL'FF 1 C I I=MT <)F VA)IIAT !ON VI )>:.13>. II I,:5t!!i 4 I I I I
)7. rron
)6 ~ 5,'ii )>
I ~ 2.'319 6 '4)>7
- 4) li! I U5 10 ~ 7116
~ I
'i I I 3105 ~ 115 ~ 0 r)50 '
I I
I 5 0~ 'i 700 2 '753 14.5r97
)
nr' I I >35 I 0~4 rt>0 4> 11! I)55 I c' I >72 4 I! I.I I I!5 9 ~ 0792
'I 4 'l I I I c!'.i I 7 1
~ E>002 8 ~ I '>56 0F 802) i o OGI)7 4 5) "Ii)5 I 6 ~ 5702 ni 'l l 31 05 I tl ~ 0340 I 3 ~ 7490 I ~ 5218 9~.310 )
4 4 I I I I)5> 11 + 87)>)3 4 'i )2) )55 13 ~ i3180 n 'i I 310'i In ~ >>>354
~
3 3 > ~ 5 5'po 1 ~ li396 20 ~ n 4 1.3 4'> I I 18'> n+ A)30K
'i 5> I 2 I f35 . 6 ~ 5790 n'>I 31':S 4 'i396 I ~ 4241 TA)3L C IIF N>=ANG ( Sne Teii )
5 AMT>L!. N IAF AN
>VUMIIF.B
.> ~ Oo ' 5 '35H 2' ~ 10.5700 4 ~, 0~ 13.2n90 3o 0~ 17 '002 1 ~ 0~ 17 '794
>>)AX I t>)IJM VONS I Gh) I I- I CANT t)ANGI-5
'I)iiSI'. T SA>MI>) L >5U)4UF.A S.
I 3
3 D<<15 Chlorophyll a (mg/m )
'>I/ ! ') h>I A 3r!AI<. I=!3)INA r) r>>~ r:r)))).: r!
>/ ~ >I >>4 hi',> 0 ~ rl I) I) (I I)
I, I '> ) II l>>lf f>> I i 3> f I) /> ~ >>'I/I >I
>,n <g>>! I~
- I >> I I /n IIn II:t: I I i I(: t",N~j >I.' XIt I A I IIII'
> I>!>.,I ~ <
3 1!.57m 1143 I2 ~ /> 525 n I.'I) 1>3:> i I. an!?
/> ) J 8 I U 's 10 ~ 4?02 4 I.I:II !55 I 3 ~ 2/)96
'3 0 a 4 >i!)r> 0 2>3<<5 11/> ~ 56/>4
/< /.'.3 I I 0!3 0 ~ 3/> 92
/> 2'<2 1 l>5 0 ~ 0000
<<2 3 31!3<3 I ~ 04 '76i 3
'3 >. 5nn!3 625<< ?6 ~ 9575
/> 'I 31 I I'.5 I I ~ .i? '3b 4 I'3/' IIS IOe<<760 I 5.3 I U'3 6~ >3'3<< A
<< 3. ") e I <> !3 4 0 ~ 4>378 7.40 fn 44 511!I y <). 4? Bn
/> <<.321 t3<> >3 ~ 7:S 00
/> /> I 3 I U') 1 0 ~ I 2()!3
>i n. n 2.32 1 ~ 2601 25 '370n 4! 3 I I !3'i
> 3 ~ I /> 2>3
<<>.521U5 5~ ?. '3!3 n 4 'i 3.31!35 4 ~ 4<3 >5!5 2 ~ I s)/> />
TABs .-. OF. Hr'ANS (Snu)C) )
5 A I>!PL<. N hIF. AN NUhloi=.rl 0 ~ 0 ~ 4 r>56
.> ~ Oo n. 42:32
/v ~ 0 ~ '9 'I? 84 J ~ 0 ~ 9~ Sih 4 <5 I ~ 0 ~ 11. 6770 IIA.< I >>U!I I<0:IS) I G>< IF, IC<>sN I IlANGI:S SUI'SF. T SAh1PLI='U!>IDI='05 1 2 3
?. <3 1 I
OI
Chlox'oPIIy3.]. II (II!II/III3 )
'illl' I.'< I '< tll h I'i < I I) hNIII')it<4h I I II<4 1 flf)tt < 0
<<<I <I III II ~ IIIIIIIIII Is I'II
'I hill 'I tl I~ -'I f f<<
til. 4' II ~ ld /II Vhll I AIII V
<I ~ I< in tl I III:,f<f: I I< II tff Ilt- li3II I P f I f )If,
~
- II II II II. II I 3 Oi I! I 4 f3 0 ~ 2I54 5 6<i ~ nt) Sn r< I'> I I I ~ 0 ~ 'lt< ')2 4 1<i<' U5 0 ~ (<'IOn I< I!I 3 I I)5 I ~ 59<3)3
- 3 0 ~ 0000 0~ 0000 0 ~ 0000 4< 2 + I I J<'i o.noon 4 r"!si I c'55 0.0000 4253385 o.noon I ~ ') I 32 ne5284 4 0 ~ 0 3tfn 4 531 I ll'i oe 54 4 3";-i21 )55 2o <)og I !55 I ~ mon 4
4, 451 10>
'3 0~
.. o. onoo 0000 000000 o.oono t< e'<
521 I3'> o, OOOO 4 4'< '3 l t'5 0~ nono
- 3 5. )3t54 .5o 2924 '30 '656 45hl I d: t< ~ 904 0 4'>'521 <5S 6 9<3.4 0 4 ~<'> I I I3<> ~
- a. <5412 0 ~ li21 I TAtIL'I< TIF hiCANS (Sl)ATI-,O)
SAM>>LI= I If;. AN RUI~IOCA 2o oo 0~0000 4 ~ 0~ o 0000 I ~ 0~ 0 ~ 01 il 4<
3 ~ oo I F 5132
< ~ no 5 ~ <) 364 VAX I I~UI! NI.WS I GN I F I CnN I fZANGCS S U< I 5l=' Sh<IPLE iAUMOCNS I .3
D-17 Chlorophyll a (mg/m 3 )
J.K r-' r 4 tf~n:JS>, rt(AN<'F()J;RA T I 09 COOI-:. = ()
- .>'IAJ.JJP MS 0 F 00000
.3 ~ 2<'>10 4 ~ 04 10 4 ..S2<) 0 Sh t<i+Lt: N MFAN vhe I ANce Co(=FJ= IC taNr nF vnn I hr tnN Nr) th'3L H 3 Or ('I (>!I 0 ~ I 32(3 44r6097 I I 0,1 i'(> () ':>2<3.3 I 102 /(> 0 ~ t I <) <) ')
1103 76 I 22<33 i 3 0 0000 0000
~ 0 ~ 0 ~ 0000 I i!t)1 76 o.norm I i'02 f 0 0~ 0000 1 i 03 76 o.nooo 0~ I I c>4 0'r 04 06 '
7:3 r 2049 1.3<) I 7h 0~ 0000 I Jni". 7<3 o. noon I I(JJ 7(> .n. In<)2 4 3 i 7<!6 0 0795 O.r't45 7u,.3
~ ~
I 401 ~ '.>7'>4 Isn2 7t> 3~ 2247 I!JO 9 ](i S ~ 01 77 0 0032 TABLE t>(E AN
'>tilth<'ll: ft C ~ 0~ 0 ~ noo()
0~ O. I I Sn 1 ~ 0~ 0 ~ 0168 3r 2726
'r 4
MA)K I MJJtl N(JN.'> I tiN I( I Ch "Ir t)ht'I( I:5
',ht.'ttl.t'Hl':lItf-'I<: ~
I g I
Chlorophyll a (mg/m )
.":>>: re.". r )I"-h"JS o r RAN.'FI313MAI' Qfl coQF. = 0 L "$ 13>') J M> o..oonoo
.5.;.C: I O nf) 50 4. 532vn
.'> All>>LI't N M>'. AN vAMIApcl= cl)LFF ICII."vr f)F vh,~rhrroh)
>V))MI)LI(
I .'5 2>>0432 5~ 0041 )5 4 ~ >3 'SOO 133 I rf> 4 ~ s) 344)
I I 'I 2 7t) I ~ 2222 III 5 76 0:17 '30 J '3 P. >J I'17 l) o 0 l,n 3 7 5 ~ >" l)."> 0 l.'} I I) e .')
f35) ll
)
I: I; t:; )34!)'I)
I >'I I 70 0 1761
'3 O. nit ZI 0 ~ 1944 94 ~ .5!509 I 311 Y6 0 ~ ">2~i 3 I .51:! 76 0 ).5 7.6n 51 5 /6 o. onoo 5 3~ 16.3>5 0 ~ I 154 I0 ~ 7.3u4 141 I 76 .5 ~ I 462 1412 76 ."5 ~ "'3 I 06 34l .5 76 2 ~ ti 537 0 ~ >33 I 'I
'rhtlL.=. Ol- (.'iORTC93 ttli-"AN'AMPLE=,
N MEA.V
'.V Uh) ) 5=. R 4 ~ O,e O.o 05I37 0 ~ 0 ~ 4571
'I ~ .0 ~ 2, ~ 0432 4 ~ oe 3 ~ I 6i35 MAX I 91)h) V()VS I GVIF I CART 'RANGCG SUI)Sthh)f>LE MUMI31-:Af 1 c'
D-19 ChlnrOPhyl1 fl (mg/m ) 3
)I II I I ') I I<t 4:I' FAAN'.at'tlti~n I l IIN t.tlill.' ll I )i III'I') Il ~ IIII0t) 0 I ~ ~ I ~ I II II ~ 114 J tl /i. rl),'I it)
.4) lt',I '
I II ill 1)i I: 4'I I )/4)1fh II I vn ifn.tr
~
III I I I) II:II )I )- )) I )i))I (lit:I t tc lt::il iit vnit tnt l(IN
)II I . )I ) )
~ I I) I'l)) )(
~
I .5 0 a 7".) 76 0 0720 35 4202 I I .5 I 76 0 ~ () c) 04 1 1.12 /() 0 ~ '3) 2 .3 d I 1.3.1 7b 1 ~ 050()
,3 0 F 0000 0 F 0000 000000 12 31 76 0.0000 I c'. Ic'6 0 ~ 0000 I g"...I I /6 0.0000
'131
.I 0 ~ 4 f) (36 0 '712 57 ~ 2875 I 76 0 ~ !3238 I 33'6'/6 (I ~ f).)itr)
I;I 3 I n. 17ii 6 1431 4,'3'/6 3 ~ 2113 0 ~ 129 ) I I ~ 2048
.I ~ 6264 I 4.t2 '/6 2 ~ 91303 14,.13 /6 :3 ~ 0192 0 ~ Ot." 02 TAO).1= .11." t~:ANs ( S13H TC 3 )
Sntll)LI; N Mt:AN NULLI tIL R 2 ~ 0~ 0F 0000 3 ~ 0~ 0~ 46') 6 1 ~ n. 0 '576 4 ~ n. 3 '113 hlAX l itlilt HfJN 'I ty'4 ll- !Chal'<ANGF S SIII16(- T snvt'LE Nuvncns I 1
3 Chlarophyll a (mg/m )
sltlffl i ) o g(<m'>>ri>. )IIgg) vill (i ' 4'ii< I.I. (( Is>ol
~
Vier [i'll />>s>
~ i" Ill IIIII'i'i cic <<i. f ie.ie>>l'.
~
I ipse.
ol. V;ir.l >l.u>n 3.3786 i'.2877 15.88 1151700 3.4950 1152700 3.8472 1153?00 2.7936 0.5238 0. 0610 47.14 12517GO 0.6984 1253700 0.3492
fl-I
'JIJ()T()J)JIYJ J tl (IIII./Ill ) T
~
~ I~
I'>
I I" I I I>>
i . ~ I I~ ~
iii .i >> ~ ' i I iitl I IIIII Ii I I .r I ~ l i(I\it'pl I >>>
ili >II< I t (ttt COI)I; = 0
','I l t l>t r n.ooono I, I' O .I t(7/O 4 ..3270 4. ()')4 n
~> A I!I) I I: tI t'i) AN VAN I ANCI-'OEF I-' C I I-.IVT I1F Vhl( I A I' ON
'VUtht(I:t(
~ I I ~ r 20() 0 ~ 0/>13 20 ~ 2'/()0
? 101 /6 I > li)4 I 2IOP 76 0~ ')0/3 21 0:3 7() I . n((02 r> 3 0 ~ 7 S(35> 0 ~ 0043 9~8778
? 'nl /6 0 ~ rl I 42
?? 4'c'0 0 ~ 7014 220 'I 76 O. ()99 a
'/6 3 2 ~ I 7(f) 0 '305 tl O143 2301 2 ~ 3'.) 32 2 30 J 2 '040 2 (0( 7() ~ I 7(3/)
4 3 2 '550 0 a 0 7 I .'I I 2 ~ 9>71 6 "401 7() 2o I 756 2 fl 02 7(I I ~ 74 00 "4 O,I /() 2 ~ 24 04 II 3 2 '7/R 0;020n 6 ~ 09)32 501 76 2 '309 2!) 02 7() ?. a 52 () 3 2.")0 'I 7 )~
r? ~ .15 I?
0 ~ 037/
ra':I L nl= M-.ANS (SflRreo)
. > h II!I) L i=. N 14L AN
'V UMIIEI(
rI ~ 0 ~ 0 730')
I ~ oi Io??06 4 ~ oe F 0550 3 ~ 0~ 2 ~ I 70()
- 5) ~ 0~ 2 ~ .'I 720 MAX I IIUM NUNS I O'V IF I Chilr RAN( CS b VIISe. r S AH()LL) i'VI)>VI3LIlS I .3
1 D-23 ~ I' Chlorophyll a (mg/ttt )
stJK rEsr 5, MEANS ~ TRANSFrtRMAT 1 ON CODE 0 EttPOR MS...=.. 0 ~ 00000
- 3 '510 3 ~ 0770 4~3270 4 '540 r'g'. SAttPLE N MEAN VAR I ANCE COLFF 1C 11=.NT nF VARrATLOtt NUMUt k 3 1 ~ 5322 0 ~ 02 76 1 O.o t54 1 9 21 '3 l 76 1 ~ 39 i33 2138 76 1 4 t302 2133 76 1 ~ 7191 2 5 Oe 7962 0+0693 33.0560 22 "51 76 0~ t3157 2232 76 0 ~ 52:3 '3
?233 /6 l. Ono1 3 3 , 2 ~ 2265 0~ 0069 3~ 726 5 2 3:31 /(> 2 ~ 1 706 llew 2 33c'6 c ~ 3c! 2.3 2 $ 3:3 "/6 2 ~ 1 786 3 1.74nn Oilt321 24 nsee an 31 7t- 1 ~ 654 tl 24 3R /6 1 ~ 3704
?4 33 76 2 '095 i 2~ 1 029 o.oele 8040 15;31 /6 1 ~ 9206 ~
(,
2532 76. 2 '856 I 253 3 7ti 2~ 002S
'0.0695 TABLE (lt MFA'NS ('SOB TFD)
SAtnPLt'- 'N MEAN NUMilEt<
2 ~ n.. 0 '962 1 ~ n. 1 ~ 5 322 4 ~ cp 1 ~ .74 49 5 e '0 ~ 2 ~ 1 029 3 ~ n.. 2 ~ 22ti5 I
MAX 1 MUM VQNC" I G'J'1F '1 C'NT RANGES SV>>SE r 'S'AMRI E 'JUMtlliRS I I
t.]
I 1 2 .3 4
D-23 Chlorophyll a (tttg/ttt )
SNK I'FST 5. MFANS) T>>ANSFO>>MAT lON COOK = 0 F tcPOR MS...=..., 0 00000
.'3 ~ 1510 3 ~ 0770 '~3270 ~
4 ~ 6540 Sh! IPLF N M!-'hN VAA I ANCF.'OLFF I C I I=.NT AF Vh>> I A I' Ot'I "NUMltt'M I 3 1 ~ 5322 0 ~ 02 76 I 0 ~ t34 19 21 '3 l 7t) 1 ~ 39.3:I 2132 76 1 4!302 213.3 76 1 ~ 7191
?. S 0 '962 0 ~ 06") 3 3 3+0560 PP"31 76 O~I3157 2232 76 0 ~ 52:3'3
?.?.;33 76 l. 0401 3 3 ',2 22t)5
~ 0~ 0069 3+7263
? .'I:3 I 7t) 2 ~ I 70')
2 332 76 2 ~ 322.3
? 5.33 76 2 ~ I 7db 4 ~ 3 I ~ 7449 0 ~ I 821 24 '5bb,
?h 31 76 ...I ~ t')5413 24 32 /6 1 ~ 3704
?4 '33 76 2 ~ 209.)
2 ~ 1 02<) 0 '6lb 1 I ~ 8040
?5.31 fb 1 ~ 9206 2532 76, 7 ~ .3856 253 '3 76 2 ~ 0 025) 0 069
~ )
rho .=- III- MFANS ISO>>rt=.n)
=
ShtlPLt= tc MLAN QUMitEtt 2 ~ n. 0 '962 1 ~ 0 ~ 1 ~ 5) 3?.?
4 ~ 0 ~ 1 ~ 7449 J0 0 ~ 2e 1029 3~ n. 2 ~ 22ti5 MAXlt<UM NONSIGNIF ICANT AANGES SU) ISE T SAM)LE 'PUhltII. H 5 1 2 3
D~24 Chlorophyll g (tttg/ttt )
SNK I 6 t tilt t)A ht S =
I .i 1 0 I:i 3
3 ~ R770 ht;:AVS TIARA )SFOtthtA T I T)N CT)OC 0 ~ 00000 n ~ '}2 70 4 ~ f>54 t)
= 0
'htPLtt N MI A I Vhrt fhNrt" <Ot~fl-'tC ft:Nf Ilr V At<fhl fON t tl)htl tv. tt 1
'3 2 ~ 704 ( 0 ~ O.it) 0 'J ~ 7 tt 'i.l-r' 'i l F ti ;.. nr;t>n
- I t')
tT-1'i S Si t'~
2 3 1 . 7nnin 0 ~ I 62? 23e0904 77.'i 1 76 1 ~ i l 26 2 52 i'6 1 ~ 5111 225.$ 76 2 '095 3 1 ~ 0505 0.0741 . 14.7055 2 1'~ 1 76 1 ~ tl6 tt 1 lory 2352 76 2~ 1 16H 23 i3 76 1 ~ 5729 3 0 ~ 0140 0 '711 32 '327 2n il 76 0 ~ 57. 3ft
- 7. 4 'i2 76 0 ~ H/30 2n.>3 76 l ~ 04 76 2 '037 0 '604 7614 2551 76 2 ~ 034 9 2552 76 7 ~ 2 8'i)')
? 153 76 2 ~ ."i 2'63 0 ~ 06,30 TABLLi I)F htt-ANS I ST)ATt-I>)
SAitPLL N ttEA t
'VUMHCA 4 ~ 0 ~ 0 '14c's 2 0~ ,1 ~ 74Ii 4 3% 0~ 1 ~ 6 ~0'>
5~ 'v 0~ 2 ~ 2837 Qo 2 ~ 284 7 SUUS:
1 T,
htAX'I htUR 'VOWS'I 6't'IF'ICAhtT AANGL.S O'AHPLF .'4UtnOt: AS 4 '1 1%
D-25 3
Chlorophyll a (mg/m )
l~ 5!MK CE
.....ERAOA.
ST "
4 MLANS i TAANSFORHAT ION CODE =
MS..~....,,, ...0 ~ OOQOO.
0
' 2610 4 '0410 " 4 ~ 5290
'~l '
~
SAMPLE N
~
MFAN, VAA'IANCE COEFF I CIFNT OF VAR I AT ION NUMQFA 1 0 '820 0. 0406 34 '410
... 3101 76 0 '492 3102 /6 0 '904 3103 76 Oa6904 2 3 0 F 0000 Oa0000 0 ~ 0000 320 I 76 0 F 0000
.....;3202,76 .0 F 0000
'3203 'I'6 0 F 0000 t t
...3... 3, ...,0+5020,....,.'...0 0406.... ~ 34e6410 3.$ 01 76 0 ~ 6984 3302 76 0 ~ 6984
......3.30.f'. 76........O. 3492. t t 4 3 76....10 ~ 0620' 8+5920 .;" I ~ 6512
~"
.. ~
14 ~ 9555
...,340 3402 '6 1.,
7 ~ 6824, 340'6 0~ 0316 t
TABLE OF MEANS ( SORTED ), >'i*";j)P'>~>'"
SAfhfiLE...N ' " .MEAN ...
NUMBER 2
1 e... ~...
e .," .',~."
0 ~,,0 0 ~,. "
~ 0000 0 ~ 5020
" '.:-!-.~ 0 ~,-'.-
3
.0
~
~
.""" "0 .'.
~
= ~ 0'o 5820 8 ~ 5t/20......
SVU.SET, 1 ',
MAXIMUM NONSI GNIF I CANT RANGES--";"
. SAHP.L~VY.BE.RS 2 3 t
~ ~
t 8 t
D-26
'3 Chlorophyll a (mg/m )
N SNK Tt:S T
.. ERROR AS 4 MFANS ~ TAANSFORMAT1ON COOL =
0 F 00000 0
3 2610'AMPLE 04 1'0 4 5290 N MEAN VAR1ANCE COEFF1ClENT OF VAR lAT lON l,..... NUVOI"R 1 3 0 '328 0 '406 86 ~ 6025 3111 75 0 ~ .54 9?
3112 76 0 F 0000 3113 7w 0~ 3492
? 3 0F 0000 0F 0000 0 F 0000 3711 76 0F 0000
......,'3212 76 0F 0000, 3213 76 0F 0000 3 ~ 3 . 1 ~ 0476 .0 ~ 1219 33 '333 331 1 76 1 3968 3 51 2 76 0 ~ 6984 331 3 76 ...1 ~ 04 76 3 6 ~ 51 84 . 0 ~ 2845 8 ~ 1 83?.
3411 76. Ga 9364 34 12 76 6 '348
- 54 13 76 6 '040 Oa 1118 I. TABLE OF MF ANS (SOATEO)
, SARPLEi N .......MEAN NUM8t' 2 ~ 0~ .0 ~ 000.0
,1 ~ 0~ 0 ~ 2328 3 ~ Os 1 ~ 0476
.4 ....,........
~ 0 ~ 6 ~ 5184 NAXlMUM NONSIGNlF TCANT RANGES
..SUOSET SAMPLE NUYOERS .
1 3
L 3 D-27 Chloropltyll a (mg/m )
'. lvl' l 5 T 4 NL>AtVS ~ TRANSFORYAT I ON CODE ~ 0
~ P. t t o t v 43t 5 0 ~ 00000 5 ~ '~~) ') 4 ~ 0410 4 ~ 529~
43- 4 t V AW fA!3C= CC="FF I C li'3 T "3. < 4~ I l T I.'>>
t JUMiJi. R 0 . ~ 1
'3
+43492 ' ~ 0000 0.0000 ogt492 Q<
31.38 3133 76 3
~ ~.~ 0, 30@2
'qp
'J 0~ 0004 ~
p pppp 0 ~ 0000 Q 3;331 76 0~ 0000
- .... 32 S2 76 . 0 ~ 0000 3233 76 . 0 ~ 0000
- 3 8 1 ~ 0714 4 7 ~ 1404
- 3.3 '32 76 2 0 0952 133 70 ~ 0470 Q 3 1 4 3 4 0 t>560 0 ~ 28~$
Qi 1431 76 4 ~ 5396 I ..........343c! .76 . 4 ~ 1904 34 33 76 502380 Q~, 0 1'>c) 7
! TAOLF. OF t~EANS (SOATFO)
Q~. SAMPLE iV HEAt I ...NUMI)ER, 2 ~ 0 ~ o.oooo i 1 ~ 0 ~ 0 3 ~ 0 ~ 1 ~ 5714 4 ~ 0 ~ 4 '560 NAX I MUM NI)tVS I OiNIF I CAtVT RANGES SUHSET SAMPLE NUMI)ERS
. 1 . ... 2 . .... 3 G
3 Chlorophyll u (mg/m )
Sample Number Mean. Variance: Coef fi'cient of; Variation 2'.,2117.0950 0.2848, 2,4. 13 3X5107'6.
3152076 1 7460 3153076 2.,7940
'..2328 0.0406 . 86, 55 3251076 0.0000 3252076'253076 0.3492 0.3492 2,0990, 0.1250 1.6. 84 3351076 2e0980 3352076 1.7460 3353076 2..4530
D-29 3
Chlorophyll a (mg/m )
bNI( I L .') I 5- PEANS TAANSFORMAT l ON CODE ~ 0
...PHIIOA MS ...... ..0 ~ 00000...~).
30 1 51 0 J ~ 8770/ 4 ~ 3270 4 ~ 6540 Q',, 5AHI)LE L.'NUNQEA N
~
PEAN VARI ANCE COEFI- I C I EN T OF VAR I AT ION j
6 2 ~ 9100 0 ~ 04 06 6 '20?
4101 /6 4102 76 4103 76 2 3 4 ~ 0740 0 ~ 7 723 2I ~ 5709 4201 76
..4202 4203 /6 3 .3 6 '528 .1~5039 20 '609 4301 7s) 4 302 /r')
4 303 /6 4 3 6~ 2856 0 ~ 3658 9 '225
.. 4401 /6 4402 /t)
Q 440 I /))
I 5 5) ~ 354 4 0 '406 765) S oj 4501 '/6 4')02 /I)
'I ' I) I 0
TAOLI= I)F 'I'ANS (SORTCO)
S A M I ) L I=' N MCAN NU!>lIEH 1 ~ 0~ 2 ~ 9 1 00 .
0~ 4 ~ 074 0 5 ~ 0's 5 ~ 3544
,3o 0 ~ 6 ~ 0520 4 ~ 0 ~ .;,.6 ~ 2856 P AX I MUM NUNS I GN IF I CAN T IIANGC5 Q SUOSET SAMPLE NUMOCAS 1
3 Chlorophyll I SNK I't:5 I EHHOA MS 3 ~ 1510 a (mg/m )
3 ~ f5770 5 Mt.'ANS > TRANSFORMAT 1 ON CODE =
....., . 0 ~ 00000 .
4 ~ 3270 4 ~ 6540
~ ..
0 ig
'0 'Ah1f~f.f: N NE AN VAR l ANCE COEF V l C 1ENI OF VARIATION I NUM I I I!II I c' 3280 0 ~ 04 06 0+660 3 4 II I 76 4 I 12 76
'4 11 J 1'\
~ ~4 I 3 3 '920 0 '536 26 '575 4? I l 7fI
., . 4212 76 4213 76 3 3 .5a 4 708 0 '723 16 ~ 0635 4311 7(I 4.'I l Ib 4.j 1.1 .76 3 6~ 7512,, 1 ~ 5039 18~ 1649
...,. 4411 76 4412 76 441.5 5 3 3 '0fI4 Oa2845 14 '825 4511 76 4'3 I I II6 0 ~ fi'3 1 0 TAQLF. OI-'FANS (SOfITEO)
SAMPLI: N MF.AN NUMUER.
1 ~ '0 ~ .2 '?80 2 + w ~ ~ 0 ~, 3 '9?0 5 ~ 0~ 3+6084 3 ~ 0~ 5 ~ 4 708 4 . '0 ~ ...,. 6 ~ 7512 I
I MAX 1 MUn1 NONS 1 GN tF TCANY RANGFS SUIISE T SAMPLE NUhlHFRS L .... 1 1 ...4....
D-31 3
Chlorophyll p (1<<f,/I<I )
5<VI< I L 5 I ") I/EAIVS TAANSFOkMATION COOE = 0 E I II I) I I 8 5
< 0.00000 3~ 1510 .3 ~ 07'/0 4 ~ 3?.70 4 6540 jw( "hl<<<I I II Ml; AN I/hlI I AflCL. COI:I I' C f I!N T f)ft </Aff I A l I flhl
~
I I'Illh'I I I II 1 I 0? 64 0 ~ 04 06 6.6617 4131 /<.
4 1'I'<<
n I 51 /<<
I ~ 91 00 Oo OI< 06 6 '?f52 4< 2 31 '/6 4232 /6 r6 0(
I 3 3 3 ~ 8412 1 '633 31'+4910 433l 76
/< 33? /6 433 I 76 l
- 0. /'6 3 le74'60 0 F 0000 0 F 0000
. 44131 44 52 76 44<3 5 /6
~
3 'S ~
.I ~ 6084 0 ~ 2845 14 '825 4531 76 4532 76 4533 '/6 0 ~ 3<>58 TABLE. OF MEANS ( SOIR TED) 0 SAMPLI-.
I IUMIIFff N MEAN 0 4 ~ 0~ 1 ~ 7460 r ~ 0~ . ,2 '100 I I ~ 0~ 3 '264 r> ~ 0~ 3 '084 3 ~ 0~ .,3 '412 MAX 1 MUM HQNS 1 GN lf 1CANT flANGES Q SUUSLT SAMPLE NUMBERS 1
Qp,
3 Chlorophyll a (mg/m )
Sample Number Mean Variance Coefficient of Variation 3.3756 0.5284 21. 53 4151076 3.1428 4152076 4.1904 4153076 2.7936 2.5608 1 ~ 0162 39.68 42510?6 3.1428 4252076 1.3968 4352076 3.1428
- 0. 3492 0.1219 100.00 4351076 0.0000 4352076 0.6984 4353076 0.3492 4.0740 0.0406 4.95 4551076 4.1904 4552076 4.1904 4553076 3.8412
3 D-33 Chlorophyll a (mg/m )
SVK (t: S r 4 MEANS ~ TAANSFO(tMATI ON COOE =, 0 F AAUM MS =..... 0 ~ 00000..
'3 ~ 2610 4 ~ 0410 4 ~ 5290 SA(A()L(': N MF AN VAA 1 ANCE COEF F I C Il'.NT OF VA(0 I A I ION NUM(4L(t 1 3 0~ 0000 0 F 0000 0 F 0000 1101')(a 0F 0000 I I'02 Oe0000 110 3 t)6 0 F 0000 W) 3 0 F 0000 0 0000 0 F 0000 I? 0 1 66 0 ~ 0000
! 202 86 0%0000.
I 2 0,'3 t(6 0 F 0000 3 3 0 '656 0 '845 114 '644 I .SO 1 t)f) 0~ 3492 I 302 uf) 1 ~0476 130 3 86 0 F 0000 4 3 2 '608' I ~ 9917 55 ~ 1 107 1401 06 ~ 7936.
1 4 02 II() 3 ~ 04 12 1403 86 1 ~ 04 76 0 5691
(
I O TAHLF Or. MCANS (SOATFA) j I. SAM()LC,. N HL AN
('I (JMI SE(t (I a 0000
- 0) 0 s 06(3()
3 ~ 0 ~ 0 a 46'i6 4o 0 ~ 2 '60(3 9 NAX I MUM NON') I G)N IF I C'ANT RANGES SUUSt='T *. SAMPLE NUMOEIIS 1 1 4
D-34 3
Chlorophyll a (mg/m )
S>NK TI S T MehNS ~ TTIANSFOAMATTON CODLi I: II I I I I I I fd '.w I>>OIIOr) II I ~ > li I () 4. I) 4 1 r) 4 ~ 'l l>>) 0
~ hHI'I I tl Pl'l I V hl) I hl'll I" (,Ill I I )
I' I>Il ( III V hl) I h 1 I IIII IIII)'>)> i) y 1,5 I I I I o'>>
I I
~
~
396)5 7460 0 1219 25 F 0000 1112 06 1+3960 111.$ U6 I ~ 0476 2 3 0 ~ '14')2 0 ~ 1219 100 ~ 0000 1211 de 0. 3492 1212 c)T> Oa 69()4 I 121,5 66 00 0000 Qj 3 S 9 ~ .36 76 2 '939 16 '680 I ll I I)e 7 ~ 6236 1312 u(> I 0 126)5 I %1.5 )56 I 0 ~ $ 'a24 Qi 3 4 '396 0 '536 20 ~ 3519 I
I)e 5 ~ '31) 72 I 4,1 2 UI'> 3 0412 Ihi I I H6 1904 0 ~ U)7V I
Q TAOLF OF Mf'ANS (SOATFD)
SA M)HALF N UM)' )')
2 ~ 0~ 0 ~ '3492 I Oo I ~ 396 I)
Q. 4 ~ 0~ 4 '$ 396 3 ~ 0~ . 9~ 3676 0 MAX IMVM NONSlGNIF ICANT AANGES SVOSF T SAMPLE NVMOE,AS, I 2 3 G
D>>35 Chlorophyll a (mg/m 3 )
SNK I LS I 4 HEAIIS, TAANSFOAMA7 1 ON CDI)E = 0 EIt HUH vS 0 F 00000 3 '610 4 '410 4 '?90 SAVILE MEAN VAR I ANCE COEF F 1 C lENT OF VAA AT lON 1
NUMIILA 1 I ~ 9/UH 0. ?o<<5 26 ~ 956 3 I 131 66 2.0952 1 132 i:Ci 1 ~ 3968 1
r 'I 113 ) )I6 231 ()6 ?
2 2
~
'116
~
4444
<<444 0 0406 9a 1 I6 I 12SZ t!6 2 ~ 0') 52 1233 86 2 ~ 0952 3 3 9~ 5036 2. )716 18 '388 1.$ 31 t>6 9 '792 I 33 06 11 '000 133) Ue 5 ~ 0316 4 12. 164?. 1 ~ 40?0 10 '079 1431 06 12 '536 I <<3? t)6 10a028?.
I <<.3.) I;6 13 ~ ?.1 00 1 ~ 1 )4 7 I
9 TAI)LE nF NEANS (SI)ATEO)
SAVVLE N HEAN.
NUI"I<EIt 0~ 1 ~ ,9788 0~ 2 ~ 2116 3 ~ 0~ 9 ~ 503t) 4 ~ 0~ 12 t p!I2 1
PAX IhluW NONSIGNlF ICANI'ANGFS SUBSET SAMPLE .NUMUEAS.
I I .2
- r. 3
3 Chlorophyll a (mg/m )
SNK TL'ST h'FANS, TRANSFORh'AT ION CODE = 0 Elf ROP. h1 S n.ooooo 3 '610 4 ~ 04 1 0 4 ~ cJP.90
~~I SA h)PLE N YEAN VARI ANCF COEFF ICIENT OF VARIATION NUMBElk 1 3 0 ~ 4656 0 ~ 6503 173 '050 1 1'51 U6' 0F 0000 15P Ut) 0~ 0000 1153 06 1 ~ 3960 2 3 2a Oc)52 0 ~ 1219 16 ~ 6666 1251 t!6 2 '444 1252 U6 1 ~ 7460 1253 U6 PE 0952
,J 3 P. ~ 21 16 0 ~ 6503 3t) 0 4642 3151 Ut) 1 ~ 7460 3152 f!6 I ~ 7460 3153 G6 3o 1428 I
4 3 :l e 2592 0 ~ 2045 16 '663 I ......
....... 3251 06 3 '412 125c! t!6 2 '936 l25,I Uf) 3 ~ 1420 O.4268 TA8LF. OF MI=.ANS ( SOR TED )
SAh!PLE ....,
NUMBER
.. N MEAN 1 ~ 0~ 0 ~ 4656 2 ~ 0~ 2 '952 3 ~ 0~ 2 ~ 2116 4 ~ 0~ 3 '592
D-37 3
Chlorophyll a (maAI )
SNK I I.s I 5 MEANS e TRANSFORHAT 1 ON CODE = 0 ERROR MS . .. 0F 00000 3 '510 3 '770 4 '270 4 '540
.Q+ SAMPLE N MEAN VARIANCE COEFF f C1KNT OF VAR 1 AT 10N IIUMI3I'A . ~ ~ - .. ~ ~ - ~
1 0~ 1 164 0 ~ 0406 173 '049 2101 c 6 2102 86
?103 O6
~ ~ ~
c 3 0~ 1 164 0 '406 17'049 2201 U6 2202 06 2203 II6
- 1 3 2 '5AAA I ~ I 4AI III '596 e,'I 0 I 2302 V6 2.I03 06
'............ 2401 '86 3o 3756 Oo 0406 '+9726 2402 06 0 24 03 c.b 5 3 5 '708 0 '406 3o6852 2501 86
....2502, 86
?50 3 Gb 0 '601 Tar3iE oF MEANs lsoRTEn)
Q~
(
I
'AMELE l4EAN NUMQEH 1 ~ 0~ 0 ~ 1164 2 i ,.. .. ... . 0~ 0 ~ 1 164 po 0~ 2 5608 4 ~ 0~ 3 '756 5 ~ .. .....,Oo 5 '700 I
MAXIMUM MONS 1 GNlF lCANT RANGES SUOSET SAMPLE NUMOERS' 4
9 L.
D 38 3
Chlorophyll a (IIIg/III )
SNK TLS r 5 MFANS s TI1ANSFOAMAT'lON CODE = 0 EAftflit MS 0 F 00000 3 '510 3 '770 4 '270 4 6540 SAMPLE N htEAN VAA!ANCF. COEFF fC lENT OF VAR 1 AT 1ON NUMI.IEft 1 3 1 ~ 9788 2~ 1 l.'36 73 '705 2111 ISt)
! 21 12 <<I6 0 j ? l 1 3 IIt)
I
? 3 0~ 9312 0 '845 57 '822 221 I u6 22 la IJ t.)
I 2213 06 GI I 3 3 5.8942 7a 7775 47 ~ 3146 231 1 t)6 2312 IJt) 2 31 3 Ht')
oI 4 3 5a5892 11 ~ 1197" 59 '617
) 2411 tJ6
?41 .
?4 13 tS6
) J 6 '322 lal822 18 '?47 25l 1 86 2512 b6
?511 IJt) 4 4955 0'nMpLE I.
TAULE OF Mt'ANS (SOATFO)
NVMUElt ..
MEAN 2 ~ 0~ 0 ~ 93 1?.
1 ~ 0~ 1 ~ 9788 4 ~ n. 5 '892 3o 0' 5 '942
, 5~ 0 ~ 6 ~ 0322 h)AXlMUM I'SONS?GNlf 1CANT AANGES 0 SVOSE T 1 ... 2, ....5,.
SAMPLE NVMI3EAS
D Se Chlorophyll a (mg/m 3 )
C7 SNK II S 1 5 PEAIVS ~ TRANSFOAMAT ION CODE = ~ 0 EAICCI< II! S = 0 ~ 00000 I 3 ~ I 51 0 3 ~ 8770 4 ~ 3270 4 ~ 6540 Cl
[
SAMPLE N NUMQEA PEAN VARIANCE. COEFF I C IENT OF VAR I ATION I 3 2 ~ 2116 0 '503 36 ~ 4642 2131 Ob 2 I 3r.')6 2133 86
.3 4.IOon 0 '878 16 '667 c'?,I I (16 2c.'32 c36 2233 86 3, 3.....9 ~,1348 ........, 0 ~ 6679 8 ~ 9463 2331 86 Q . 23 J2 II6
?333 86 4 3 9i 1 142 0 ~ 1483 4 '258
.........2431 II6 .
24 32 86
?433 86 5 3 6. 8470 0 '228 ~ 11 '263 2531 06
.2532 06 2533 H6 0 '154 TABLE OF Ml= ANS ( SORTEI) )
Q SAMPLE L....,..
(
NUMIIEn N MEAN I~ , 0~ 2 ~ 211,6
.2 ~ ............ 0 ~... '4 ~ 1904 SR 0~ 6 '470 4 ~ 0~ 9E1142
. 3 ~........:. 0 ~ ..'. '.9 ~ 1348 PAX I MUM NIJNb I CN IF I CANT IIANGES 9 I SUUSI: I'AMPLE NIJMHFInn IInf'I viz'tntIel! cr'I'Llil:IHIN nnk vAJ<IIIIIN I 3 0~ 3492 0~ 1219 100 ~ 0000 2151 86 2 15c'o
@I 2153 ti6 I
2 I ~ 1640 0~ 0406 17 '205 22'i I 86 2252 U6 2253 06 3 3 7 ~ 5454 2 '957 22e5525
?3ci I 86 2 15r 86 2ZS3 116 n 'I 4.o7so 0 '309 I 7 ~ 8797 2451 bb 24 Si2 86 245 1 86 5 3 6n 1496 0 ~ 7236 13 '328 255) 86 2552 66 255'3 86 0>>. 0 ~ 862 t) 1 'TAHLF. OF MEANS (SORTEO)
QI SAMPLE. N ~
NEAN t .. NUMOKA 1 n 0 ~ 0 ~ 3492 2 ~... 0 ~ I ~ 1640
'no 0~ 4 '750 5~ 0~ 6 ~ 1496
. 3>> 0~ , 7 ~ 5454 NAX I MUM NONS IGNIF I CANT RANGES 0 s SUOSET SAMPLE NUMOFRS I I ., 5 4
D-41 Chlorophyll a 3 (mg/m )
sNv. rc.sr 4 Mt'.ANS ~ TIEANSFORMAT ION COOK "-" 0
, EltftIJII hIS ~ .0400000
'Q".
j . 3 '610 4 '410 4 '290 I
SAMIiLE MEAN VARIANCE COEFFICIENT OF VARIATION I .....NLJhtl)KA 1,.3 0 ~ 1164 0 '406 173 '049 3101 tJ6 o.oooo 3102 H6i o.oooo 31 03 86 0~ 3492 lory 2 3 0~ 4656 0 '045 114 '644 3201 t56 I~ 0476 I
..3202 tl6 0~ 0000 3203 86 , 0~ 3492 C>>.I 3 3 3 ~ 9576 0~ 1 626 1085 3.)01 t36 3. 4 920 S. 5.>os 8ri 4.19O4 3 503 86 , 4 ~ 1904 I
6 I n 9 ~ 64 16 0~ 1 799 4 '992
....... 3401 t56 9 ~ 4314.
34 02 86'4 10 ~ 1298 03 8'6' 9 ~ .5636
~ 1669 I
Q TAOLE Of'EANS (SORTEI'>)
SAMPLE , hIF.AN NLJMHE R 1 ~ 0 ~ 0 e'I I 64 le ~ 0 ~ 0.4r SfJ
.3 ~ fJ i 3 '370 4 ~ 0 ~ , 9 '416 MAX I MUM NONS I GNIF I CANT RANGLS
.SUOSET .. SANPLE .HVhtRERS 1 1 2 0
Q>>
0
D-42 'P 3
Chlorophyll a (mg/m,)
SNV, l'LS T 4 MEANS ~ THANSFORMAT I ON CQOE = 0 MS o.ooooo 3
F.AROINT
'6lO SAMPLE N 4 '4 10 MEAN 4~5290 VARIANCE COEFF IC IHNT OF VAR I ATION .
NUM!IL) Il l 3 0~ 8148 0 ~ 0406 24 ~ 7435
- 5 l 1 1 u6 1~ 04 /6 3112 06 os6984 5113 db D.c 9an 2 3 1~3960 :5 '143 132 '876 3211 86 3 '4920 5P 12 c$ 6 AC)984 321 3 86 o.oooo 3 3 5 ~ 3544 1 ~ 1 381 19 '242 5'51 1 86 C) ~ 2 856 3.5 l 2 86 5 ~ 5)872 33! 5 Oo 4 ~ l904 f V:llew& 8: i'09 5'1 f!8IVB jhf 1 db l 0;bblO 3412 06 I cl ~ n I 12 34>> II6 9~0792 I ~ 2678 TAOLE OF MEANS (SOATCf>')
i.......... SAMPL'F . N ...... ME'AN NIJMIICA 1 a 0~ 0 ~ 8148 2 ~ 0~ 1 '968 3 ~ oe 5 '544 4 ~ 0~ 9 '528 Q MAX 1 MUM NONS I GNIF I CAN]'ANGES
....,.... SU!5SE T 'AblPLE NUMBERS 1 1 3 L
D-43 3
Chlorophyll a (mf,/m )
SNK TeST,4 MEANS>> TRANSFORMATION CODE = 0
, EAf<OA ff5. = ., 0 ~ 00000 3 ~ 2f>>t D 4+0410 4 5290
'; Shf>PLf' MEAN VARIANCE COFFF ICIENT'OF VARI ATION
! ... NUMfff=A 1 3 I 2804 0 ~ 'i2 A4 S>>6~7727 3131 tt6 1 ~ 04 76 3132 ff6 0~ 6984 3133 86 0 952 24 3 9>>1 00 0>>.04 06 6 928?
.l23 I:36 >>
3 1420 32 32 86 2 '936 l 3233 c36 ?~ 7936 tet (
'1 3;I 3 31 tat>
8 ~ 49/2 fl ~ 0316 3 ~ 21 1'1 2 1 ~ 0888 33:12 86 10 4760 333 3 ff6 6 '840 4 3 9 '390 2 1954 16 '921 3431 86 7 '332 3432 86 10 '062 J43 3 06 9~ 777fi I
I e 4939 I
TABLf." UF MEANS ( SOW TEt>)
SAMPLE. YE'AN NUMQE fC le 2 ~
0 0
~,
~
I +2804 F 9100 8 0 ~ 8 '972 l t ~ ..0. 9-0390 HAX I RUM NONS I GNIF I CANT AANGES SUE SE T ...,... SAHPLC l4UHBEAS..........,.,
1 1 2 3 4
vJ 3
Chlorophyll a (mg/m )
I '>INK I I:8 I 5 MEANS ~ TAANSFOI)MATION CODE = 0 EAItOIC MS 0~00000 I
I I 3 ~ 1510 3 ~ I57 70 4 '270 4 '540 SAMVLE MFAN VAR I ANCE COEf.F I C"IENT OF VAA I AI I ON
... I'4UMIICR, 1 4 1904 0 '?19 0 ~ 3333 it 101 cI6 4 102 06 it 103 86 2 3 5 ~ 'ifI72 0 '536 16 ~ 5359 it?01 86 it 202 Ilb 4203 06
,3 3 13a9330 0 '332 2 6193 4,10 I tl6 llew it 302 86 430 3 86 II 3 1?. ~ 3724 I ~ 9 1 73 I 1 ~ 1916 401 86 it 0? tI6 403 86 Ig 3 10 ~ 4914 1 ~ 53?2 7985 501 8t) 502 86
- i O.I I36 0 '117
~ TABLE OF MEANS ( SOHTEO) j
.hatt SAMPLE N MEAN NUMUEA 0 ~ 4 '904 2s 0 ~ 5 '072 5 0 ~ 10~4914 4 ~ 0 ~ 12 '724 3 ~ 0 ~ 13' 9330 I
NAXIMU<<NONSIGNIFICANT f<ANGLS
/ j SUHSF. T SAMIiLF IMUMAEAS 1 5 ~,. 3 I 2
D-45 C hlorophyll a (mg/m )
IQ, SNK Tt. S T 5 PF ANS ~ THANSFORPAT 10hc COOF = 0 EnnOR V,S 0 F 00000 3 ~ 1510 3 ~ 87 70 4 '270 4~6540 Q SAMPLC N PEAN VARIANCE COEFF1C lENT OF VARI AT10N
. NUht HER 1 3 4.4232 0 '284 16 ~ 4342 4111 86 4112 li6 4113 86
.3 3~ 9576 0 ~ 5? 84 18 ~ 3676 Q 4?11 86
....4212 e5 4213 86 O~
14 '728 0 ~ 16.)9 2 '143 4J11 86 4312 86 431 'S c!6 I
Qi 3 P't: l IA4 -"t70: 4924 'Rs: t~fAg I
t}b 1:1 46 5 3 9 '1564 0 ~ 1341 4 '046 Q[ 4511 86 l ......4512 86 45c 1 3 06 C} 1 1;~ ~ 9499 TABLE Ot- PEANS lSnttTEn)
SAt4PLE ' t4E AN
~
NUhtBER 2 ~ 0 ~ 3 '576 lo'.... 0 ~ 4 '232 5 ~ 0 ~ F 1564 3 ~
~ 14 '728
.4 ~ .., 0 ~ ?5 ~ 1 104 PAXlhtUM NONS?GNlFI CANT RANGES Q SUUSE1'AMPLE NUt40ERS
..... l..........,'.. 2, ....... 4 Qi,
D-46 Ctllorophyll a (Illg/m3 )
i 0 SNK IC,S T I': R I I OA 9 5
!) IrEANS TAANSFORYAT ION CODE 0 F 00000 3 ~ 1!110 3 ~ 87 i0 4 8270 4,6540
",iAMPLI. N SPAN >
VARI ANCE CORI'F I C f CNT OI V ARf Ar I IW NUH'BEII I 3 2 '100 I ~ 1.38 I 36 '606 4 I .I I 0(i 4 I.I2 ilfi fI I f:I IIA 5 '708 I ~ 2601 20@5184 4231 86 4232 Ub 423J 86 3 3 ....'12 ~ 8308 0+4937 5 '763 4.331 Ile 433) Ue 4333 Ue 4 3 13a0636 3 '747 14 '623
.4431 86.
44 32 86 4433 86 3 10 ~ 5120 2 '459 13 '068 4531 86
'e.
,4532 6.......
4533 66 I ~ 6625 TAfILE QF hIEANS (SORTED) i[ SAh'PLL N hlFAN NUhIBER...,...,...
I~ 0~ 2 '100 2 ' ... 0~
'708 5~ 0~ 10 '120 3~ 0 ~ 12 '308
- 4. . 0. . 13.0636 FAX I IOUS NONS I GNIF I CANI'ANGES SAhlPLE NUl40ER S
.;I..., ...,,....2.....,.,
SUHSF. T 1 2 4,
D-47 3
Chlorophyll a (mg/m )
SNh. tLST 4 PEANS, TRANSFORMATION CODE = 0
......,. ERROR MS =, . 0 ~ 00000 3 ~ 1510 3 ~ 8770 4 ~ 3270 4 a6540 Q SAMPLE N PEAN VAR I ANCF COEFF I C lENT OF VAR I AT I ON NUMUEA 1 '3 3 ~ 0264 I ~ 7478 43 '839 4151 d6 4152 86 4 153 86 3 7 '808 2 ~ 4875 22 '738 u6 4 2'i? t56 4? 53 86 3 '3 12a3858 0 '038 0 '990 4451 ti6 Q 4452 t)b 4453 86 I
G' I 8~ 8268 1.8899 1'745 4551. 86 4552 Ut) 4553 t<6 1 ~ 5322 I
Q I TAfILF. OF MEANS (SOATEO)
SAMPLE . N MF. AN NUMUFA I ~ 0~ 3i0?64 0~ 7.0808 4 ~. 0~ 8 '268 J ~ 0~ 12 '868 g PAX IMUP NON I GNIF I CANT RANGES
...SUDSE f SAMPLE .NUMUEAS 1 2 3 Q,
D-48 Chlorophyll a (mg/m 3 )
'hIK TL S T 5 MEANS ~ TRANSFORHAT l ON CODE 0 EHAQI1 HS 0 F 00000 3 ~ 1510 J ~ 8770 .4 '270 4 '540 SAMr LE HEAN VAR l ANCE COEFF I C IENT OF VAR I AT ION
. t4Uh)QEH 2 0 '492 0 ~ 2439 ~ 14 1 ~ 4213 2102 'J6
.2103 9ri O>> I I.. 3 5~ 1596 0~0831 5 '862 230l 96 6 P?0? 96 22rIS 9b 019}nO u: lhi9 id:Hhfk 2301 96 I 2302 96 ~ ~
2303 96 4 3 4 '860 0 '325 10 '948 2401 96
.... 2402 96 2403 96 I
5 2501 96 3, 1 +5132 0 '406 13e3235 Gj 2502 96
...2503,96 0 ~ 1 426 8
7AQLE OF MEANS ( SOA TED')
SA HALE N MEAN G', ,NUMBER I
1 ~ 0 ~
~
0 '492 So 0 ~ 1 ~ 5132 3 ~ ~ 2~ 9140 4 ~ 0~ 4 ~ 3860 2 ~ 0~ 5 '596 NAX I MUhr NONS I GN IF. I CANT RANGES, SUBSF.T .'AMPLE NUMBERS 1 1 2
~ ~
D-49 Chlorophyll 3 a (mg/m )
SNK TLST 5 CLEANS, TRANSFORYAT ION CODE = 0 L HllDR MS =...... 0 ~ 00000 3~ 1 51 0 3 ~ 0770 4 ~ 3270 4 ~ 6540 SAMPLE N MEAN VARIANCE COEFFICIENT OF VARIATION
......NUMOER 1 2 1 2222 '
'487 60 ~ 6092
..2112 96 2113 96,
~ * - ~ N 2 3 ... 5 ~ 7230.. 0 '7808 15 '395 P.21 l 96 2212 96
........2213 96 3 3 2 ~ 4494 0 '230 in'178
..231 1, 96 2312 9f) 2 313 96 4 3 2 '956 0 '700 21 '590 2411 96
'.......24 12 96 24 13 9fv
'5 3 2 '962 0rn099 3'3 ~ 3890 P'iJ I ')f>
0 "i I d <l0 2513 96 0 ~ 4529
... TAULE OF MEANS I SORTEU )
SAMPLE N PFAN NUHOER 1 ~ 0~ I ~ 2222 5e 0~ 2 '962 3 ~ , 0~ 2.4494 4 ~ 0~ 2 '956 2 ~
' ~ 5 '230 MAXIMUM NONSIGNIF1CANT RANGES SUBSET SAMPLE NUHAERS 1 1 2
Q>>$ Q 3
Chlorophyll a (mg/m )
3 SNK TLSI' MEANS o TPAKSFOAMAT lON COOt = 0 I
I'I(HOlh MS =
3 ~ 1510 3 ~ 0770
.....4 ~ 3270 0 ~ 00000 4 ~ 6540 Q~ SAMeLC N ~tAN VAnlnNCE CotPF 1 C leNT OF VAn 1 ATION i ......,NLIMCICA 1 1 1 ~ 396H 0 F 0000 1 5 ~ 7459 2132 'J6 2 3 3~ 9966 I ~ 0265 25 '503'
. ... 2231 96 2232 96 8233 96 3 2 '982 0 ~ 1219 16 '428 2331 76
..2332 96 2 3.I.I 96 3 1>> 9?88 0 ~ 2845 26>>9563 2431 90 24 3? 96
...,2433 96 3 1 ~ 7460 0 F 0000 0 ~ 0000 2.5 J 1 'r6 2'132 96 25 13 96 0 '582 TAHLC OF MCAHS l SOATED)
SAMPLE N ~ MEAN NUMIICIC 1>> 0~ 1 ~ 3968 5~ 0~ 1 ~ 7460 4 ~ 0~ fllfdA 0; 2:0992 H: j:988h 8 MAX lMVM NUVS1GRTF 1 CANT AAHGCS
. SUL St T SAMPLE NUMBEI)S 1 1 2
3 Chlorophyll a (mg/g )
INK fL'5 T 4 h'f'.ANS 10hhSPOQPA T EON CODÃ 0
),!.IIII!I ll.]P'III'<.((1$ n.oooo'I,I,yI p>>Qpt LI! II >>PAL vaA fnlJck cHliI'I:I H I HN H! v'ARID I HII
. r~t)t~bLli 1 3 ~ 5910 0 '033 23+0133 2151 96 215? 96 215J ')6' 2 3 ~ 3 ~ 6700 0 ~,04 38 5 '007
?251 96
....... 2252 96 225:3 3 ~
0 '168' 0 '319 09 ~ 2903
? 351 96'~.
2 IS/ 96
........235~ <)e g 4 1 ~ 2804 0 ~ 04 06 15 '459 I.... 2551 96 2g 5?,96 2553 ') 6 0 ~ 3249 O Tn>>l r: nv >>.p~>>q lqnn<gpi i hAMt<LF=
I lul~l > I=- I<
3 ~ 0~ 0 '168 4 ~ 0~ ,1 ~ 2804 1>> 0~ 3 '910 2 0 0~ 3 '700 MAXI MUM NONS 1 GN EF E CANT HANGt';S SUOSF T, ... SAMPLF. NVNOFAS .,
1 3 2 C
D-52 Chlorophyll n (ms/m 3 )
SNK l l-'. ST 5 MEANS TfeAHSf-ORNA T I ON CODE 0 0 E l le oil M s 1 O.aaaaa 3 ~ ) -i ) I) 1 ~ llr Va 4, 4P ra 4 ~ 0 )4a ~
0'I fenfllet l fl fftf Aft VAlf thfff:f' ftt)t't'll'ttfNf fit'fhtflhl tflff Hfffftff:.ff I 3 9 F 0052 0F 1626 0 '860 lal c 4 102 96 4 l03 5 ~ 1216 1 ~ 1381 20 '299 4201 ~
)6 4 20c! 'J6 4203 9f) 3 S l.r460 0 '219 20 '000 4301 >6 G ~ 4302 ')6 4303 ')6 3 5~ 4100 1 ~ 1 862 20 '319 4401900 4402 96 4403 ')6 I 3 ~ 1430 0~ 1230 Il ~ 1553 Ol 4501 ~)o l...... 450? 96 4503 9f>
0 0 '464 N
I AULE Ol. M('ANS ( SOR TLI) )
0 SAMPI l.'. N MEAN NUMi>E R 3 ~ 0~ 1 ~ 7460 5 ~ 0~ . 3o 1438 1 o 0~ 5 '052 2 ~ 0~ 5 ~ 121,6 4 ~ 0 ~, 5 ~ 4100 I
MAX 1 MUM NONSIGNIF !CANT RANGES Q SUOSET SAMPLE NUHOERS L.....
oi 0
D-53 Chlorophyll a (mg/fff )
'I SNK Tfl S f' Pf;ANS TAAhSFOAMATION CDOE = 0 E I'.Ikf))k MS 0~00000 I
3 '510 3 '770. 4 '270 4 '540 (jl; SAMr LE N PEAN VAe I ANCE COEFFICIENT OF VARI ATIOht I NUMf3EA 1 3 6 '52H 3 ~ 21 ll 29 '054 4 111 96 4112 96 4113 96 Q
?,5 42ll 96 5 ~ 8014 1 ~ 6644 ?2 '381 12 96 I
4213 96 3 .. 1 ~ 3,968. , 0 ~ 8536 66 ~ 1438 4311 4.1 12 96 4:51 5 )6 4:5 aJ fj 7 ~ 7400 2 '672 22 '553
'lff I 4
- iB l
5 3 3 ~ 2602 0 '633 12 '946 .
451 I 96 4512 .96.'....
13 96 1 '719 T AHLE OF MEANS ( SOfkTEf) )
Q SAMfiLE N PEAN NUMQEf1 ~ ~ ~ ~
3a 0 ~ 1 ~ 3968 5 ~ ... Oo 3 ~ 2602 2~ 0~ 5 '014 fo 0~ 6 ~ 0528 4 ~ 0~ .. 7 ~ 7400 MAX I MUM NDN S 1 GN 1F I CANT RANGE'S 0 SUOSET SAMPLE NUMflLAS
....1 ., ..3....... .. 4
~ 'I Q
t3
D-54 Chlorophyll a (mg/m 3 )
SNK TEST 5 NEANS < TlfANSFORMAT lON COOE =, 0
,, CRIICII MS 0 ~ 00000
- 3. 15 10 3.117ro 4 . 3270 4.65no SAMPLE N YfAN VAR I ANCE 'COEFF I C IENT OF VAR I AT l ON
. NUMULB
'I 1 4 ~ 5060 0+5204 16.0784 4 1 )I ')6 4132 96 n1~3 'v6 2 ,5 3 ~ ~)576 1 ~ 74 70 33 ~ 4053 4231 ')6 4 238 'J6 I
423 l 96 Q>> ~
I 4
3 Ill 96 3 0 ~ 1 164 0 '406 173 '049 4 I I<')6
<<3 I.S ')6 4<<81 3 0 ~ 4 302 0 '800 0 ~ 2861 96 44 3c')6 4<<3'I 96 3 2 608 0 '845 20 '299 n.31 96
<<532
<<533 96 0 6179
~
I TABLE OF MI=ANS fSORTED)
Q' SAMPLE III EA N NUMI)EI1 3 ~ Oo 0 ~ 1 164 5~ 0~ ~ 5608 2~ 0~ 3 '576 I ~ Oo ne3068 4 ~ 0 ~ 8 '302 1
NAX IMUM NUNS 1GNIF ICANT RANGES Q l SUASET SAMPLE NUMBERS I
....: 3 0
I
D 65 Chlorophyll a (mg/m 3 )
SNI( Ir ST 5 ~VANS, Tffhf Sf uRhfhTION COO@ ~ O I> I( f(III( )I 4 0. 0n00n Z, I~ I O .I . n 7 7n ,4 i:fa )O n . ~(I(f ff j)( QhMIII I ff Mphil Vhfl I hHCÃ f'IIKfI" I C l fff>ff Of( V hff I h I I IIH IIIIHIII!II I I Ii I /I f)II Ue lfiFIII I Va dII!10
>I I!s I 'Jf>
4 I 5> )6
'>) (>
? 3 ? ~ 3200 0 ~ 0,4 06 0 ~ 6603 4?5 1 96 4253 96 3 0~ 1164.......... 0 ~ 0406 173 ~ 2049 4 3.'i 1 96 4 352 96 435J 96, ~ ~ t 4 7 ~ 8142 0 ~ 5927 9 ~ 8526
.,445] 9(>
4452 96 5 3 ?e2>>6 0 '284 32 '684 4551 96
....,,. 4 552 96................
4!i5 J 96 0 ~ 3137 T ABLE OI- HE AN S (SORTED)
SAPf>LE N h>EAN NUh1liEIP, 3 0 o. o. >>64 2116 J s P, ~
I ~
0~
0 0~
~,2 . 2 ~
~
F 1428 3280 4a ,Oi....,7 '142 b ax v Uw 1 NON S 1 GN IF 1 caN T RANGES 9 SUUSET SAIAPLE NLIMI3ERS L. ..'1 ,......3 .....,,. 4....,....,.. ~
D-56 Chlorophyll a (ms/m 3 )
C9 SNK ME ANS ~ TRANSFORMATION CODE = 0 r LRHOEC HS 0 00000
~
.I ~ ae<n 4 ~ 0410 4 ~ 5290 0 sAMPLL' MEAN VAR I ANCE COEFF I C IENT OF VAR I AT ION I...,.... NUMOFM 1 13m 8250 2+9337 12 ~ 3092 110 I. D7 14 ~ 3544 1 102 57. 15 ~ 2106 1103 57 II+9100 2.4444 0 '658 ?4 ~7436 1201 57 3~ 1420 IP02 57 2~ 0952 1203 57 2 '952 3 '
5 '296 0 ~ 3616 I 1 ~ 0744 1 30 I 57 5 '364 I 302 57 4 7C52 1303 57 5 '872 3 6 ~ 0860 0 '506 16 '178 I... .... 1401 .57 .. 7 ~ 2 I 26..
1402 57 5 ~ '5224 Q 1 4 03 57, 5 ~ 5254 I + 1529 6; TAOLC Ot: ME.. AN'b ( SORTEO)
I.... SAMPLE,... N MEAN NUNBEII 2 ~ ~
. 0~ 2 ~ 444,4 3 0 0~ 5 '296 4 ~ 0~ 6 '86EI 1 ~ .0 ~ .13 '250 k
NAX I MUM NONS I GNIF I CANT RANGES SUBSE T . SAMPLE NUMOERS 1 3
e I
D-'5V Chlor'ophyll 3 a (mg/m )
~NK I Lb I 4 h)r ANS ~ TRANSFORh)AT 1 ON CODE = 0 ERROIR MS'..........,0~ 00000.,
I 3 ~ 2610 4 ~ 0410 ~ 4 ~ 5290 Q! SAVVLf. N h)EAN VARIANCE COEFF IC tENT OF VARI ATlnN l...... NUMHE11 1 .3 1 7 ~ 2676 1+5746 7 '669 1111 57 18 '468 1112 57 . 16 '934 111"3 57 16 '626 6772 27ol521 Q '211
....,... 1212 b7 3
57...2 '444 2
3
~
'920 0 ~ 5284 1213 57 2 ~ 0952
- 3. 3, ... 8 ~ ?974 ~
.. 0 ~ 3220 6 '385 I 31 1 57 7 ~ 9698 Q,. 1 '312 '57 7 ~ 9698 1 31 J 57 0 ~ 9526
.3 7~ 6742. 0 ~ 1245 4 ~ 5971 1411 57.........7~ 9080...................
1412 57 '7 8462" 141 J )7 ~ 7 ~ 2604
, 0 ~ 637J Q TAF!LE OF 14EANS (SORTED)
. SAMPLE....,.... N
, NUIIOI R 2~{ 0~ 2 '772 4 ~ 0~ 7 '742 3 8+2974
~
1 ~
0~
0 ' .17 '676 cubi Phkl Mill~ floflbf(I)didfGAWf I)AHbf-h SU(! SL T NA4!ALE blU!t!BER S 1 J 1
Chlorophyll a (mg/~ 3 ) I 3
SNK L'f1fNOI'(
~ 2610 TES'f HS, 4 '4 4
10 MEANS'RANSFORMATION 0 e 00000 4 '290 CODE = 0 SAMPLE N MEAN VAR lANCE COEFFICIENT OF
~
VARlATlON'.......NUMUER.
I 3 4 '724 0 '284 15 ~ 2317 1131 97 4 ~ 1904 I 132 57 5 ~ 5872 I 133 57 4 '396 3 I ~9788 0 '845 26 '563 1231 a7 2 '444
....1232, 57 2 ~ 0952 ....
123.1 57 I a 3968 3 3 5. 8540 0 '065 I0 ~ 8917 1331 bl 6 '112 13 52 57 5 '300
...133 J 57 5~ 8128 4 3 4 ~ 7734 0 ~ 5267 15 '034 431 57 ......4o 5396 4 I2 57 5 ~ 5072 4'33 57 4 '934 O.4SGS,......
TAQLE OF MF ANS ( SORTEf> )
SA~PLC yPAq tPNIIP ff
? ~ 0 ~ i; V4o'U le 0~ 4 '724 4 ~ 0~ 4 '734 5 '540 I
NAX I HUM NQNS f GN lf 1.CAN T RANGES
'.....,SUB SE T ......:.... SAHPLE NUMOE8 5 ...
I 2 3
~ ~ k
D-59 3
Chlorophyll a (mg/m )
bivl<. I L5 C 4 MEANS, rnANGFORMArtoN conE = 0 ERROR MS 0 F 00000 j 3 '610 .4 '410 4 '290 Q! SAMr LE N MFAN VARIANCE COEf'F IC JENT OF VAR I AT.ION I.:...... NUM GER 1 3 . 2 ~ 095(' 1 '975 " 'LOS 0000 1 LSL 57 ~ 04 76 1 152 i7 2~ 0952 1L53 57 3~ 1420, 2 3 0 ~ 8148 0 '406 24 ~ 7435 I '51 57 0 ~ 6984 1252 57 .
1' 0476 1 253 57 0~ 6984 3 3. 6~ 0900. 0 '222 9~ 3192 3151 !17 6.576n 3 L 5'c'7 6+2298 3153 b7 5 '666 3 6 ~ 61 00 2+0641 25 '030
.......3251 57 8 ~ 1 984.,
3252 57 6 'OL6 3253 57 4 '300 ~
1 ~ Ol3L 1 Q TAOLE OF MEANS (SORTEO)
SAMPLL ... ,N NUh1OE R 2 ~ 0 ~ 0~8148 I
'1 ~ 0.. 200952 Q a 3 ~ 0 ~ 6 '908 4 ~ 0 ~ 6 '100 Q'AXI MUM NQNS I ON IF I CANT CHANGES SUUSET "
SAMPLE,NUMOELLS 1 2
Ill!l >> ~ Il~~lly ) l ll
.',Ijl. II'.: I :,'I:.A"lJ..; III k.",I=HPllA"I ) H4 A"
CHHL = 8.
I:.I;I:(Il( H S o.(iooob
.I l 3 ~ I )10 .3 ~ 87 70 4.3270 4.&sdo SAMPLE N NEAN VAllI ANCE COEFF IC tEHT OF VAHIATIOhl Nu)4QEA I .I 14 '?00 0 ~ 0443 I +4108 2101 57 2102 57
? 103 57 2 3 4 '912 0 ~ 2501 11+&546 2201 57 2202 57 2203 57 el I 3 4 '?5(3. 0 ~ 2791 , le 7242 2301 57
? .302 '.i 7
?.30 3 's 7 3 5.9126 0 ~ 2737 8 ~ 8405
?401 57 2402 5 7
?40:3 57 5 3 2 ~ 1724 O.0350 8 ~ 6063 2501 57
... 2502 57 2503 57 oe I 764 TABLE Of MEANS ( SOR IEI) I i I SAHPL F. N VI=.AN l ~ .. ~ p)UMI<EH 5 ~ Oo 2 ~ 1 724
?, ~ 0~ 4 ~ ?91?.
I 3~ 0~ 4 '258 4o 0~ 5 '126 I I ~ oq 14 '200 l,
l..... ... I...
PAX IMUH NQNSIGNIF ICANF RANGES sunsET SAND LE NUNf)ERS 2...
D-61 3
Chlorophyll el (Ittg/III )
9 SNY. Th I' r IereOIe MS = .
MEANS ~
0~
TRANSFOIeMAT I ON COOE =
00000 0
3 ~ 1510 .3 ~ 8770 4 ~ 3270 4 ~ 6540 8 SAMPLE N
...NuMB Ere MEAN VAR 1 ANCE COEF I= 1 C 1ENT OF VARI AT I ON I 3 I 9 ~ 6480 2 ~ 3'1 97 7o 751 7
? 1 I 1 57 2112 57 2113 57 2 Se 180?. 0 ~ 3679 II ~ 7093 221 l 2212 57 2213 57 3, . 3 '.: 0 ~ 4292 1 ~ 0231 1 1 ~ 9999 231 I 57 2'112 57 2 3 I 3 57 3 soon 0 ~ 4 069 1 4 ~ 1620
......,. 24 1 1 5,7
? 412 57 2413 57 5 3 F 1528 0 ~ 4459 31 ~ 0183 2511 57
. 2512 b7...,.
25 I 3 57 0 '127 TABLE OI= MCANS (SrIIeTEI) )
SAMPLL N MEAN NUDGE H...
5 ~ 0 ~ 2 ~ 1528 4 ~ 0~ oe5044
? ~ 0~ F 1002 3 ~ 0~ 8 '292
. 0 ~ '. 19 '480 I MUM NONS I GN IF SCANT IIANGES 1
I'AX SUHSET SAMPLE NUMQERS 1 4.
D-62 3
Chlorophyll a (mg/I )
SNv. rEsr 5 MEANs, rRANSFORMArloN cooE = 0 Cf<ROle M 5 0 F 00000 3~ 15 1'0 3 ~ 8770 4 ~ 3270 4 ~ 6540
'SAM)ALE
'.... WUMOER N MFAN VAR 1 ANCF. COEFF lClENT OF VAR lATlON 1 3 3 '632 0 ~ 1633 12 '832
'21 31 57 21 32 67 213J 57 2 3 l ~ 2602 0~ 1633. 1 2 ~ 3946 r23l 57 22.12 57" 2233 57 3 e7 ~ 22 74 , 0 ~ 7178 10 '980 233l ':>7 23.)c b 7 23J3 i7 g,l 3 5 ~ 0178 0 '040 9 '778 5
2432 57 2433 l7 5 3 7540 0 '209 6 '429
) '~31 57
)~
i ...,... 2532 57.
253 1 57 4 0 ~ 2939 TABLE CF MFANS ( SOB TEl) )
4I SAMPLE N: MEAN NUMI3E le 2 ~ 0~ 3 '602 1 ~ 0~ 3 '632 5 ~ 7540
=
5 ~ 0~
4 ~ 0~ 5 '178
.3 ~ 0 ' ..8 '274 MAX 1 MUM NONS 1 GN lF 1 CANT leANGES C
.....,1.....
SUOSE l 2...
SAMPLE NUMBFAS 3'...,."
D<<63 Chlorophyll 3 a (mg/ttt )
/ 9 SNK TES T ERAOA MS 5 MEA'4S TRANSFORMAT lON COOE =
0 F 00000 0
3 '510 3 ~ 0770 4 '270 4 '540 SAMPLE ' MEAN VAR1ANCE COEFF IClENT OF VAAlATlON I.....-....NUMOLR 1 3 l ~ 5132 0 '503 53 ~ 2938 2l5l 1 2152 57 2153 57
? 3 2 '902 0 ~ 12 19 l Pa 6420 225l 57 2252 b7 2253 57 3 3 6 ~ 1424 0 ~ 0862 4 '806 235 l 57 2357 57 3 5 AD !916 0.0747 18.0146 245l bl 2452 >7 2453 57 5 3 '4 ~ 7064 0 ~ 1219 7 ~ 4 197 2551 57 2552 5 7 2553 57 0 '710 TABLE OF MEANS (SOATEO)
SAMPLE ' MEAN
/NUMBER, le 0~ 1 ~ 5132 2 ~ 0 ~,, 2 '902 5 ~ 0~ 4 '064 4 ~ 0~ 5~ 1916 3 ~ ~,, ~ ~ ~ ~ ~, 0~ . ..6 ~ 1424 ..
MAX lMUM NONSlGNIF lCANT RANGES Q.t 'UttSET SAMPLE NUMOFRS
,1 ~ I 7 ~ ~ ~ ~ ~ ~ 2 ~ .- 3 2 1 2
D-64 3
Chloxophyll a (mS/m )
SNK, TEST 4 Mt.. ANS TRANSP OR MAT 1 ON COOt. = 0
,...,.... ~. I= A AOA M S. 0+00000 ....
3 ~ 2610 4 '410 4 '290 SAMPI I'. N MEAN VAALANCE COEFFlC lENT OF VAR f ATION i ~ ----..I4UM(1EA ~
') 9.8776 O S )230 3 '505 3)01 '.i7 10+2280 3108 57. 9 '766 3 103 57 .9'~ 5274 I, 3 12 ~ 0944 0. 7546 7 '824
- )PO ) .'p 7 ) 3 i'0596 320'". 5 7 1 1 ~ 3754 3203 57 1 1 ~ 8482 3 3,, 11.8472 2~ 1 740 12 '457 3JOI, 57 1 1 4990 3302 57 1 3a 4646 3 JOJ 57 . 10 ~ 5780
'3 7 0108 1 ~ 283) 1569 340 l 57 ,8 '688 llew J402 5 ~ 81 r)8 3403 ~>7 7~ 1478 1 ~ OBJ7 T AtlLE Ol" MEANS ( SOA TED )
SAMPLE .... N ... MEAN
'UMHEA 4 ' 0~ ., 7i0108 1 ~ Oo 9a t) 77f) 3~ 0~ 8472 2 Ia ~ ~ ~ ~ 0~ ~ i ,12 '944 1
f, NAX 1 MUM NONSI GN1F 1CANT RANGES Ut) SE SAMPl E .NUMBERS 2
3 Chlorophyll a (mg/m )
SNK Tes T 4 MEANS, TAANSFORMATlON COOE = 0 EHIJOR M5 0F 00000 3.26lO n. o41o 4 '290 SAPPLE PEAN VAA1ANCE COEFF IC fENT OF VAR 1 AT lON NUHaJEA l .5 1 9~ 0016 2io1537 24 ~ 1034 3111 sr 24 ~ 1416 3 l 2 57 1 15 ~ 154S 3113'7 1 7~ 9484 Il a A7ATI jI5 I I I f I 1 e ail 30
, I P~IIH.kb
.421 3 57 I7 s 9826 3 '3 8 ~ 1356 0 ~ 1219 4 '923
.3311 sr 0 ~ 1 336 3.l 1 2 '.> 1 7 ~ 7874 l.'3 l 3 57 .8 '858 3 6 ~ 2814 0~5106 1 1 ~ 3764
.,3411 57 . 5 ~ 4666 5412 Sr 6.8016
'341 3'57 6 '760 6 ~ 294 8..
Q TAoLE ol-'EANs lsaATEo) j SAMPLE N MEAN NUM15E R 0 ~ 6, ~ 2814 3 ~ 0 ~ , 8+1356 2 ~ 0~ 16 '700 lo 0~ 19 '816' PAX lPUM NOhlS1 GNIFTCANT RANGES SU(3SET , SAMPLE NUMOERS .
1 4 3 O 2 2 1 6
3o2610 b
Chlorophy3.1 a (IIIS/III3 )
SI4K p.......... EAAOA SAMPLE ILS f MS N
4 ~
4 0410 HCANS MEAN e
~
4 ~
TRANSFORMATlON COOK ~
.=....,........0 00000 .....
5290 VAR IANCF.
0 COEFF I C IENT OF VAA I ATION NUMAE ll 1 3 8 ~ 7804 0 ~ 3531 6 ~ 767'5
,, 3131 57 9a 3078 3132 57 8 '968 3133 57 8 ~ 1366 2 9 '590 Ia8660 13 '555 3231 oi8796
...3232 57 ..11 '146 3233 57 8 '028 3 3 . 13s6704 4 ~ 1454 14 3.'1 3 1 i7 1 3 ~ 8 1 98 57 15.eaVe 3i3
'936'431 I 'zV . 1 I ~ 5638 3 9 '368 1 ~ 1388 II ~ 5533 57.. 8 ~ 0710 I
3432 ~7. 1 n. 1C Vo 34 33 57 9~ 4716
-1 ~ 0758 TABLE OF MEANS (SORTED)
.SAMPLE . .., ,N NUMlII-:A 1 ~ 0~ 8 ~ 7804
- n. 0~ 9 '368 2 ~ Ow 9 '590 3 ~ 0~ .13 '704 NAX iMUM N(INSI GNIF 1CANT RANGES
. .SUUSET SAMPLE, HUMOERS I 1 3
~
I I
9-67 3
a (mg/m ) 'hlorophyll SNV. Tt' 7 5 MF ANS ~ TAAh SF Off MAT I f3N CODE = 0 EfffkUA MS 0 ~ 00000 4 o 3270 4 ~ 6540 I
3 ~ 151 0 J oH7 70 I
SAMPLF N PEAN VARIANCE 'OFFF ICIENY QF VAR 1 AT 1 ON t . NUMflEA 1
4101
.:357 16 ~ 0120 8 '944 1 8 ~73f) 1 4102 57 410.3'7 2 3 3l ~ 8140 0 ~ 5384 9. I eaa 4?01 ~v7 4202 57 4203 57 3 3 I 0 ~ 5070 0~ 7690 8 '507 4301'7
'.'30? 4 503 5 7
'.i 7
'I 4 3 7 ~ 3970 0 '292 1 I ~ 5442 4401. 57 4402 57 4405 57 L
I i 3 2 ~ 9100 0 '406 F 9&82 8, ,4501 57 4502 57 I
4503 57 3 8145
~
.l TA8LE Ot MEANS lSORTED) e( SAMPLE PEAN tVUMUF. R 5 ~ 0~ 2 '100
.4 ~ 0~ 7 '970 3 ~ 0~ 10 '070 1 ~ 0~ 16m 0120 2 ~ .0 ~ , . 3l + f3140 I
MAX I MUM NONS I GN IF I CANT RANGES .
Q SUft SE T SAMPLE NUMBERS
...,,,1 .....,...'5.... 3....
2 V 1 Q 3 1 2
9-68 Chlorophyll a (mg/I3 )
0 SNK TL'Sl 5 MCAN ~ TRANSFORMAT I ON CODF = 0 ERROR MS = . 0 F 00000 3i 1510 3 ~ 8'770 4 ~ 3270 4 ~ 6540 E
.SAIIPLF N PEAN VARIANCE COEFF I C lENT OF VAR I AT l ON NUMf3ER '
3 18 ~ 0764 2 '929 8 ~ 7346 4111 b7 n112 57 4113 b7 2 27 4658 I ~ I 324 3 '745 4211 's7 212 57 4213 57
.3 3 ....6 ~ 6430 .... 33 ~ 6691 87 '477 4311 b7 4312 57 4313 57 pi 4 3 8 '548 0 '656, 9 '265
.4411 57 4412 57 57'413 5 3 2 '616 0 '791 15 '991 4511 57 512 a~7 .~ I 4513 57 7 '278 TABLE OF MEANS ( SOR TEA )
SAMPLF " '
MEAN I'IUMUEH .....
5~ 0~ 2 ~ 661 6
.3 ~ .0 ~ . 6 '430 4~ 0~ 8 '548 I~ Oi 18 '764 2 ~ ~ ~ Oo .27 '658 2
1',,
MAX I MUM NONS SUBSET'AMPLE I.GNIF ICANT RANGES 5......1 NUMBERS 2
Chlorophyll 3 a (mg/m )
St'IK TEST 5 MEANS ~ TAANSFORNAT I ON CODE = 0 F RAOR hlS n.noooo 3 '510 J ~ 8770 4 '270 4 '540 SAMPI I-. N MEAN VAR I ANCF. COEFF I C IENT OF VAR I AT ION NUMHER 1 3 1 3 ~ 7034 13 1548 26 '676 4131 '57 4 1:$ 2 b7 0 4133 67 ~
2 .S 1~i. 31 On la3955 7%7156 42 sl !i7 4;a;. 57 I $ 2)3 6 f I 3 l d S 51308 14 "fSt'52 991V0ISV 4 '3.> 1 43 3'r'7 433.S 57 Qi 4 3 9 '584 0 ~ 6243 8 ~ 5342
- l. ..4431 57 443i? 57 4433 57 5 .1 3 ~ F756 0 ~ 4622 20 '552 0 4bl1 57 i , . 4532 57 4533 57 0 be0844 TABLE OF ML'ANS ( SORTEI> )
Q SAMS'LE MEAN NUDGER 5 ~ =
0~ 3 '756 4 ~ 0~ 9r2584 3 ~ 0~ 12 '588 1 ~ 0~ 13 '034 2 ~ 0~ .,15 ~ 3104 I'AXIMUM NONSIGNIFlCANT RANGES Q SUPSET SAMPLE NU>RERS 1 5 . 2.
Q
9-70 Chlorop'It'll a (mg/m )
.'iNK TEST 5 MEANS o TRANSFOAt>AT 1 ON CODE>> 0 ERIC@ MS = . 0 F 00000 3 '5SAMPLE 10 3 '770 N ,
4 '270 MEAN 4 '540 VARlANCE COFFI'lCfENT OF VAR lATlON NUhtHV.A 1 3 4 '650 Oo,5927 15 '252 4151 5 4 152 57 R 153, 57 i') t)y I 1 > 4 l9P. 'i ~ 011,95 I VeVÃl l 4252 b?
4253 57
.... 3 ' . 7 ~ 2374 39 '998 . 86~8390 4 )51 57 4 '152 57 43b 3 5?
8.7516 , 0 ~ 9066 '1 0e8796
..'4 4'5 1 57 4452 57 4453 b7 s-, 3 '864 1 ~ 2566 28 ~ 1203
(
4551 '57 I...;...... 4552 57..... '.
45b3, b7 9 ~ 4690
'AULE OF MEANS (SORTED)
SAMPLE . N MF.AN NUM8ER 5 ~ 0~ 3 '864 1 ~,...,...... .0. 4 '650 3 ~ 0~ 7 ~ 237.4 4' 0~ 8 ~ 7516 2 ~ ~;
~ v ~ ~ ~ 0 ~ ... .1 1 ~ 4392...
'I 'I NAX'1 t>HUH NDNS1GNlF 1CANT RANGES SUOSFT SAMPLE NUMBERS c............l ...,.....5 ...... 2
Chlorophyll a (mg/m )
SNK TLST 4 MEANS e TRANSFOAHAT ION COOE 0 El(AQII MS Os00000 3+2610 4.0410 4.S290 QN SAMPLE N MEAN VAR IANCF COFFF ICIENT OF VARI AT ION I NUHUEH 1 3 1 ~ F326 0 ~ I 62.6 24 '981 1101197 I ~ 3998 I 1021'77 2 '982 I 1031') 7 I ~ 39') 8 2 2 '902 Oo2337 16 1669 1201197 .f~ 1488 I '0 '197 . nn?n 120 1197 3a3744 3 3 I ~ 0644 2 '0?0 86p6026 I f01 li? 2o79b6, 1 10? 197 2a 7')66 I .10 J 1 ') 7 0 t OOOO Q. 3 7+ 9976 0~ I 7?6 5+2696 1401107 7 '226 1402197 8 ~ 4820 Q 1403197 7 ~ 7874 O S ?958 I
Q; TAIILE OF MEANS SAMPLE NUYhE'lI
( SOB TEO)
N l4EAN I~ 0~ I ~ 6326 3o 0~ 1 ~ 8644 o~ 2 ~ 0~ 2 '902 t .. 4 ~ 0~ 7 ~ 9976 0 PAXIMuh NOWSlt NIF ICANT naN<;ES SVl>SET SAMPLE NUMHEAS, I 1 2 Q
Q
D"'72 Chloz'ophyll a (mgAI )MEANS' I (
~ ~ i'gl ~ y'7 SNK feST 4 .TRANSFORMAT1ON CODE EAICUR .MS =........, ...:, 0 ~ 00000 3 '610 4 '410 4 '290 SAlvfiLe N PFAN VAR 1ANCE COEFF1C lENT OF VAR 1AT1QN
.- ...-. NUMHf'.ll I 3 1 ~ 1660 0 ~ 04?1 1 7~ 5II79 1 I 1 1 1 )7. 1 ~ 40271 I 1 121')7 ' ~ 0476 1113197 1 +0476
- c. 3 2 ~ 7760 0.1OOe 11 '253 I? I I I 97 3 ~ 0040 1 ~ 12197 2 ~ 79.$ A
'll c]7 llew 18 l P~ 490~t 3 3 1 '910 1 ~ 4654 se F 6006 131 1197 2 '952 131 ?.1')7 ?a 0902 131 31') 7 0~ 0000 4 3 8 '436 0 ~ 9093 2932
.... i 4 1 1 I 97 ........ 7 ~ 5000......,...
l 4 I ?197 8 ~ 4240 141 3197 9 '068 0 ~ 6293 l A@LE OF ME AN S ( SOA.TED )
L,............. SAMPLE......... N .... MEAN NUMOEH 1 ~ ~ 0~ 1'o 1660 3 ~ O. 1 ..i9re 2 ~ 0 ~ 2 '760
.4 Oa.... 8 ~ 4436 NAX I MUM NUNS I'GN 1F 1CAN 7 RANGES
. ....,SUUSET , .SAMPLE HUMOERS I 1 2 0
D-73 3
Chlorophyll a (mg/m ) /
C) ShlK 1 & ST 4 MEANS t TRANSFORQAT I ON CODE = 0 El<I)OR HS 0000000
. I 3.2610 n.onlo n.5290 .
0' SAMPLE "
hl MEAN VAR I ANCE . COEFF IC IENT. OF VAR1AT ION
'i,,........NUMOER I 3 I~ 0486 0~ 0000 0 '652 1131197 I~ 0476 I
I 132197 I ~ 0476.
113;3197 ' ~ 0506 I
2 3 ' 7956 7936 0.12no 12 '985
~ I F31 197 '
~
1232197 2 '444 I 1233197 3. 1488 0:
I 2 '976 0 ~ 1230 12 '358 1331197 3 '488 (3 '332197 2 '96h I .13 3197 ,2. 4n74 7+3744 4 '000 29 '094 9.n098 ln 32197 5 '556 1433197 7i6578 I ~ 2IilU I
9 I I
TABLl=. OF MEANS (SORTEO)
SAMPLE NUMuER I ~ n. I ~ Ont)f)
Pe Oe de7956 3e Os ~ 2 ~ 7086 4 ~ Oe 7 ~ 3744 6, . NAX IHUM NONSIGNIFICANT RANGES I ..SUH SET , SAMPLE . NUMBERS I I 3
'0 Q
3 Chlorophyll a (mg/m )
Sample Number Mean Variance Coefficient of Variation 1.7490 0.1240 20. 14 1151197 1.7490 1152197 1.3968 1153197 2.1012 2.6782 0.1640 15.12 1251197 3.1458 1252197 2.4444 1253197 2.4444 3.1458 0.1219 3.88 1351197 3.1458 1352197 3.4950 1353197 2.7966
D VS 3
Chlorophyll a (mg/m )
I. AllOR Ilr. I I S I '.5 MLAtl" .I'llhNQPOHMATI ON COOP.
lpga w, 0 MS II ~ 00001)
II3
'I ri>t 'i '.'ll i
[i[APi'v'ilAfR)YI I lii
)I I i if fig vllfilAIliii'i NUh!Ol';A I 3 2 '310 0~2824 ?2 '993
~ 2101 lif7 2102197 2103197 2 3
~ ), I 4
~
~
8664
~ ~ ~
0 ~ 04 13 10 '949
?. 2 0 I I 'P 7 2202 1'J 7 2203197
,.3.. 3 .3 ~ 5712 0 '175 13 ~ 0581 2301197 2:S02197 2 30.'I I v 7 4 3 '4 ~ 5540 1 ~ 7931 29 '038 2401197 24021'J7 240SI97 5 3 4 ~ 9794 0 '345 3 '304 25021,97 2501197'....:.
2503197 0 '730 V~
TABLE OF MEANS'(SORTED)
SAMPLE N MEAN NUMBER .....
2~ 0~ 1 ~ 8664
, I~ 0~ 2 '3IO 3~ 0~ 3 '71?.
- n. 4 ~ 554 0 5 ~ .....0 0~
~ '." 4 ~ 9794.
FAX LMUh> H(JNS1 GNlF I CANT RANGES SUI.SI-: T 1 ...2., SAMPLE NUh'GLAS 5
Chloro'phyll a (mg/m )
3 SIIlc.'E S T EI)r<CiI
310 05 3'8770
= .,5 MFAHS 4'270 Or
'e TAAHSFORMAT lON COOE =
00000 4 ~ 6540 VAR l ANCE 0
I SAM)>).E N HI."AN COEFF 1C lENT OF VAR 1 AT lON
. HUMU):))
1 3 l o'6".I i6 is9966 8'6 '025 alii I )7 21 ) 21') 7 211 3197 r1 3 2 o 07'5'>> Oal231 lbo9034 2 c' ) I )7 22 I cc? I iJ 7 22i )1~)7 3
2311197 i ..~'590 0 '001 1'i ~ 7551 i~ 3 I 2 I 'I 7 23'i 31)7 2'a .) $ II II 0' P)6$
l)l rc'); i'5 l 2)I I 3197 13 2'5 1 1'I 9 7 3 '461 50 0 '550 10 '564 2'5 1r2 1 9 25'I 31 ')'7 0 ~ 'i004 7'A8LE OF MFANS (SORTEO)
SA'MI LrE N ItcEAN NUMUE 8 0 "o 1 ~ '63 1'6 2 ~ 0~ 2.07Se 4 ~ 0 ~ 2 '300 3~ 0 ~ 3 '590 5~ .0 ~ 4 '158
. ))AX 1 HUM 'AONS'1 GN IF I C'ANT RA'NGES SUBSI'. T
.1....
SAMTILE 6lUMBERS 5...
D-77 3
Chlorophyll a (mg/m )
SNK lb S f' MLANS o TRANSFORMAT lUN COOE = 0 ERROR MS = .. 0 ~ 00000 3 '.iln 3 '770 4
'270 4 '540 SAMPLE N MEAN, VARlANCE COEFFlOIENT OF VARlAT1ON
" iNUQHFR ~ ~ ~ ~ ~ ~ ~ ~ -- ~ - ~ ~ ~ -- - ~
I . 3 8 ~ 4474 0 '219 14~2682
, 21 J1197 2132197 21 J3197 P 3 2 '268 0~ 1 036 13 '600 2 c.' 1 1 97 2232 197 22331 97 3 3 3 '068 0+4787. 23 ~ 0104 2331 1 97 2332197 2333197 3 3 ~ 59'OU 1 ~ 1022 30 ~ 2790 2431197.
243;197 24 J 1197 5 3 3 '072 '0 '358 5 '026 2'.i3 197 1 I......... 25 J2197 2'i Jl <)7 S
D 0 '044 TABLE OF MEANS (SOBTFf))
SAMPLE N YFAN NUh1QER 2 ~ 0~ 2 ~ 426(
1 ~ 0~ 2 ~ 4474 3 ~ 0~ 3 '060
- n. n. 3 '908 5 ~ 0~ 3 '072 MAX 1MUM NONS1GN1F 1CANT RANGES SUI'I SF. T SAMPLE NUMUERS 1 . - . 2 ...... .5,.....
D-78 3
Chlorophyll a (mg/m )
SNK TEST 5 PLANS TRANSFORMAT lON CODE = 0 CHAQll M S 0 F 00000'
'510 3 ~ H7'70 4 '270 4 '540 N MLAN VAR1ANCE 'AMPLE COEFF1CIENT OF VAR1AT ION
.NUMUl'.H 1 I ?e 1310 0 '866 24 '678
?,1311 J7 2152197 215 3l 97 3 . ? ~ 3310 Oe 0406 8 '491 225 l 97 1 2252197 225 31 97 3 3 ..2 ~ 7760 0 ~ 1016 1 1 ~4841
?.351 197
? 352197 2353197 4 .3 6 ~ 1 980 3 '946 20 '8?4 2451i9r
?452197 2453197 5 3 '236 0~ 1460 9 ~ 9944
? 5 5 1 l 9:7 2 552 1 9 7 8"-'I i I 'I /
,n~'Vjjv TABLE OF MEANS (SOHTEO)
SAMPLE N MEAN NUMljF'8
? ~ '0 ~ 2+3310 1 ~ '0 ~ 2 '310 3 ~ 0. ~ 2 '7760 5~ 0~ 3 '?36
'4< ~ '0 ~ 6o 1980 NAX 1 MUM NONS 1 GN1F 1 CANT RA'NGES
' SUPSE1 'SAMPLE "NUMOERS
..1,. '
D-79 3 il Chlorophyll a (mg/m ) ~ ~ a 4 V SNK f'hSI MEANS s TRANSFORMATION CODE = 0 E A I c 0 IC M S 0 F 00000 3.2610 4 ~ 0410 4 '290
+ t SAMPLe. N )IE AN VAR I ANCF. COEFf-'IC IENT OF VAR I A r ION I,.... .NUMflER 1 3 ho 3752 0 '417 3 '043 110I,207 6 ~ 3876 1 1n2207 6 ~ 5730 1 103207 6 ~ 1650
'I 7 ~ l 4HO 0 '209 4 '6;18 I'.ni or o ~ P.n 1 ri 1 '0"'.1) r 7 ~ l 4 'r0 12032U t 7+4970 3 3 9 ~ <<)476 0.2498 5 '247 1301207 10 ~ 0434 I 30<'207 1 0~ 3926 1303207 9~ 4068 3 1 3~ 0276 0 ~ 24 95 3 '345
,.,1.4012U7. 13 ~ 1214............
1402207 17 ~ 4078 1403207 1 3 ~ 4736 0 ~ -1 655 TAOLE 'OF MEANS (SOATEI) )
SAMPLE...,
NUMf>ER
....,N...,. MEAN 0~ ,. 6 '752 2 ~ 0 7F 1488 0~ 9 '476 4 ~ 0~ . 13+0276,
~ NAX I MUM NONS 1 GN lF I CANT RANGES
...SUOSET . SAMPLE,NUMBERS 1 I 2 l ~
Chlorophyll a (mg/m 3 )
GNK Tl:.5 1 4 HEANS TRANSFORNATION CODE = 0 F. II A OR M S 0 F 00000
',I 0'!
3 2610
~ 4 '410 4 '290 SA Wr LE h'EAN VAR 1 ANCF COEFF IC lENT OF VARI ATLON L...... NUMOLIR 1 3 6.097n 0 '941 1 1 ~ 1747 1 11 1207 r.rom 1112207 6 '524
~ i 1113207 6 ~ 4524 I.
2 3 8522 0 '466 7 '469
, '211207 (> ~
- e. 38n6 1212207 6 '986 1213~0 7 7 '734 e
3 3 8 ~ 8236 0 '224 1 ~ 6952 13112ur 0 ~ 7 08.4 1 ~ $ 12207 8 ~ 7702 1313207 0 '921I
~t 3 1 3 '346 0 F 1776 3 '605 I ..1411207 " 1 3 ~ .1 244.
14 12207 1 .3 ~ 8198 0 14 13207 1 3 '596
- 0. ~ 2602
~l VAnLC OF vLANS (SORTED)
~
'SAYPLI'='ODDER N MEAN I
2 ~ 0~ 6 ~ 8522 1 ~ 0 ~ 6 ~ 8974 3 ~ 0 ~ 8 '230 I
- n. ..0 ~ . ,13 '346
p~g gtl fItrn~tl!yt ) $ !tq~/!!I )
~
'gt!t' t 's t' III: I I) .
kl! hI e I'I.j4I': 'Fk@ar'IO t CJOE ="
t.<<>!tier "I , 0 I !Itt!(II MS 0 ~ 000() 0 3 '610 4 ~ 0410 4 ~ 5290 SAMPLE N MI.:AN @All I ANCE ' COEFF I C I ENT OF VAR! AT I ON '
NUMBLR 3 :I ~ 4 550 0 F 122? 10 ~ 1 168 I 131207 3.49aO 1132207. 3~ 7824 11'33207 3a0070 2
12.! 1?07 3 3 3s 0900
?024 0 '202 14 '510 1232207 3o 7176 .
1 233? 07 2 ~ r 996
-3 ~ 3 0 ~ 5374,....... 0 ~ 1232 'I 121 I 331207 Oal336 13 32207 P. ~ 7 702 133 3807 e.70bn' 4 3 11 ~ 7266 1 ~ 4369 10 '223
... 1431207 ....12 ~ 0738.
- 143220r 12.7134 1433207 10.3926 .,
0~4 r56 TAOLE OF MFANS (SORTEO)
SAMPLE................N ....MEAN .'..
I'UMHEk 2 ~ 0 ~ 3 ~ 2024 1 ~ '0 ~ 3 ~ 4550 3 ~ 0~ 8 ~ 5374 4 ~, 0~ 1107266 NAX I MUM NONS I GNIF I CANT RANGES
........ SUB SE T SAMPLE NUMBERS 1 ? 1
c4 3
Chlorophyll a (mg/m )
SNK IFST 4 MEANS ~ TRANSFORMATION CODE = 0
....., . ERHOle MS 0 F 00000 3 ~ 2610 4 '410 4 '290 Q 'AMPLE N MEAN VAR I ANCE COEFF IC IENT OF VAR I AT ION NUMHEA 2~0786 0 '90? 30 '696 1+6902 2 '996 1 ~ 7460 c.' I ~ 3384 0 '496 6 6705 125120? . 3 ~ 4 33c2
, ...., 125220? 3 ~ 0840 1253207 3 ~ 4980
~ -- ~ 3 ~ 2 ~ 0952 .. . 0F 0000 0 F 0000 3151207 0952 3152207 2 ~ 0952 3153c207 0952 I
il 4 V.7V nn 1 '5PO 1 .1 k .) 1 I! 0 f H.(V3a
- 12!ir'207 P.7310
.Sc'532 u 7 2 '996 0 ~ 1 104 TAt3LE OF MEANS (SORTED)
SAMPL'E ........... N, MEAN NU~~SER
. lc .. 0~ 2 ~ 0786 3 ~ 0~ 2~0952 4 ~ ', 0~ 2 '750
~ 2 ~ ~ .Oa .3 ~ 3384
'AX I MUM NUNS IGNIF I CANT RANGES SUUSET .. SAMPLE NUMBERS .....
1 1 2
D-83 3
Chlorophyll a (mg/m )
5VK I L) S T .) MEANS ~ TRAN SFORMAT I ON COOE = 0 I-RIOR MS = .. 0~ 00000 3 ~ I 510 3 ~ 0770 4 ~ 3270 4 ~ 6540 ShliVLE N YEAN VARIANCE CQEFFlCIFNT OF VARIATION
.NUMBER I' 5 ~ 6150 0 ~ 3210 10 '896 2101207.
2102207 2 I 03207 l II.? 094 I I ~ OI Ik r'l!0 I V07
~ 2~0220 t 2203207 3 3 . Il ~ 1060 .1 ~ 4123 10 '234 23nI?07
?302207 2 303267 3 I'0 '996 0 '464 5 ~ 5011 24 0 1207, '-.........,...........,
2402207 2403207 5 3 12 '222 0 '114 7 ~ 0156 2501707 2502207...
2503207 0 '517 TABLE OF MEANS {SORTEOI
~l SAMPLE N. PEAN' l NUMHER.....,...., ..
~ 0~ 5 '150 2 ~ 0~ . 6 '094 4 ~ 0~ 10 '996 3 ~ 0~ 11 '868 5 ~ ...........,. 0 ~ ... I? ~ 0222
/
YAX I MUM NUNS I GNIF I CANT RANGLS SUIISE T
.,4,,
SAMPLE NUMBERS I
5 2
o-ec Chlorophyll a (mS/m )
SNK TLST 5 MEANS ~ TRANSFORNAT lON COOE '= 0.
ELLRQB MS = , 0 ~ 00000
'..i 3 '510 3 ~ 8770 '4 '270 4 '540
j SAYPLF N 0 FAN VAR 1 ANCE COEFF 1 C LENT OF VARI AT lON N UH 15EB.
l 5 '436 0~ 1468 6 '467 211 1 207, 21 12207 c'1 1 1207 2 3 6 ~ 5060 0 '443 10 '459 221 1207 2?12207 llew 2?L3207 3 .3 LQ ~ 0424
~ 3679 6 '400
?JLL207
?31220 7 2.51 32(I7 I
n *
~
0302'o '095 2 15 '641 I., 24 11207 2'n 12207 24 L3207 5 12 '870 0 ~ 6265 6 '485 2511207
?512207 251.1207 0 '990 I TALLI-I'>i: lii:AN I (LANAI>>pili 0 .'iAMfILL". Ht'.AN L.....,
j HUh'L5EH 1 ~ 0 ~ 5 '436 2 ~ ~ ~ ( i 0 ' 6 '060
'424
~ ~ ~ <
'3 ~ 0 ~ 10 4 ~ .. 0 ~ 11 '302 5 ~ 0 ' ..12 '870 FAX lIIUM NONSL'GNlFLCANT RANGES SUBSET SAMPLE NUMBERS 1 2
),
t)~05 O))loropl)yl] n (I)!g/m )
'itll I I 's Ml AII',, lib(s))f ll))lib IIl) ( gf)f; e f) t j I'Ill)))I'i'l 1
~
f Il, <iiIII Is L I/ II OI> , f) ~ OPOOP,,
3: J.;-'t O;l.)') 770 ~) ~ 3? 70 4 ~ 65<(0 VF AN VAR I ANCE COEFF I C lEN T OF VAR I A Tt'ON l,,... NUM))ER 1 3 3 '612 0~ 0991 9 '591
,21J1207 2I3PP07 2 1.$ 3207 2 3 3 ~ Of) 54 0 '007 10 '527 22:1.1? 07 2232207 2233207 3 3 5 '862 1+3529 21 '947 2.)31207 2332207 2333207 4 3 9 '796 $ ~8207 22 ~ 4510
.........2431207.
?4 3?207
'243 3207 5 3 1 3 ~ 85?,8 3 '269 13 ~ 3633 2531207,
.-. -,2532207.
2'i33207
) ~ 9601 TABLE OF MEANS (SQRTEI))
SAMT LE N H-F.AN NUMUER 2 0 0~ 3 '654 1 ~ 0~ 3 ~ 1 fi12 3 ~ 0~ 5 '862 4 ~ 0~ 9 '796 I) ~ I) ~ l.3 ~ fl AP A FAX IMUM NUNS I GNIF ICANT RANGFS SUOSET SAMPLE NUMBERS
'" 1 ~ ~ 'I 2 . 3 ~,...
2 3 3 5
D-.85 3
Chlarophyll a (mg/m )
fLST '. 5 BEANS ~, TRQQSFORPATION COOE =
3 ~
SNQ EQQOQ 1510 3 HS =
U770
., ' ~ 3270 Oo 00000 4 ~ 6540 0
SQRPI E N PEAN VARIANCE COHFFIClENT OF VARIATION a....... NUMBEA 1 3 2 ~ .I 1 14 0~ 034 3 8 ~ 0111
?. 15 l 207 2152207 215J$ 07 3 2 ~,9.9 I? 0 ~ 23? I Ieel052 22 71207
~ 22'52207 225 1207 I
3 3 7 '012 0.27ae 7 '294
? "351207 23,5dc?07 2 35 $ ?07 3 ~
7 ~ 5002 0 ~ 4239 0 ~ 9187 2451207 8452207
?4o 3807 I
I 5 3 1 3 ~ 7796 0~ 7735 6o3027
. ~ 25) 1207.
I 2552?07 ..
2'i532D7 0 ~ .'1485 TAOLE OF h'KANS ISORTED)
AyPLC NFAN i NVHOCR 1 ~ 0~ 2 ~ 3114 2 ~ 0~ 2 ~ 9912 4 ~ 0~ 7 '002 3 ~ oe. 7 '012
'I 5s 0~ .13 F 7796 NAX I've NONS I C'NIF. I CANT RANGES SU~rsET SAhlPLE 4
...2..
tVUHUFRS'....1.......1 3
D-87 3
Chlorophyll a (mg/m )
SNK 1EST 4 MEANSRANSFORMATION CODE = 0
,ER)NOR M S 0 ~ OOODO 3 '6)0 4 0 04 1 0 5290 54tl)PLE N ttlEAN Vhl)IANCF. COEFF IClENT OF VARl4TION NUM ULs H 1 2 '200 0 ~ 1626 17 '205
.$ 10120/ 2 '936
.) 102207 2 '952 310 3? 07 2 ~ ()952 i' I s &lot) f l 9 ~ 45())
2012() T I ~ 396H I
3 2 0 2 c.' 7 1 ~ 396 t) 320.)? 07 1 ~ 04 76 Ol l
3 J 3 301207 3 ~ 3560 2 ~ 79:36 0 '7RO 15 '345 330i207 3 ~ H4 12.
') 30 '1? 0 7 3 ~ 4332 I
Q e 4 3 3 '936 0 '201 16 '296 I .,3401207,. 3 '332 3402207 4 '034 3403207 3 ~ (1442 0 '255 Q I Tht3LE OF Mf=ANS ( SOATEl) )
I ........ SAMf'LE N NUt>HER 2~ 0 ~ 102804 10 0. 2 '280 30 0 ~ 3 '560
, 0~ 3 '936 ~ ~
QI MAXIMUM NONSI(NII'ICANT IlANGSS
. SUO SE T SAMPLF.NUMBERS 1 2 4
C hlorophyll a (ms/m 3 )
SNK TLST 4 -MEANS> TAANSFORMATlON CODE = 0 BR)II)H Mb 0 F 00000 3 '610 4 '410 4 '290 SAMPLE I4 MEAN VAR 1 ANCE COEFF 1 C lENT OF VAAIAT 10N.
'L...... NUMBER 1 ?~ ]724 0 '455 33~9968 Sl l207 1 3~ 0252 I ~ l I 12207 1 ~ 7460 31 13?.07 1 ~ 7460 c! 3 1 ~ 5132 0. 0406 13 '235 321 1?.0 7 1 ~ 3968
, ... 3212201 1 ~ 3966 3213207 1 ~ 7460 3 3 3'e,3 1 6.) 0 '877 Uo9297.
'131 1207 3 ~ 1458 3312207 ~.eeeH 3313207 3e 1458 n 3 ~ '7814 0 '515 ,24 '027
.....341.1207... ...4 ~ 4778........
34 122I) 7 2+7348 34 132,07 4+ 1316 0 '81 3
. I TABLE OF MFANS ( SOR TFll )
I. SAMPLE.......,.
NUHOE Ih
.. N MEAN 2 ~ 0~ 1 ~ 5132 1 ~ 0~ F 1724 3 ~ 0~ 3 '168 4 ~,..., .. 0~ 3 '814
~" "I
NIJNSLGNlF lCANT RANGES
'AX1Ml)M
"--...". SUBSET . SAMPLE NUMBERS .,
l 2 4
D-89 3
ChloroPhyll a (mg/III )
C3 SfvK TLS f 4 MEANS ~ TICANSFORVAT lOY CODE = 0 EAAOA HS 0 F 00000 Qj 3 '610 SAMPLE N
,4 '4 10 YFAN 4 '790 VAR IANCF COEFF lC lENT OF VARlATlON
~
i .... NUHHFA 1 3 1 ~ 629b 0 ~ 1626 24.7436 31 31207 2 '952.
3 1 '32207 1+3968 31 33207 1 ~ 3968 3 1 ~ 7460 0 ~ 1219 20 F 0000 323I?07 1 ~ 7460 323~i207 2 '952 3233207 1 ~ 396A 3 3 6 ~ 1022 1 ~ 3369 18 ~ 9477 3331207 7 '090 3332201 4 '300 3333207 6 '876 4 So 2730 2 '688 32 ~ 1214 34 $ 1207 5~ 4636 14 IP. P Il f Ae Ila')4
>no juror .> i zvio 1 ~ 1 ~~26 Q.
I...,
T4ULF OF H'EANS (SORTED)
.. SANPLC NUHHEH
... , N hlE AN
.lo 0~ 1 ~ 629b 2 ~ 0~ 1 ~ 7460 0~ 5 '730 3 ~ 0~ 6 '022 Q RAX 1 MUH NONS1 GNlF 1 CANT RANGES
. SUOSE7 . SAHPLF NU>i8EHS...
1 1, 3 G
G
'D-90 Chlorophyll a (ma/m 3 )
SNK TLST 5 PEARS ~ TRANSFORPAT lON CQOF = 0 Enncn Ms =,. ..O.oooon 3o 1510 3e87 70 4 ~ 3?,ro 4 eb540 jQg ~ .SAMPLE, N PEAN VAR 1 ANCE CQEFF l C lENT OF VAR?AT 1 ON L....NUP.GER, 1 3 .3 ~ 9? 04 0 ~ 4770 17 ~ 6171 4 101207 410?2or 4103207 2 3 ;.3 ~ 2982 0+1357 1 1 ~ 1700 4201207 4202207 4203207 3 3 ...3 ~ 7422 ... Oe 1460 1 0 ~ 2094 4301207 4302207 4 303207 4 4 '930 0 ~ 4015 13 '021 4401207..
440?207 4403207
'320 '374
~"
3 7 '092 0 8
%, ~ 45012or 4502207.
450 3207 0 184 TABLE OF MEANS tsnnTEOi SAMPLE PEAN
- NUMUER 2 0 0~ 3 '902 3 ~ 0~ 3 ~ 7422 1 ~ 0~ 3 ~ 9? 04.
4 ~ 0~ 4 '930
.Sa .;......0 ~ . ',7 '092 PAX lMUM NONS 1 GNlF 1 CANT AANCiES
.I SUBSET SAMPLE NUMBERS 1 .. . ~ ... ..2,... . 4 . ..,
D-91 3
Chlorophyll a (m8/m )
SNtl I t: 5 I' MEANS TRANSFORMAT ION CODF = 0 Et<I)OR MS = . ~ 00000
.3 ~ 1510 3 ~ 0770 4 ~ 3270 4 ~ 6540 0', 'AMPLF. N Nt=. 4N VAR I'ANCE COEF F I C ICNT OF VAR I AT I AN
.NUMBER 1 3 3 ~ 6876 0 '278 4 '234 4111207 41 12207
'4 1 13? 07 3 3 '570 0 o 0403 6~ 1637 4211207 4212207 42 13207 3 3 3~ 7000 Oe 1253 9 '676 4 311207 4312207 4:I 1 '207 n 6o8954 I ~ 30?.8 alba 5531 4411207 4412207 4413?07 5 3 7 '674 0 '447 5 '830 Q 4511207 l ....... 4512207 4513207 O 0 '282 I TAOLE OF MEANS I SOR TED)
Q:: SAMPLE N MEAN NUHlfER 2 ~ 0~ 3 ~ 2.570 I ~ 0~ 3 '876 3 ~ 0~ 3 '000
- n. 0~ 6 '954 5 ~ 0~ .. 7 ~ 0674 NAX I MUM NONS1 GNIF I CANT RANGF 5 SUtISET SAMPLE NUMOERS
.. 1
~
Q J 2 4 5 G
0
D-92 Chlor'ophyll a (mg(m ) ~ 8 SIIk TtST ERIinn as 3" i Si o 3 ~ 87 7o 4 ~ 32?o
....5 MEAN TRACE:SFORPAT lON COOE
- o. ooooo 4 ~ 654 o 0
SAQPLi= N YEAN VARlANCE COEFFlctENT OF VARTATloN
...... 'hlUH'GER ~ ~
1 3 3 ~ 7422 0~ 1233 9+3840 41312U?
4 133207 4 i3j207 2:3 42 11207 3o 29 72 0 ~ 2574 15 '884 Il 2 3 i" 2 0 7
'4~c 332 07
) II i.90 eO t 0'I:)hi
'4.l 32207 4333?07 3 8 ~ 1490 0 ~ 4601 8 '235
...'.4'43]207
'44 3Z2'07 4 43 3207 5 3 '4'84 '0 ~ 4231 8.'5O49 4531207
........., '453220'?
4 533207
'0'e 3'4'8 7 TAOL'E 'Of" HE'ANS 'l SORTEO)
SAMPL'E N
.NUVuEV 2~ '0 ~ 3'a 2cI72
,'1'e . .0 ~ , .3 ~ .7422 3~ fp. 4 e'9I304 5~ '0 ~ ? ~ 6484
..4 ~ ,......... '0,'o "8'o "1 4'90
~ I PAX1HUH NONS'1'GNlF'fC<<ANT RAhfGES SUtHSE'T SAMPLE 'I'IUHBERS "2
1........<<25 ..... .,3
~ ~I I
D-93 3
Chlorophyll a (m8)r'm )
G SI IK TE5 T b MEAI'IS a TII ANSFORMAT 1 CN COOE = 0 Ell l<OI'C M 5 -" 0 ~ 00000 3 'S 10 3 '770 4 '270 4 '540 VARIANCE COEF I' C 1ENT OF VAR 1 AT I TIN Q SAMVLI= N . MEAL'I NUIjBEIZ I J 3 ~ 892() 0 ~ '04 10 5 ~ 2017
<<151207 415P207 4 53207 1
P 3 ~ 2344 0 ~ 1 351 1 1 ~ 3635 42.) I 207
<<?522 0 7
<<253207 3 3 9 ~ 1544 1 1 ~ 7506 3 7 ~ 4456
<<351207
<<.ISP207 4353207 3 7 '548 1 ~ 5617 16 ~ 9915 4451P07
<<<<52')07 4453207 I
I) 3 7 ~ 3836 0 ~ 044S 2 ~ 8559 QI 455 l 207 j....... 4552207 4553207 0 2 ~ 7066 l TAHLE OF MF.ANS (SORTED)
GI i .... SAMPLE NUMHER N PEAN 2 ~ 0 ~ 3 ~ 2344 1, ~ 0~ 3 '926 I
4 ~ 0~ 7 '548 Qi 5~ 0~ 7 '836 I 3 ~ 0 ' 9 ~ 1544 MAX 1MUM NONS I CaNIF 1CAN I RANGES O
1.....,. 2,...3 SUIISET SAMPLE NUMOERS
D=94 Chlorophyll e (mg/m )
SNK TES T 4 MEANS, Tl)ANSFORMAT ION COOE = 0
,,.....ERROR MS 0 ~ 00000 I 3 ~ c'61 0 no 0410 ' ~ S290 Oj) SAMPLE N PEAN . VAR I ANCE COEFFICIENT OF VAR I A T ION
. .. NUMUEA 1 3 ?. ~ 52SS 0 ~ 1 370 14 '5S6 1 101217 2 '4011 1 1'022'f 7 2 '378 I 1'032 I 7 2 '982 2 '3 2 '626 0 '347 6 ~ 99ee 1201217 2.neon I 20221 7 2 '996 2 '378 I
)
12032L7
)
3 3 8 ~ '04 08 0 ~ 34 3'8 7 ~ 2921
'1305 2 17 u. SOOn
.1.'0022 1 7 8
'748'an382 1 30'1217, 4 3 '8"o 1366 3 '004 21 '868 I' 01217 6. I O32 l'nl)d)") I 7 IL e 0180 lnoz217 9 ~ 4 opls 0 '9290
~j '7AUL'E Ol; ME AN S ( SOR YEO )
l....., . SAMPL'E ... 'N MEAN NUMBER 0 ~ 2 '256
? ~ 0 ~ 2 '626 3 ~ 0~ ~
e.onoa
'n.. '0'o e.'1366
, I
~O'AX IMUM 'NONSIGN>IF'ICANT 'RA'NGES I.. , ...:SVHShT, SA'MPL'E 'NUMOERS 1 1 2 2 3 4
9-95 3
Chlorophyll a (mg/m )
SNK TI:ST MEANS, TRANSFORMATION COOE ~ 0 ERI"UH .MS 0 F 00000 3 ~ 2610 4 ~
~ 0410 4~ 5290 SAMPLE N MEAN VARI ANCE COEFF IC IENT OF VAR I AT lON
..NUMHER, I
I I I 121 3,
7,. I ~ 9592 2>> 0304 0 '343 9 ~ 4512 I I I?2 I 7 I >> 7490 1113217 2 0982 P 3 2 ~ PI 66 0~ 0410 9 ~ I 348 1211217 2>> 0982
... I? 12217 2>> 1012
- 12) 3217 2 '504 3 .3,.... 3~ 2220 0 '354 5 '367 1311217 3 '840 I 312217 3~
3~ 4362 145'313217 4 3 II ~ 9 6 3 II 0 '405 5 ~ 5613
... ......., I 4 I I 2 I 7 9 '606 I II I~2 I 7 ~) > fl)ling Il I <i'I 7 Ba AOIIO III0890 TAOLE OF MEANS (SQRTFO)
SAMPLE MEAN NUMQEA I>> 0~ 1>>9592 2 ~ 0~ 2 ~ 2166 3 ~ "0 ~ 3 '220 4 ~ 0>>... 8 ~ 9638, f
~ ~ ~
MAX I MUM NQNS I GNIF 1 CANT RANGES
.....:. SUUSET.. SAMPLE . NUMBERS I' 2
D'-'96 Chlorophyll a (ms/m 3 )
SNK TLST '4 MF AN 5 ~ TR ANSF ORHA T 1 ON COOt.. = 0 ETIPOR MS 0 F 00000 J ~ 26l 0 F 04 10 4 '290
'AMPLE "
N YEAN VAR l.hNCE COEFF1C 1 ENT OF VhA I AT?ON I, ..... NUMUI=R.
I 3 2 ~ 6616 0>>0343 6 '602 lldl217 '
2 '966 1 132217, ~ 7378, 113 I?17 2.4504 2 1 2 '030 0 '270 1'9568 I /3 Ill 7 2 '340 12322I7 2 '730 I
I 21 I/I 7 ~
V.Inly I 3 6336 o.onno 3+1924 I')31217 6~ tI664 0 133221 7 6 '820 13332 l 7 6 '524
~' 3 9>> 1440 0 '092 1 ~ 0503
,. 1<<31217 9 '606 14322 I 7 9 ~ 1224 0 1433217 9 ~ 2490 0>> 0426 C
I
~ T'llBL'E OF 'MF AN>> (SCRTEO) i 'k'APRL'E N. PEAN
!NVtlUER 2~ ~ 0 ~
" '7. >>'5030 1>>
3' 4,i ~
'0
'0 iO ~
~
~ '6 '33b'2>>'6616
.: 9 ~ !1440
' 'P'AX 1MUh1 NONS1'GN IF:I'CANiT /RA'NCES
.....'SUB'SEiT ', 'S'AMPLE .lNUPBERS 2 tl i
t[
D-97 Chlorophyll a (mg/m )
fiNK Yh5 I 5 MEANS i IAANQf'OHh'ATION COOK 4 0 CRnan MS ~ 0.00000
,.I 3~ 15)0 > ~ "770 4 'P70 4 'iI40 Q' hftftLE N NEAN VhflthNCE CCCVf'ICtENT ttV VAfltilitilN NUbll!IL'R
~ l 9 q II n,>sea 4A f0l6 Il I 0 le I I 0 l l)d.". l t 2 l 03217 3 2 '760 0 ~ 1027 11 '437 220121 7 220221 r I
22032 1 7
't Oi 3 3 2 '596 0 '347 7 '067 2301217 230221 7 23032 17 Q
l
~ 4 3 3 ~ 20 14 0 '414 6 '524 2401217 2402217 240 321 7 t
5 5 '934 0 '926 7 '46B 0 I 250121 7 250221 7 2503217 G 0 ~ 1242 I 'AOLE OF MFANS (SORTEO)
OA SAMPLE MEAN NUMULH I ~ 0 ~ 2 ~ I 940 3 ~ 0 ~ 2e 6596.
2 ~ 0~ 2 '760 4 ~ 0~ 3 ~ 201 4 5 ~ 0~ 5 '934
.MAXIMUM MONS I GNIF ICANT RANGLS, g SUBSET SAMPLE NUMBERS
.,..1,, ......1..... 4, ,,
a (ma/III3 )
~
'?'hlorophyllSNK TEST 5 NEANS 'RANSFORPAT10N EOOE = 0 ERROR MS = -..... 0 F 00000 3 )10 3 '770 4 '270 4 '540 Ised SAMPLF. N YEAN VAR IANCF. COEFF IC lENT OF VARI AT (ON.
-.. NUN'OER .
I 3 c~ ~ 6596 0' I 804 9678 2111217 I.
2 I I 2.2 I 7
?.113?17 2 3 ?. ~ 2'I 5) 6 Oa0414 9+ 1788 2211217 221 c'21 7 221'3217 3 I 3 2 '976 ... 0 ~ 1219 12 'S23 2311217 23122l 7
..231'321 7 4 3 6 '224 F 1153 nS.S900 241 1217 24 I c'21 7 24 I.IP. 1 7 5 5~ 6376 0 ~ 0396; 3 '302
?511217
.;25122l 7 2!i 1 321 7 I'997 TAALI. Ot. MEANS ( SOHTI:II I' SiAMI)LE NUMOCR
) 'EAN
? ~ 0~ 2 ~ 2156 1 ~ .0 ~ ., 2 '596 3 ~ Oe ~
2 '976 5~ ~ 0~ 5 ~ 6376 4~. , 6+6224..
MAXIMUM NONSIGNlf lCANT RANGES L...1.....,
SUHSFT SAMPLE NUMBERS
. 2 4........
~ ."
Qe Chfaraphyll
~~'l"
)lfffHI! kl."
1:-:,
a (p~/m )
5f ""' l~""~t HfIt'"fl>~"
'o.'Hbbb8
'HHf- -. 'I 3:JC I b 3: H'$$ O 3: 32$ O n.'6643 SAI4PI E l'l P4AN VAR f AhlCk COEFI- I C f khlf lid VAR I ar t ON
.....NUMBER 1 3 2+4298 0~ 1016 I 3 ~ 1204 21312l 7 21 j2217 213321 7 7 3 2 '760 001016 1 1%4841 2231217 22.32217 2?S3?!7 3 3 3+7220 0 '345 ' '651 23 '3 121 7 2332217 7.333717 4 8~ 6126 12 '358 4 1 ~ 1094 2431217 243221 7
.2433217 I
I 5 3 6 '688 0 '284 11.0662 C3 ?53!d!7 I . .: 2532?17 253321 7 2.f 604 T AHLE OF MEANS (SORTEO)
C), SAMPLE, N MEAN I....,....... NUMHE R I ~ 0 ~ 2 '298 2 ~ 0 ' 2 '760 3 ~ 0~ 3 '220 5 ~ 0~ 6 '688 0~ 8 ~ 6126 flAXIMUM NONS I GNIF I CAN T RANGES
..I...,
SUHSET SAMPLE NUMBERS
. 1,...,...4 G
D 100 3
Chlorophy11 a (mg/m )
I I t.> I b MEANS TRANS'BLATION CODE = 0
.'ErROk MS =... . O.OOOaO 3~ )510 3 ~ 87 70 4 ~ 3270 4 ~ 6540 SAMPLE N PEAN VARIANCE COEFFICIENT OF VARIATION L......NUMBEk 1 3 2 ~ 0934 0 '272 5 ~ 7051 2151217 2152217 2 153? 17 2 2~ 6012 0 ~ 6559 30 ~ 2069 2251217 225221 7 225321 7 3 . 3 ....3 ~ 1272 0 ~ 1026 10 '439 2351217 2352217 2353217 4 3 '
~ 051.0 . 0~ 1495 '3 '243
... 2451217.......:,..........
2452217 245321 7 I
6 '732 0 ~ 5666 11 '995 2551217
."..........255221 7 ..
255,321 7 0 ~ 3004 TA8LE OF MEANS (SORTED)
SAMPLE ~
N PEAN
., NUMBER,.....,
2 ~ 0~ 2 '812 1 ~ 0 ~..., 2>> 8934 3 ~ 0~ ~ 1272 5>> 0~ 6 '732 4 ~, .. 0 ~ ...,9 ~ 8518 ..
PAR I MUM NONS I GN IF I CANl'ANGES SUUSET ~ SAMPLE NUMBERS
. 2 , ... , .. 3 P
D-l01 Chlorophyll a (mg/m ) 3 L
SNW TEST 4 BEANS TRANSFORMATlON CODE = 0 EHROll MS o.ooooo 3 ~ 2610 n. on 1 o 4 '290
$) SA MPLE N WEAN VAR1 ANCE COEFF I ClENT OF VAR lAT1ON NuhlHE R 1 1 ~ 0476 0~ 1219 33 '333 3101217 1.0476 3102217 0.6984 310321? 1~3960 3 1 + 1640 0F 1626 34 6410 32012 l 7 0 6984
! 3203 1? 1 o 3960 3 . 3, 7 ~ 9326 1 ~ 8701 17 '393 330121? 9 ~ 3100 3302?17 6 7 '110
'760'303217 4 3 9~ 2862 0 ~ 1221 3 '630
.... 34 0 1 2 1 7...,9 ~ 24 60........
34 022 1? 9 ~ 6540 34 032 1? 8 ~ 9586 0 ~ 5692, I
iI T'ABLE OF MEANS (SORTED)
SAHVLE............. N .... PEAN NUh'HER 1 ~ 0~ 1 ~ 0476 2~ 0~ 1 o 1640 3 ~ 0~ 7 '326 4 ~ ......0 ~ 9a2862 J. PAR}MUM IPUHht OI4t!='f CAI4t RAAbhh
...., SuljsEt BAHt LE. NuveERS .,
1 1
I D 102 Chlorophyll a (ms/m 3 )
S "IK TI. S T 4 IIGANS ~ TRANSFORMATION CODE = 0 EHIPOk HS O.OnOOO 3 '610 SAMRLF N 4 '4 10 YEAN 4 '290 VAR l ANCE COEFF 1ClFNT OF VAR l AT?ON NUMUEP 1 3 1 ~ 1640 0 ~ 0406 1 7 ~ 3205 3111217 1 ~ 04 76 3112? 1 7 1 ~ 3') 60 31 1 3217 1>> 0476 3 0~ 933? 0 ~ 0413 2 1 ~ 7890 3211217 1 ~ 0506 3? 12217 1 ~ 0506 I
321321 7 0 ~ 6904
~l I I
3 3 8 ~ 3870 0 ~ 0275 1 ~ 9784 3311217 0 ~ 4 02tf 3312217 0 ~ 1 954 3313?17 0>>4020.
I i 4 3 9 '01? 0~ 1473 4 '808 I 3411? 17 0 ~ 0320 3412217 9 '922 3413? 17 9 ~ 1 194 0 ~ 0642 I
~ TAOLF OF MEANS (SORTEO) l,... AMVL'F NUMBER N.. PEAN 2 ~ 0~ 0 ~ 933?
1 ~ 0 ~ 1 ~ 1640 3 ~ 0~ 8.3870
~, 4 ~ 0>> 9 ~ 1812 MAX lMUM NONS1GNlF lCANT RANGES SUOSET . SAM+LE NUMSERS 1 2 1 3 4
I D-103 Chlorophyll a (mg/m 3 )
SNK T c'. S T MEANS ~ TRAhSFORPAT I ON CODF = 0 EH teO>e Ms 0 ~ 00000 3 ~ 2610 4 '410 F 5?90 SAMPLE '
MEAN VAR I ANCE COEFF I C IEHT OF VAR I AT ION NUMBER 1 3 1 ~ 3968 0~ 1219 25 F 0000 3131217 1 ~ 04 76 3132217 1' 3968 3133217 1 ~ 7460 2 3 1 ~ 2004 0 ~ 2845 4 1 ~ 6598 3231217 0~ 69en 323221 7 746O 323321 7 1 ~ 3968 3 3 ..7 ~ 5278 . 0 ~ 2498 6 '398 J.S31? 17 7 ~ 6236 33322 7 1 6 ~ 9870
, 3333217 7 ~ 9728 4 3 9 ~ 6056 0 '218 5 9O54 3431217 9 ~ 1194...
343?217 '
0 '280 3433?. l 7 9.4686 0 ~ 2445 I
TAULE OF MFANS (SORTED)
SAMPLE........ MEAN NUDGER ~
2e Oa , la2804 1 ~ 0~ 1 ~ 3968 3 ~ 0~ 7 '270 0 ~..... 9 ~ 6056.
i ..
MAXIMUM NONSIGNIF ICANT RANGES Su'lsET 1
. SAM< LE.NUMoERS.....
1
3 D'1.04 Chlorophyll a (mg/m )
Sample Number Mean Variance Coefficient of Variation 0.8158 0.0413 24.93 3151217 0.6984 3152217 0.6984 3153217 1. 0506 2.1930 0.5954 35.19 3251217 3.0840 3252217 1.7490 3253217 1. 7460
D-105 3
Chlorophyll n (mg/m )
SNK I EST 5 MEANS ~ TRANSFORMATION CODE = 0
. EHIROII PS = 0 ~ 00000 3 ~ 1510 3 ~ 8770 4 ~ 3?70 4 ~ 6540 SAIAPLI.' hlEAV VAI< lANCE COEFFLC CENT OF VhRi AT lON NUMOEH I I 2 '950 0 '281 7 '384
.n I O1217 4 10221 7 410 I21 7 2 .I 1 ~ 7480 0 ~ 4899 40~040 L 420 I 217 420217 I n2o.l'17 I 3 1 ~ 7840 0 '309 9 ~ 8506 4 301217 4:Io? 217 n.j0321 7 3 9~ 3120 1 ~ 1660 11 '957 440121 7 4 n 022 l 7 440 3c! 1 7 1 3 5~ 7230 0 '979 13 ~ 5110 45012 7 L
.... 4502? 17 450321 7 0.4625 TABLE OF Mf'ANS (SORTEO)
ShhlPLE ' VEAN NUVOCR 2 ~ 0 ~ 1 ~ 7480 3 ~ 0 ~ 1 ~ 7840 1 ~ 0 ~ 2 '950 5~ 0 ~ 5 '230 4 ~ .Oi 9 '120 hIAA IHUhl NONS 1 GNlF f CANT RANGFS SU<45ET SAMPLE NUMBERS CP 1.......,,2......1....
D 106 3
ChloroPhyll a (ms/LLL )
JNK I r'5 I '8 MEhNS TRANSPQRHA T 1 ON COI)8
~,. ~ 44 I1 EL)I)OR VS 0.00000 a,<e)0 1.n)rn 4,>zro n.risen L)AMI>I I N ISAIAH Vhlt I ANCE CORI'P j CILHf L1P VANE hf fax IAUMILI It iI lg >RA) Oc I)) l f ILiI I liI i f ILdl ')0 I t
? 3 ... 1 ~ 981S 0 '4L7 )0+3045 411 1217 4112217 4113?)7
=3 3 ? ~ 3340 0 '407 8 ~ 6369
........ 4311217 431?2 1 7 4313? 1 7 4 3 9 ~ 1966 O S )821 4 '401
- 44) 1217
....44) 221 7 ....
44 3217 1
..5 3 .7 ~ 0334 0 ~ 7719 12 ~ 4919 451 12) 7 451221 7 L...,. 45)3217 0 '303
.,TABLE.CI- MEANS (SORTEO)
SAMPLE MEAN NUMQER 1 ~ 0~ 1 ~ 3983 2~ 0~ ) ~ 96)U 3 ~ 0~ 2 '340 5 ~ 0~ 7 '334 4 ~ 0~ 9 ~ 1 966
'I
.MAX LMUM NONS )GN)F I CANT RANGES SUOSET SAMPLE NUMOERS 1 3
D-1D7 3
Chlorophyll a (mg/m )
SNK II=ST 5 MEANS'AANSFORMATlON CODE = 0 EA IVOR M 5 0 F 00000 3 ~ 1510 3 ~ 8770 4 ~ 3270 4 ~ 6540 SAMPLE N NEAR VAR1ANCE COEFF1CIFNT OF VAR?AT 1 AN NUIT ACR 1
'1 1 ~ 7510 0.1219 19 ~ 9431 4131217 413e217 4 13321 7
- 2. 5 i+lb'50 0 '863 45 '269 4231217 4232217 423ae17 3 3 2 '626 0 '793 26 '022 4 '$3121'!
4 5.'322 I 7 43 532 I 7 hI &lb 4431217 44 JZ? 17 44 3.1217 I
5, 4531217 3 6 '482 0 '004 1P ~ 5960 I.... . 4532217 45 5321 7 1 ~ 7005 TABLE OI-" MEANS (SORTED)
SAMPLE N l4EAN I IUMBE 8 2 ~ 0~ 1 ~ 1 650 1 ~ 0~
=
1 ~ 7510 3 ~
". 0 ~ 2 '626 0~ 5 '316 5i 0~ 6 '482 MAX I MUM NONS 1 GNIF 1 CAN T,,RANGES C7 SVASET SAMPLE NUMOERS
.,l., ~ = ~ ~ ~ 2 o ~ ~ ~ ~ ~ ~
D-108 Chlorophyll a (ma/m )
INK I t.'5 I 5 HEANS ~ TRANSFORNAT I ON COOF = '
FRHCH HS 0>>00000 3 ~ 1510 3~ 8770,4 ~ 3270 4 ~ 6540
~): SAMPLE N'NEAN VARIANCE COEFF IC IENT, OF VARI ATION
.... NUMBEA ..
- 1. 3. 2>>.1950 O 0497 10 ~ 1565
. 4151217 4 1522 l 7 4153217 )
2 -3 2 '640 0 ~ 2877 22 '084 n 25121 7 ~ ~
..... 42.52217 4253217"
...., .. 3 .. 3 ....6 6440......,.
~ 2 ~ 6508 24 ~ 5050 4351217 4 15Pdl 7 4353217 3 7 ~ 2044 5 '499 33 '718
.4451217 4452217 aa532,1 7
'5 '
&>>6224 '
~ 0403 3 '314
'4551'21 7 L .....4'5522,1 7 .
45'53i! 1 7
'1 ~ 7 7.5.7 t
I"
'T'ABL'E 'OF 'MC'ANS ",(SORTED,)
'S "A M P 1.'E 'N PEAN
~L.......... NUMUEA
'I.>>, <0>> .2, ~ I 95.0
.2 ~ ..... ~...~0+., '2>> 3&40 (0. ~ ~ .6 ~ 6224 3 ~ to ~ ',>>'.644 0
. >4 ~.........."..0 ~ ...., ..7s'2044
~
' ~ ~ ~~ ~ ~ ~
'P'AX I'NULLI NONS,I GN'IF:IC'ANT RANGES
- SUD SET 'SAHPL'E lNUNBERS L ........~I ............:1....... '4...,..::... '..
p 1 ' Il 3
Chlorophyll a (mg/m )
SNK Tv.SI n MEANS, 'TI<ANSFOANATION COOP = '0 l ERROIE ..MS 0 F 00000 3 '610 4. ~ 04 I 0 44 5P,90 C,I ~
'SAHPLII, N ME AN VAR 1'ANCE " COEF F 1 C TENT OF. VARIATION NUMOEH I 3 I ~ 7090 0 '838 16 '258'I ".4
, 5101217 'I ~ 74 90 510c'.217.. I ~ 9776 k
510321 7 I ~ 402H l
? 3 I ~ 0516 0 '230 - 33 '493 520 121 7 0 ~ 7014 5202'! I 7 I a 0506 I. 5203217 . I ~ 4 028 I
3 3 2 '304 0 ~ 24 35 ', ?4 ~ 2084 5 '10121 7 ~ 7520 5302217 . I ~ 7550 530 3217 2 '002 1I I 4 3 6.6906 4 '206 '?9 '336 5401217 F 1032 /
5402217 5 '586 5403217 0 ~ 9340.
I I ~ 1177
'c I
Oi- I TADLE OF MLANS ( SCR TED)
I, SAMIELE, N Mf. AN ~
i~IUMHEA 0 ~ I c Oc316 I I ~ 0 ~ I ~ 7098 6', 3 ~ 0 ~ ? ~ 0304
~ < ~ 4 ~ 0 ~ 6 '986
. Q 'AXIMUM NONS IGNIF I CANT RANGLS
.SUOSET SAMPLE NUNDCRS I c'
~ ~
"3 Chlorophyll a (mg/m ) I i 0 .
SNK TEST ERROR MS
=, '
MCANS ~ TRANSPORMAT ION CODE =
0 ~ 00000 0
3 ~ 2610 4 ~ 0410 4 ~ 5290 SAMPLF N MEAN VAR lANCE COEFF lC'lENT OF VARl AT lON L......... NUMUER . ~ ~ ..>> '. -.- >. - . ~ ~ . ~
3 ,I ~ 61 30 O.omni 11 ~ 4471
.5111217 I ~ 74 90 51 I 2217 I ~ 6872 51 13217 1>> 4,02U 2 2 '706 3 '900 0 '2II
'I 5~ 1 142 52 l217 1
.....,... 5212217 2 '996 5213217 lory lory3 '222
........3 3 . 5 ~ 9642 2 '983 28 '443 5311217 7>> 7874 5312217 '>>6892 5313 17 n. n I 6o 0970 0 '154 9 '757
......5411217 6800 5412217 Q>>9928 sn I.>21 7 10 '182 0 '677 I
1AIBLF. Ol= MEANS lSORTED) i.............. SAMPLE N .,MEAN NUMBER 1 ~ 0~ 1 ~ 6130 2 ~ 0~ 2 '706 8 ~ 0 ~ 5>>9642 4>> 0~ . 10 '970 NAWIt)UH hlUhjstuWik (6Ahtt WAWtIL5
, .... sUUCL= T sihIi~Lh;luMI3ERS.
I ~
I 2 2 3
~ ~ ~ ~
Chlorophyll a '(mg/m )
3 D l Q SNK ThST 4 PLANS ~ TRANSFORkATION COOF 0 ~ 00000 0
. ERROR .MS . << ... =..
3 ~ 2610 4 ~ 04 I 0 4 ~ 5290 ql Q; 'AMPLE N MEAN VARIANCE COEFF I C IENT OF VAR I AT ION I.,;.. NUIIBER 3 I ~ 9230 0 '222, 7 ~ 7512 5131217 I~ 7550 51 3?2 I 7 ?.0394 51332 I7 I ~ 9746 4 3 I I +3454 I ~ 3090 10 '845 533 I 21 7 I I ~ 7864 533 "21 7 ., 12 ~ 2034 533321 7 I 0 ~ 04.64 3 3 . 12~8504, 3 464 F 14%6547 54312 I 7 10' 6800
.543?? 17 14 ~ 0514
. 5433217 .13 ~ 8-190 I
3 ~ 3109 0 '620 7 '038 I 5231217 . 3 '428.
5233217 3 '950 I ~ 4025 TABLE OF MEANS ( SORTEO)
~
Q', SAMPLE N PEAN I..... I'IUMQER I ~ 0~ I'230
- n. . 3o3L'89 I. 4 ~ 0 ~ LL ~ 3454 EQ: 3 ~ 0 ~ 12 '504 PAX I MUM NONS.IGNIF ICANT RANGES P SUPSET SAMPLE NUMBERS 3
Ik
~ I c9
3 Chlorophyll a (mg/m ).
SNK TL 5 I' NEAI4S ~ TRAHSFORVAT I ON CODE = 0 EAROR HS 0 F 00000 3 '610 4 '410 ' '290 SAMPLE N MEAN VAR I ANCE COEFF I C IENT OF VAR I AT ION
.... NUh! DER 1 3 2 '020 o onO6 8 '58b 5151217 2 '056 515221 7 2 '348 5153217 2 '856 r>,
.5 3 ~ 5846 0 '801 14 '636 5251217 4 '728 525221 7 3 '510 525321 7 3 '222 3 '724 2 '592 45 ~ 1617 715121 7 5~ 1 792 7152~1 7 3. 1 n28
'7 15.521 7 2 '952
'5 el n 3 '722 0 ~ 0351 5 '477 7?5121 7 3 '4980 7252217 3 ~ 4332 725S217 T~ 7854 O TO3V TZOtV at- t.VAna ISOOrat~)
5 Alllhl-L:. AN.
IIUMIIER
ÃAXIMUH HONS IGNIF ICANT RANGES
. SUOSET .. SAI4PLE NUMBERS
D-113 3
Chlorophyll a (mg/m )
SNK fL'5 T b MEANS ~ TRANSL=ORMAT I(1N COOL = 0 E eieoie ps =. 0 ~ 00000 3 ~ 1 5 1 0 3 ~ 0770 4 ~ .3270 4.654O
'AMPLE N MEAN VnRI ANCE COEFFICIENT OF VAR I AT ION
..NUMOEA I 2 '156 0~ 1654 1'555 6101217 6102217 61032 1 7 2 3 2 '246 0 ~ 2190 Iu 5349 62012 L 7 6?02217 620321 7 3 1 0~ 0640 3 '680 17 ~ 4045 6 501217 lory 6302217 6 '50321 7 4 3 9 '888 0 '452 4 ~ 9572
..6401217 6402217 640'3217 I 6 3 2000 0~ 3149 5 '013 6501217 t.......... 6502217 6503217 0 '025 T'AHLE OF MFANS {SORTEO)
SAMPLE N PEAN NUM!IF Le 1 ~ 0 ~ 2 ~ 2156 2 ~ ...........,0 ~ .2 '246 4 ~ 0~ 9 '9888 3 ~' ~ Io ~ 06'40 5 ~ ...,....0 ~ 10 '000 PAX IMVH MONS IGN IF ICANT RANGES SUASE T SAMPLE NUPIIERS 1 .... 4...,5...
1 2
3 Chlorophyll a (ma/m )
SNK 1L.ST 5 MFANS ~ TAANSFORNAT 10N COOP = 0
. 1=RWUR MS 0~ 00000 3 ~ 1510 d>>8770" 4 ~ 3270, 4 ~ 6540 SAMPLE N'EAN VARlANCE'OEFF lCiENT'OF VARlATlON L.......NUMBER 1 3 2>>3114 0 '360 '8 ~ 210.1 61 1 121?
~
6112217 611321 7
~ ~
2 3 3~ 0390 0 '410 5 ~ 2743 621121 7 6218217 Ail ~PI 7 3 . 3 10 ~ 9560 . 0 '449 b>>7376 6.1 1 121 7 6.S1 28 17 b313217 4 3 1 0~ 4854 0 '968 4 ~ 2312
.64ll217 6412217
.6413217 5 3*, 8 ~ 8806 0 '443 7 '994 6511217 6512217... '..
651321 7 0 '526 I TABLE OF MEANS (SORTEO)
I SAMPLE N PEAN
........,...., NUMBER
-I 1 ~ 0 ~ 2 ~ 3114 2 ~ ....... 0 ~... 3 ~ 0390.
5 ~ . 0>> -
8 ~ 8686, 4>> Oe 1 0 ~ 4854 3 ~.............0 ~, ... "10 ~ 9560 I KAXlMUM NUNS 1 GNlF 1 CANT RANGES SUbSET SAHPLE NUMBERS
.. l. '2 2 5 4
Chlorophyll SNK I c 5 I i (mg/m )
3 5 VL'ANS ~ THANSFORMAT I ON COOE = 0 F.HROH MS 0F 00000 3 '.)10 3 '770 4 '270' '540 AAMFLF.
"--.-",NUMBER II
. ......, MEAN VARIANCE I
COEFFICIENT OF VARIATION I 3 ~ 2 '246 0 '35)0 7 ~ 4056 6131217 61 32217 6 13 3217 2 3 4 '962 ON4607 15 '968 f)23 I 2 I 7 623221 7 I
I
.6233217 l 3 3 12 '356 , 0 ~ 1016 2 '488 6,33121 7 6332217 63'33217 4 3 1 0 ~ 83.76 I ~ 9669 , 12 '406 6431217 ~
64 3P'17 6433217
) 3 10. 4534 0 '857 6 '667 653121 7 L. 6532217 653 3217 0 '100 I TABl E OF IEEAN5 ( SORTEO)
~l ~
SAMPLL N IvEAN NUI>UER I ~ 0~ 2 ~ 5246 V . 2 ~....,.. 0~ . 4 ~ 4962 5 ~ 0~ I 0 ~ 4534 4 ~ 0~ 10 ~ 8376 3 ~...,. , .. 0 ~ 12 ~ 0356 NAX IMUM NONSIGNIF ICANT RANf FS SUII SE T SAMPLE NUMBERS 1.......5......
2 I 2
,/PI'phyll g!gy/It I l~
L'll l,l=.it ~ 5f'-'"4':'lllnkkf-'555kfff)t~ h@h =
..LI!Pllli 5~ =;, ...
3;- I 5) 8 3: 3f r'd 4.'32f O 4.6d40 SAMPLE N YEAH V AR1 ANCE CaEPW iC i'qhT OF VAR 1 Ar t(i4
-.-.".-NUMOBH I, '3 ' ~ 2014 0~ 1 633 1 2 ~ 6223 6151217 6l522,t7 6153217
~p 5 ~ 4460 3 '761 32 '047 6231217
...... 6252217 6253217 3
63'D1217
-3 1 po 7428., ..0 ~ 9718 9 '764
'6.952'1 7 635 321'7
'4 ..3 lpe959? 1 ~,1798 9 '113
. =.64 512 1 7
'6'452? 17 t) 4532 1 7
'6S'6'1 21 7 9 '050 009306 10 ~ 7129
- 65522 1 7
~
'65532 1 7 1 ~ ?643 TAHLF. I IF MEAN S (SORTED)
S'A'MPI F 'N '
MEAN
~ .......,....NUMUEA.
1'o '0 ~ 3 ~ 2'0'1'4 2 ~ '0 ~ .. 5 ~ 4460
'5 ~ '0 ~ 9 ~ '0050 1 ~
'4 ~ ..
t'0, ~ '10 '428
,...10 ~ 9592
'MAX'1'M(JM 'NON S 1 GN 1F.I CANNOT 'RANGE'S SUI3SET 'SA'MPL~E iNUMBERS J2 F4
'? Cl '2
D 117 Chlorophyll p (mg/m )
g !IN' I:.5 I fE II II I'.I l > g 6 Mt ANli n.
I I'<AhbP QPIhk 'f I ON C(IPC +
On f1 IIO 0
,f ~ Its tl) 4 llh 4 ~ ~>c'9
~
~LAlhf VhA l ANCE CHI:-I'l- f C f L0f HI'VAR lb T f H4 NiJI'L=A I 3 I ~ ~~ I 32 0 ~ 2045 35 '506
.. 7101217 7 ~ 0952
~ 7102217 I ~ 3968 7'-I 0 32 I7 I ~ 0476
~
'472
~
2 3 ~ 2 ~ 21 36 0 ~ 0410 9 720121 7 2 '952 720221 7..... 2a 0982 .
r20321 7 2 ~ 4474
~ I
,3 . 3 ...,.. 8 ~ 0944 ...... 2 ~ 0354 I? ~ 6254 730121 7 6 ~ h 554 7'3072 I 7 8 '702
. 730321 7 9 '576 4 3 24 ~ 1870 5 '324 9 '473
...74 0 12 17 .. 26 ~ 8458........
7407217 22~6830 740.3'2 t 7 ?3 ~ 0322 1+9233...
TABLE Ol-" MEANS (SORTFO)
L ............ SAMflLE......., N...., .. MEAN NUMlsl: R'
~ 0 ~ , I ~ 5132 2 ~ 0 ~ 2 ~ 2136 3 0 o 0944
- 4. ........ 0~ .. 24m 1870
~ '
MAX I MUM NON S I CN lF 1 CANT HANGES
........ SUOSET ... SAMPLE,NUIAOERS.....
I I 2
>( ,
] r 1 ~
D>>118 Chlozophyll a (mg/m 3 )
SNK f&S I 4 ~EANS.'rAANsfn)11 n,rloN cone = 0
, ... Ellnall.xs 0 F 00000 .
3 ~ 2610 4 ~ 0410, . 4 ~ 5290, O'i 'hr~VL'C PEAN VAR I ANCE ' COEFF ICIENl'F, YAH I AT'104 L ........,NUHHEH 3 ~ 3 '586. 0 '863 13 ~ 5161 7111217 3~ 8412 71 1221 7 4 '426 711 3217 3en920 r F 2 .3 n.365n 0 '436 . 11 '068 7r! 1 1217 3 ~ 84 72 7212? 17 ns8300 721:3217 4 '190 3 3 .
9 ~ 5654 0 '130 4 '246 7311217 .1224
~ ~ '312217 9 ~ 5304
,7 1 1 '31! 1 7 1 0 ~ 04:$ 4, I
) 4 a 27 ~ 6670 2 '103 5 '930
..74 112 1,7 27 ~ 1272,...
,7n 1221 7 29 ~ 3832 74 1321 7, 2Q 4906 0 '033;, ~ ~
0l TAOLE .OF NEANS (SORTEO)
'e SAMPLE ...,., N NEAN NVMBEA 1 o 3 '586 2 4 0 ~ .
4 '654 3 0 0 ~ 9.5654.
4 ~ 0 ~, 27 '670 0 k% ) NUN Holds ) 64 f 4 t 6AM t )44vhs
....SUOSE'T ... SAMPLE., NUMBERS.:..
?
D>>119 Chlorophy11 a (mg/m 3 )
SNK TEST 4 MEANS. TRat SFOAMAT ION COOE = 0 EHAQf4 MS 0 F 00000 3 '610 4 ~ 04 I 0 4 ~ 5290 SA hlPLE N PEAN VAftlANCE 'OEFFICIENT OF VARI ATION
.......- NUflfJEA 1, 3 3 '294 0.04 17 6 ~ 7411
? 13121? 3a1458 713221 7 ?9a6 7'I 3:12 1 7 3 '480 2 3 3 '722 0 '351 5 '477.
723121 7 3 ~ ?854
.. 7232217 -. 3'4980 7733217 3~ 4332
....,.... 3 . 3' 8 ~ 5466 0 ~ 371.7 7 '339 33121? 7 ~ 84 62 7332217 O. 958e 7 333217 0 ~ t! 350 4 3 14 F 0570 0 169 3 '893 L ......7A312l7., ... 14a5242.....
743221 7 15 ~ 5070 74 3.121? 539.8 0 ~ 19 In E AGLE OF MFANS (SORTED)
L .........., ShMPLE,............ N ....,.. HEAN NUMUEA 1 ~ 0~ 3 '?94 2 ~ 0~ 3 '722 3 ~ 0~ 8 466 4 ~ ... 0 ~...14 ~ 8570 MAXIMUM NONSI GNIF I CAN 1'ANGES SVOSET, SAHPLF .NVPBERS.,
1 1 2
3 Chlorophyll a (mgttm )
' SN~ ri:sr 4 MEANS. TRAt SFONvArlON COOE = o EHAQIW tds a.oaooo I 3 '510 3 '770 4 '270 4 '540
.SAMPLE tt NEAN VAA1ANCE COEFFLCLFNT OI= VAR 1 AT lON I
s ...... NUMQLA I 3 2 ~ 2136 0 ~ 0410 9 '1472 810121?
'81022 I 7 el03217.
2 3 2 ~ 0110 0~ 1 397 13 '980 ePOI217 8202217 "8203217 3 3 20 '556 3 '921 9 ~ 4 144 8401217 04022 17 0403217 3 1 0~ 3370 1 ~ 1430 1 0 ~ 3427 e501217 H502217 e503217 t 1 ~ 3040 I
TABLE OF MEANS (SORTED)
I .. .... 'AMPLE INURE I'IVtd D E R N NEAN Ir 0 ~ 2 ~ 2130 2 ~ 0~ 2 ~ Rl 10 4 ~ ,0 ~ 1 0 ~ 3370
~ ~ 3 ~ 0 ~ .....20 ~ 9556 0 ~ 10 '592 N AX NONS1GNIF I CANT RANGES SUOSET SAHPLE NUMBERS 1 1 ~
2
D-121 3
Chlorophyll a (mg/m )
SNK TES T 4 MEANS ~ TRANSFORMATION CODE' 0 ERROR MS 0 F 00000 3~ 1510,3 ~ 8 770 4 '270 4 '540 SAMPLE N MEAN VARI ANCF. COFFFIC LENT OF VARI ATION
~ ----.-..NUMISCR ~ ).
)
1 3 ~
6 ~ 8546 0 ~ 0270 2 '844 8111217 ~ )
8112217 8113217 2 3 6 ~ 12 )8 2 ~ 8052 27 '414 8211217
.. II2 1 i' 1 7 8213717
.3 . 3 ... 27~5536..., .. 15 ~ 51 l 5 14 '938 8411217 84 10217 8413217 3 10 ~ 2000 0 2298 4 '996 L ...B51 121 7......,.........,.:..........
8512217 0513217 4 ~ 64 34 ~
TAOLE OF MEANS (SORTED)
SAMPLE ....., .....,., N MEAN HUM(SER 2 ~ 0~ 6 '258 1 ~ 0~ 6 '546 4 ~
0~ 10 '000
~. ~ ~ 1 ' 0~ .,27+5536 4 ~ 0~ 10 '592 NAXIMUM NONSIGNIFICANT RANGES
,....... SUHSEl SAMPLE.,NUMBERS 1 2 3
~ f
~ D-122 Chlorophyll a (mg/m3 )
SNK Tf:S f b MFANS ~ TRANSFORM'AT ION CODE>> 0 EHAOH MS 0 F 00000 3~ 1510 3 ~ 0 770 4 '2'70 4 '540 ShMPLI! N MEAN VAR I ANCE COFFF I C lENT OF VARI AT ION
..N UhlOCR 1 3 ' '502 0 ~ 9 l 95 23 ~ 6753 0131217 0132217 81 33217
- I <I a )AM lid (ldI f
.0V32. r 1 023 1217 3 3 10. 6274,...0. 0227 1 ~ 4185 8331217'3322 l7 03312 I 7 4 3 13 '676 2 '655 12 '989
.... 8431217 843221 7.
043 3P17 13 '078 0 '390 6 ~ 0315 8531217.
... 85322 1.7 853,12 l 7
'0 ~ 9 355 TABLE OF MEANS ISORTED)
SAMPLE N MEAN L........ . NUMDEH ..
1 ~ 0~ 4 '502
, 2 e . . . . . .,., 0 ~ . 0650 .,
3 ~ 0~ LO ~ 6274 4 ~ 0~ L3 ~ 1676
..5 ~, . ~
.,:, 0~ 13 ~ 4078 f
MAXIMUM NUNSIGNlF ICANT RANGES SAMPLE NUMBERS 'UBSET 1 3c........5,......
2 1 2
D-123 3
Chlorophyll a (mg/m ) R .;,
SNK I f I 5 MEANS ~ TRANSFORMATION COOE = 0 Eiefeoie 3 ~ 151,0 S
M
.5 ~ 07 70
= ..... o.ooooo .
4 ~ 32 i'0 4 ~ 654 0 j
SAMPLE N MEAN VAR I ANCF COEI= F I C lENT OF VAR I AT ION
.......NuM8ER 1 3 3 ~ 7620 0 ~ 36 73 l 6 ~ 1055
,.815l21 f 8152217 8153217 2 2 4 '728 0 ~ 1652 9 '795 8251."IZ I
...82522 l 7
- 3. 3 6 '932 1.8866 19 '412
...8351217'352217 835 3217
- I 7o 9976 0 ~ 0974 3 '023 845 l 2 1 7
........ 845221 7 845321 "j
855121 7 3, 1 I ~ 8410, .. 2 ~,7953 14 ~ 1198 855221 7
....,85532 1 7.
II 1620 IAULE OF'eLANS I SOfe TED )
SAM r~Lfe N PEAN NUMBER.
2
.3 1
~
~
0~
oa 0 ~ ..
3~7620 4a0728 6 e.9932 4 ~ Oo 7 '976 5 ~ 0 ~ 11 ~ 8410
...h'hX I If'UI'Ib I Gt'I I I" I ChN I NUHIIf'II' lth14<if,i'UIIQI.'
5AMI~LI!
4
~ t APPENDIX E MEAN, VARIANCE, AND COEFFICIENT OF VARIATION AMONG ZOOPLANKTON CONCENTRATIONS, AND RESULTS OF APPLICATION OF THE STUDENT-NEWMAN-KEULS MULTIPLE RANGE TEST TO THESE DATA
- Explanation of sample code used in Appendix E:
Example: sample 8 1101185 1 1 0 1 18 5 a b c d e f a >> the first number refers to the sampling location; numbers 1 and 3 are upstream of BFNP, numbers 2 and 4 are opposite the intake.
b - the second number refers to the boat collecting the sample (See Figure 4).
c - the third number is a placeholder for computer processing.
d - the fourth number refers to the replicate.
e - the fifth and sixth numbers refer to the day of the month sampling took place.
f the seventh number refers to the month of sample collection.
Sample 1101185 was collected (a) upstream of BFNP by (b) boat 0 '1, (c) not applicable, and was the (d) first replicate on the (e) 18th day of (f) May.
Interpretation of the Student-Newman-Keuls Test The input parameters are reproduced in the output, and a table of sample means sorted by ascending magnitude is also produced. The numeri- 'N cal identification of the means is assigned automatically by the program corresponding to the order in which the means are entered into the computer. Following this are given the maximum non-significant range of means. These subsets are sequentially numbered and c
list the identi-fying numbers of the two means constituting the end points of the range.
Thus, if the numbers listed under subset, sample, and numbers are respectively 1, 1, and 4, the subset considered is subset 1 and the range of non-significant differences is bounded by means 1 and 4.
(after Sokal and Rohlf, 1969, p. 689)
GNK TC S 1 4 hlF. A 45 ~ TRANSFOAh5AT I ON CODF = 0 tANOn hlS n.noOOO 2 '900 '5 ~
64 90 , 4 ~ 0460 GA h5rcLLc MCAQ VAllIANCE COFFF IC ICNT OF VARIATION NL)thill-IP 4040 '500 46 '843 llll185 1
1121 b5 I 5 7 a 9
F
'011 12 1131 185 1141 185 10 '404
~
1151 1 8'0 5 ~ 83 2 cj 17 '700 2boo'374 28 '696 1211 105 1 l ~ 54 I?.? I 185 13 34 1231 185 19 F 00 1241 105 2(~ o 55 1?51 105 21 ~ 62 3 c3 I9~ 44?O 41 m 1772 33 '056 1.51 1 I 0c> 25< ~ 06 I lr' I 3 ~ ilfc I 5 ll l c5'> I 5 ~ 4 I l,l4 l l cc c r',' r' 5 1 5'i 1 10) 10 WHO l
l 5i ? 7 ~,3'z8l5 1.79 ~ 6666 48 ~ 9947 1411105 28 49 1421105 37 ~ 7.'3 14.31 105 15 ~ 20 1 44 1 1 05 ~
4 r2 o 15 55 1451105 12 49 6'H78 TAULF. flF ill. ANS ( SOB TED )
SAMPLE, N hlF AN NUMHE ll 04 7 ~ 4040 I
3 4
~
~
0~
0 Oe
~, 17~7700 1 Qo 4420 27 '580 I
I
- , MAX IMUM NQNS I GN IF; ICANI'ANc F'5 SUP.GE T SAMVLL NUMr55-'AS l 1 4
SNV, Tf:Sr tlf- l 'f."- 1~t ANSFOA>AT I ON CODf: =, 0 t..c AOR hh 5 re 00000
,I ~ ') )80 4 ~ 2320 r, ~ ~1500 SAHPl I- N
.S ~ '>7 >t 0 V aft I ANCt. COEFF I C I CN I'F YAH I ATION NIfMOEfI I 5 8>>?? OO f .n546 30 '075
'111185 212ILGS 5 Ines 2131185 11 ~ 10
.? 141 185 9' 19
? 151185 9 ~ 7?
2 5 15>>9220 19>>')7n3 ,28 '733
?211185 95
?221185 21>>42 2231185 13 NOH 'I = ~
22n I Los 2?51105 labs 3 5 21 ~ 0420 I I 0 ~ 34<)7 49 ~ 9228 231 1185 ?. <) ~ 58 2'321185 3 I ~ .S~)
?33L IRS 2D ~ ')2 234 1185 10 ~ I9
?351185 I I>> I 3 n 5 2n.n >00 ?43 ~ 5039 63 ~ 7183 I ?41 118$
? 4 2 I I f'.
2 4 3 I I 85 5:S 44 4
~
7?
"f 0 0?.
I 2441185, ?2 ~ 6')
2451105 14 ~ lb 5
34 F 0580 ,306 '915 . 51 F 4283 251 1195 10 ~ 20
? 5'2 I I 8 5 2 fl ~ 2')
2531105 34>>78 254 I I 85 38 ~ 35 2551105 58>>67 lsd'220 I 37 ~ 4158 TABLL OF f4F AN 8 ( SOATCD )
SAMPLL'UMOEA PL AAN I
I . I>> 0 ~ f3 ~ 2200 2 ~ 0>>
3 ~ 0 ~ 21 '420 4 ~ ,0 ?4>> 4 %of)
)~ n. sn.o58o wax lfiuf~ NONSI I'Nrf: IcaNT nat~GLS SUISSf T SAHIPLL NUMIIf'AS l I 5
SNK It ST 4 a!t.h I'i T>tARSF()IRMhl ION CODI= = 0 I=rrHO!t MS 0 ~ 00000 IDENT
! 2 ~ 99(50 .I.t 4<to on Oo S h MI 'LF. N Mf. AN VATt I ANCI= COLFF I C Ot- VAR I AT ION I . N.UMrkt=P 4
1 5 I ~ 1420 Oa I 769 36 o 831 t3 3111185 I ~ 02 3121185 0 ~ 9/
31.31 I H5 1002
.31 4 I I t35 F 88 3151 I 85 0 ~ 82 4 .3.8n io 9 ~ 3514 79 ~ 531 8 r
3211185 7 ~ 90
.3221 I 85 0 ~ 8.3 3231 105, 4 ~ 32 3251IUS 2 ~ '5 3 3 4 2' I 200 I ~ A145 63 ~ 5J99
'311185 23 3.3 3 I 334 1 (3 5 05 1 ~
0 '7 3 ~ 'I '3 11 5 S!i I 1 85 2 ~ 3!3 5i (i,'34() 3.'5l 5~6855 6@ ~ (3292
- In I I I (35 9'5a I33 342 I l)>i5 2 o')4
- 34 j I 185 93 ~ In 34411Ub I t'i9 ~ 72 3451185 3'.i ~ 94 949 ' 102 1 A(3LK OF MCAN5 ( . Oft TI='O )
',ihMt it I'. tt Mf: At'I It(IMIII-t I i 0 ~ . I ~ 1420 0 ~ 2 ~ I 200 2
4
~
~
0 0
~
~ '333~8450~ 6340 MAX I MUM NON S I GN It- I C AN T 'JAN('i S SUM St.". T SAMP( L N(ttnOI..RS I 1
SNK Tl'ST MtANS ~ TRANSFORMATION CADE 0 E tt!t())t tf 5 0 ~ 00000 2 ~ ')'iOO 3 r>> 7,30 <)500 4 ~ 2.)20
) bAb!PLL'. N Ml-. A~) VAR I ANCE COFFF I C lENT QF VAA I AT ION NUMB)c.:A , I I
4 I I ) I u!>>
Ij I'4 ~ 7,i <<0 I t.>> 0'i
~ i>>44 j r'5 ~ 9'302 41 2.11 05 I 3 ~ 7tl 41JL Ie~ 8 ~ f> I) 4 )4L LU!i 4 I;>> I I c)5 ld>>77'4 I I>> ~ '>>0 c; 2Ii ~ 2 440 190 F145 56 ~ 9111
'7
<<2 4211185 12 42<<r!' 1 t)!i 4',>>i) I I f)'.i Ill
)I>>
22
~ Ow 4,'!4 I ) il'i )') ~ 7'I 4>>! ' I I IJ'i I!)>> Ob
'>> ~ l)240 48 61 be 44.O633 >ti 4311185 11 ~ 05 L 4.'32 I I 8.>> f)>> 38r rr..-
43') Lei C
13 ~ 24 4341 )8 > 2 ) ~ .)6 I '
4351 I c3'> 2 I ~ 0')
4 5 46 '.>>260 I 4 4>> t)2 06 25 8654 44LLLU5 42 ~ 93 442 I 185 t>>5 ~ 91 nn 3I L85 3 f ~ .$ 9 II44) I <<)5 :I 6 ~ 68 4451 I t)5 49 ~ 72 ~ '
,5, 8551 ll1824759 451 II '94I) 1950 1602 39 6145
"<<3'P.
7 rt'h I 4521 I t>>5 IIr ~
I""'54>>85tl5 112 '3 45.3 I I 71 ~ 10
"<<.Igir ~
I 4551 I 8!i 70>>57
~
, 469 69)2 NV TAHLF Ot- tl'- AN 5 ( SOB TE )i )
SAMl>>LE N MFA N.
f NUMHE A I
I ~. 0 ~ 14 '580 3~ 0 ~ 15 '240 2~ 0>> 24 ':)40 4 ~ n. 46 '>>260
'i ~ 0>> I I I ~ 475<<)
ttI XX I MUM NON' "~'tlF I CAN) )CANI L'S SUII Sl.i T .'>>hM)I).I>> IuUI'II-Ite I
I t I
rt tI<<7VP I
~ hl 'll '
I ~,'
'I
~
Ssll' t: S l 4 Mt h sS ~ T((ANSF()QMA T l ON COOQ = 0 s"
i MP(ls( MS 0 F 00()00
~ r c? ~ ') s) il\) 3 ~ ('>n 90 4 ~ 0 i 60 SA M('>LC N ML>hN V nn I ANC(; COLFF I C I ENT OF V ARI ATION I
NUMBLjA r
>S sh)P 1 5 112 ~ 9120'1361 a2695 94 '003
~.. 1101 76 42 ~ 83 .
- 4>p 1102 76 65a88 CI>h ~
1 103 76 45 F 19 1 104 f6 296 ASS
'l 1 105 /6 114<<08 ts'" 4' 5 ?8e il')20 4 5 ~ '3950 ,23 ~ 3.199,
's, g L201 76 37 ~ ns) 1202 76 1 sg ~ 2 1203 76 26<<40,
<<g(gh P>jl S 1204 76 31 ~ 61 1205 76 29 ~ 73 I,
4 7(3 ~ 3549 3?15~0767 72 '651 I30) 76 1 0's ~ '.i 1
) (S)r> /js ln 1 e 7 1 l ((l' /(s s ( ~ s)l 1 (07 F() l 4+ 1 7 1
4 4 Oi?
1403 76 ln04 76 1
r 4 0".s 76 76
'0 55 << 9120 50 ~ 70 nn.ln
.'s 's ~
~ 45 51
~ 96 ~ 3426 17 '551 h
1406 76 sn.76, 3710 483(i gj h, F TAOLC OF Mf;ANS l SOB TLD )
SAMPL(=" N MFAN
'I NUM((s= ('(
2~ 0~ ? () ~ 8920 4<< 0~ 55 ~ 9120 30 0~ 78 ~ 3549
), fp.II 1 ~ 0~ 1 12 ~ 9120 II r~
h "*
MAX 1 MUM NUNS 1 GNL(-'CAN T ()A RGF S bULISf!T SAMPL(. NUMBCAS 1 2 1 h I ~
'L O'IK 1LS II "O'I.;, T:i AN" F I lf4hlAT AN 1 CfIDt.. = 0 "i'inh 1':
1S 0 F 00000 2o 0:i00 3 ~ ') 7c30 3 ~ ~)500 4 ~ 2320 SAhIPLE N Mt: AN VAtt I ANCF COGFF I C IDENT OF VARIATION l
NUMOI=A 6 i ~ TIIZO 1 000 ~ 6') 04 4do0807 2101 76 101 F 58 2104 76 6P.O4 2'105 76 15 ~ 74 2106, 76 7@~32 2107 76 70~23 5'i fi380
~ 333m 0068 32 '986 2202 16 62 ~ 96 220.I 76 56 ~ 7?,
2204 76, 7?+43 220~>
? P.06 76 76 24 '3 3
2301 1 83a9800
- 83. 98 0 F 0000 '2 '986 76 4 5 P O O.O<<60 SA hIf>LI= N MEAN VAR I ANCF. COC.FF I C IENT OF VARI ATION
[ NUhI8 C.A 1 5 5<< ~ 3t300 ?'>7 ~ >91 I 2') ~ 5139 3101 76 48 ~ 05 31 03 76 3> ~ 7>
3104 76 46e 09
.'3 1,05 76 67~71 3106 76 74 30 2 5 '>5 ~ 8800. 490 '112. 39~ 6340 3201 76 2$ ~ 93
, 3202 76 45o 65>
r ..3203 '/6, 80 o 22 320<< 76 58 ~ 28 3205 76 71 ~ 32 r 4 5 37 '540 15 '1370 1 004828 330 1 76 3~> ~ 4<<
l '3303 /6 33.84
.3 J04 76 <<3 ~ bJ
~
3305 76 37 ~ 33
.3 306 76 3 ~ ~ 03 4 "5 '3:) ~ 8060 21 '413 Ill 6597
....,. 3401 76 .....35 37.... ~
3402 76 42 ~ 55 3403 76 46 ~ 50
':3404 76., 38 ~ 21,
~
~r 34 05 /6 36 ~ 40 19 6 ~ 1 829 I
I AII) I I )F Hl- gf'J ~ ( /I III f j- I '
5 n tlI'>El. MF. AN NUMI>E8 3 % 0 ~ 37 '540 4;......... 0, 39,Soep 54 ~ 3800 1 ~ 0 ~,
2 + O. SS.O800 r
I MAXIMUM NON'(iN IF I,CANT'tlAhlGES SUI3Sf T SAMPLE NUhIUL>AS 1 3 2
~ ~
'I I I F" I ~
Ie f I!F nl'I!if.IIAfih,f 10N CODi = 0 I: I> jhf'Iif 0 e,OOOOI) 2 o')500 e >780 3 noes 3 ~ c) "18f) 4 ~ 23? 0 c5A IH(LQ N II!E'N VAR I ANCC COP F F I C IFNr OF VAR I AT ION NUMBFR ~ I ~
1 5 5520 1 24 ~ 0?.88 22 '750 41OI 76 ,,43 e,f)9 4103 76 61 ~ 82 41O4 76 60 ~ 09 4)g'> /6 35 ~ 7 1 410 ( 'le 46~ 2ll I
-" 2 q201 5
rf*
53 ~ 1440 40.01 2l6~2111 2,
'/ ~ 6664 Il20 3 76 4;I ~ 61 n ppn 76 59+ fI0 4 20'"I /6 /II 06 4206 76 45 ~ 50 3 5 32 ~ 6 7f)0 101 ~ 1674 30a7797 4 30c! 76 .30. 66 4304 /6 35 ~ 2tI n 105 76 2 ;1 ~ 1 I) 4 IOII 76 nv.e3 n 307 76 25e 66 75.5540 Iln2.40ia 44 ~ 735,5 44,01 nno'e 76 ., 05 ~ 00,,
ri7 4403 76 124 F 08 4 4.04 76 Oa 440576 34 ~ 21 10 B ~ I)5 39 F42>5006 I 'I ~ P9M (fp lif71 ~l If f)on /I3 I/I)fuff nc'05 76. 100 ~ ?6 4506 76 85 ~ 61 4507- 76 1 olob2
, 365 ~ ?795 TArfLI." III- )fr=AN~ (Snf<rLI))
f"'UN8CR 5A)1f LI= N, Mf AN ~ '*
3 ~ 0~ ., 32 ~ 6 780 I~ 0 ~, 4 I) 5520 2o 0~ 53 1440 4 ~ 0~ 75 ~ 554 0 5~ 0 10)1 9539 NAX I I <<TRANSFOAMA T I ON CQUf:. = 0 t:l(AOR MS 0 ~ 00000 r, 2 <<9<)80 3 ~ 6490 n.oneo SAMPLf N h>F.. AN VAR I ANCF. COEFF I C I EN T OF V AA I AT I OH I
NUMFSFF) 1 3 Ii >> ? Ir Ff 0 81 ~ 0797 25>>5459 1101 2ff ~ 12 I 102 ue 41 IO 1103 86 46>> 64 1104 06 '4 ~ 79 1105 8e 3'.i>> 59 43 8960 . 12() 9201 2b>>0509 1?01 86 27 ~ 4 1 202 06 1'7>>
0?
1203 86 ni).5>)
1204 06 51 ~ 95 I?06 (36 52 ~ 71 485 '038 '750 h
.'3 5 5 I ~ 7740 42
.103 06 >59 ~ 61 304 F36 59 ~ 71
.505 (36 3>'> 07 30(> 86 c)7 ~ 1 '3 307 (3() 3()>>,3 I 4 - 5 29'>>?OFIO 44>>5638 22 '554 nol ae,,29>>o9 1 402 86 25 ~ 46 403 86 59 ~ 76 1
404 405 86..
06
.21 29
'6
'7 r If)d>>1119 I
TAIILF. (If'f'Nb I b<).f Tt fr )
'gA Ml 'I. I ~
I Pf.hfl NUMI)I'l 4 ~ 0~ 29 ~ 2080 I>> 0~ 35 '480 2>> 0~ 43 '960 3 ~ 0~ 51 ~ 7740 MAX IMUM, NUNS I ('NIP f CANT PAN( I..S GUOSf> T SAMPLL) f)UQfbf=.AS 1 J
S NK 3'h S T 5 tel: h'I, Tl;ANSFORtr AT I DN COOI-. 0
- l. RROR MS = 0 ~ 00000 r ~ <5500 3 5700 '3 ')5t50* 4 ~ 232n
(
SARI>LL N I'LA<4 'hR l ANCLr COEFF IC ?ENT OF VAR l AT ION N1JPI31:H ~ --- I I
1 5 71 0 '<)') 225.;inn 1 21 ~ 0475 f101, U6 8<< ~ 2.3 2103 86 50 ~ 1 <7 2104 86 t50o 15 2105 86 80m '32 2107 86 Gn.?F 5 5 i! ~ 0<<4 0 1 31 e?<J22 19 ~ 472.3 220/.'?.
86 66m 37 0;3 t36 6 ) ~ 94 220<< 86 69%03 2205 86 4." ~ 4 0
?i 06 86 4<< ~ 50 I
3 2 301 230? '6 86 5 43 '500 33 'l 01 ~ Ol 126 ~ 3478 23<' 8699 2304 8e 4<< ~ 9R 2305 AG a<< 05 2306 86 34 ~ 10 4 ?'J 71J30 1 10 ~ 5103 35 ~ 373R 2401 u6 ~ 3<5 240" 86 22 ~ 05 2403 86 ? r<.01 2<<04 d6 ,;30 ~ 50 2405 66 47 ~ 65 5 5 79 ~ 1640 234 '375 19 ~ 3331 2!302 06 6 7 i 95 503 86 8no75 2<04 t36, 67 ~ 49 2505 86 1 04 ~ 74 2506 86 74 F 89 165i178<<
TAOLC. OF tlf:ANS ( Stilt Tf..l) )
SANPLt- N Ht AN NUN!JI=IC
- 4. n. 29 ~ 7180 3 ~ Oa 43 ~ 4500 2o n ~ '3H ~ R<< 4 n 0 ~ 7 1 ~ n?9'J 5 Oo 79 1640 NAX 1 NLJM N<)hlS 1 fiN l F I CANT 1ANOl 5 SU< I 5f." T jhtnl'<L 8 45J %<3l 0 1 <<
SNK. TL 5 T 4 Ml.h MS ~ TRANSFOHMh T 1 ON COOL. 0 I-.. Il 8 ()R,M S O.OOOOO 2 + 9~)00 3 ~ 6490 One 0 ShMPLF N MF.. AN VAR I ANCF. COFFF I C I EN f OF VAelnrrOA NUMFI5A 1 5 35 ~ 24 FIO 81 ~ 0797 25 5459 1101, 06 . 2,8 ~ 12 I 102 Ue 4 1 ~ 10 1103 86 46 ~ 64 llO4 06 24 ~ 79 1105 oe 35 ~ 59 Sled i? 43 '96i) 120 '201 ?bi0509 1201 86 27 ~ 41 1 202 06 37 ~ 02 1203 06 49 ~ 59 l204 06 95 1?06 u6 52 ~ 71 4 :3 5 5I ~ 7740 485 '038 42 '750 r I .In 3 l)6 59 ~ 61 13() 4 86 39 ~ 71 1305 06 36 ~ 07 1 30(> Ue 07 o 1'3 1.307 06 36+ '.3 I 4 ~ 5 ~ 2<)'e? 080 4 no bf>38 22 '554 I ~iol 86 29+ 09 1402 86 25i46 1403 86 .59 /6
'1404
'""'140- '06 .86, 21 '6
~
29 ~ 77 f
108 F 1119 TAIILF I1I Mf'AN5 ( bi)H TI" s> )
'a h MI '. I 'I )>ih) I NI.) MIJ I'- I I 4 Oo 29 ~ 2080 1 ~ 0 ~ 35 ~ 2400.
20 0~ 430 8960 3~ Oo 51 ~ 7740 I
MAX I MUM NUNS I ('N IF I CANT PAN( C 5 SUB SF. T SAMPLE IIUMRFAS 1 n .3
tl l
SraK l'L~ T Mt h't'I ~ Tl)ANSFORMAT I ON COOL' 0 EH ftOH MS 0 ~ 00000
,I I ? 99QP 3.C4>>0 4 ~ 04 fi 0 SAMI)Lf- N Mf.'Att V AA I ANCF COLl" f' C IFNT'F VAR l AT IOt4 I . tlUMf>CA 1 5 ft ~ 11 40 14 n ~ 4330 528O 3I,O1 H6 4 7 ~ t)rt 310? 06 39m 09 3J 03 86 45 ~ 05 31n5 86 41 ~ 10 3 l 06 86' 68 55 8'i hhc
~ 0 '>Oh t 7nh ~~ P(i q P 9'jO
') I ~ /fr ftr, rio, 12 r .120 y Of) ft 1 ~ 94 320m tsb 90 ~ 91 3207 dt) 1-14. 48 r
t)90 '364 '429
~ ~ ~ ~ ~
3 5 48 ~ 35bO ,54 3 301 86 31~27 3303 86 59 ~ 24 3304 86 35 ~ 51 3 306 of.i 89 ~ 53
'6
.3307 Rt) 26~ 13 5 3 ~ I 060 287 ~ 2495 31 ~ 9144 I .3401 86 ~ 21 34 0? ft6 63 ~ 05 3403 Ab 50 F 99
,Bn 04 86 71 0?rr
.in05 86 sn.26 405 '45t)
L..
TAULl'; Ol- thf'.AW5 ( SOI'f U)
SAMPLF N MF. AN
.ttUWuEq I
Ie 0 ~ 48 ~ 3140 I
I,....... 30 ....n. 48~3560 0~ 53.1nbo 2 0 0~ 85 ~ 4420
,. MAX IMUr4 riU VS I GNIf. I CAI4T tiArt(.t S SU(<SC 1 SAMPLE'UtlHt:t)S l 1 ?
'I)( I '~ I h' ' I ) t 4 'I '(I 'it)t~ A I I 11' (. ( I [) I t ))tet I)> t)I', , t)(ttt tt ))
,', 'I t(((
~ ) << ~
) )~
~
r
) '>>)V I I( I ll( I
<<g A Ml('l.l. 1<<) VI-n I V hl) I ANCI; CGLFI 1C 1E N I ()F VAR f AT 't OIV NUMI<I-. H I 13 5 3 ~ 4 <<)60 1 2 () a (> 6 .35 21 a 0048 4 1 oa 8() 4 l) ~ Q6 4104 86 6n. 19 41OS 86 65 ~ 12 41 06 86 3(3~ 39 4307 (3e . 50 ~ 72 2 cL> r6. r579 1 c) 9 a,3 )36 7 . ...l. 8 ~ 3.96.0..
4201 06 rS ~ 59 4203 06 64 ~ 91
- 42. 04, 86, 1 Ot) ~ 71 420'3 86 7 4 ~ *.'3 n?or u6 (') 7 ~ 9ri 5 74 ~ 7?20 541 ~ 2100 31 ~ 1340 4 Ioc> 86 t> 0 ~ .5 1 '9 4303 96 ~ 37 4 30.5 tlt> '38 ~ c).3 4 '306 86 t>') ~ 62 4 .307 (36 115+38, 4 5 lO24?59 64 I 5276 24 '285 440 1 (36, 134 83 4)t 0?. H(> I 1 r ~ 8')
440.3 (36 7I.O3 44 04 86. HS ~ J7 4405 86 103 ~ 01 5 5, 115a4359, 37(> ~ 8972 , 16 ~ 8208 )
4501 86. 105 49
'4 502 86 1 2'5 ~ OS
,4)0.3.,8.6 .. ...1 4.c? ~ 67,.
4 SO4 86 9? 2C 4505 86 110 ~ 81 3 ?7<<i 0566 .
TABLE OF MEANS (SOATCO)
SAMPLI: N c(IF AN I NUtnil 6 I(
I I
1 ~ oo 53 ~ 4 <60 3 0 0 ~ 74 ~ 7 22 0
? ~ n. 7t> ~ 7579
- 4. 0 ~ 1 02 ~ 4259 Se 0 ~ 1 I S ~ 4 159 MAX 1 MLJM NONS I G 111 I Ch)IT I)AN((l'5 SV!'>5": t GhMVLE '(I)MOi:P 5 I
I l cg
'~"t)<.
t-:)tAU)t M..
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.5 ~ 0 ~ I > ~ /i 780 2~ () ~ ? f) o 'i I t' I~ n. ')
22 o /) l3 0 5~ Oo '53 ~ 2800 MAX I MUM:I(lhl! I < '0 IF I CAN T RANC I:5 SU13SI:" I'hhlh>LL> .uUMIIF RS I /t J
SNK TI=ST Mt a I S '. rit AN SF ORVA T I ON CODE = 0 f-'iii(GR MS 0 ~ 00000 9980 64'>O 4 0460 SAMI>LE N MCAN, VAR lhNCF CtiEFFICLENT OF VhRlATlON NUMOI:P 1 27~ 9400 1 fl4 ~ 2310 4'790 5101217, 29 ~ 73 5102217 17 ~ 71 5103217 50;en 5104217 '20 95 5105217 20 ~ 47 2 5 21 ~ 0900 7 ~ ~.'34 0 1,3 ~ 0.155 .
520 1217 1H ~ 65
'520?2 1 7 ~ 22o 86 5203217 24 ~ 04 5204217 10.49 5205217 20 ~ 61 29 '180 46 '745 22 '135 I
3 5
~ 5301217 5302217 27 '9 31 ~ 83 5305?17 40. tn
'>3042t7 27m 50 530'>217 ?1 ~ 73 4 5 3' 954 0 457 ~ 1460 Gtet689 l 540121 7 17 ~ 90 54 022 1'7 () 0 ~ 09 5403217 47+43 5404217 41 ~ 12 5405217 0 ~ 33 173 '968 TABLE OF MEANS ( SOIR TLI) )
SAMPLE MEAN
,, NUMBER 2 ~ 0~ 21 '900 1 ~ 0~ 27 '400 3 ~ 0~ ?9 '180 Oo 34 '540 MAX I HUM N;III.'l l ~il I f 1 CAII T Rh I+ii-.,j SUI) SI- T SAMIil c .iIIIMfll i'>'i 1 ?
5'.4K I< iT MLAN. ~ 1RA'.45F (l))HhT IA)4 CQO)= = P E>if<UR M> 0 F 00000 2 ~ 9r) 00 .3i .i730 3 ~ 95AO 4 ~ 232p Shhlf)LLJ '
MEA'4 VA>4 1 A)4CF COEFF I C IFNT OF VARIATION NUM~>ER 1 r) ?a.n J Ills 96 45 ~ 12 6101217 2(o47 f)L08217 2'>~ L9 610 3217 39 ~ 02 fil04217 9 <<5 6 I 0!'> 2 1 7 2LoL?
6201217 30e63 3n.05 54 o 4'i 24 '9 620?217 3?~24 620321 7 6i 0421?
42 '1 2 3 ~ 'i.'3 6i.'Pri21 7 2'>o 1 i!
3 5 . n.67 Lf rip 19>>66 6301217 2 > 45 630i 21 7 2 I:34 630 li". 1,7 17 ~ 13 F> 5042 1 7 2 3+50 63052 I 7 1:i ~ 94 20+ 20 L94 ~ 63 69 F 05 640121 7 9o 30 6402? 17 '1 L ~ 5?
"6<<0 3217 42 fch (1404i! 1 7 2<< ~ 50 6405?17 1 >". ~ 70 j>>'.) } >!,} I(
2t ~ >.'<< d.'5 }
f3+ 3)tff
. '>'3 l
6'50.! 2 1?
~
~> ~ r ~
>3 6:)0321 7 20oaD 6 J04217 '5 0 ~ >2 6ri0521 7 ?.9 ~ a 1 130 ~ 7000 TAf3LL OF MEAf46 ( SOR TCO )
SA MfJLF. N MCAN NUMlcf='I<
4 ~ Oi 20 ~ 2040
'3 ~ 0 ~ c! 0 ~ GF>Hff 1 ~ 0~ 2a 4>ioo 5 0 26 ~ (J44 0 2 ~ 0~ .30 ~ 6 300
SNK Ts"'5 I TAAhISFOA~ATII)hI CUIiC = n I- ieA()A MS 0 F 00000 2 '9RO 3 ~ 64 90 n.0460 SA hIPLL' >F AI I VAR I ANCF. COFFF IC IEN I OF VAA I ATlON NUhIUI':Ie I 5 21. 0420 19 '952 ?I F 1443 7101?17 2 I i 06 7102217 I r>
7103217 28 ~ 45 ZInn217 19 ~ 5w 71 0',)? I 7 19 ~ 57 I) I 6 e ')720 ne,1 464 I I p 997!)
7? 0121 7 13~87 72022 I 7 17aR3
, 7203217 I 8 ~ 06 7?04217 I A ~ 2A 7205)21 7 16 ~ 01 3 l6 NIv0
~ 5+3933 I 4 ~ 2354 73012 7 I, 13~91 '
730221 7 ) ~ 3'e 7.1032 I r 20 ~ Ih Z:f0421 '7 16~14 7:IO")2 I 7 I )~97 n 5 12 '460 0 ~ 2179 23+2195 740121 7 ..... 1.3 ~ 30 740221 7 1? ~ 66 740 521 7 )I ~ 39 Tn 04?. I7 11 ~ IR 740")2 l 7 9 ~ 5082 16 '0 t I'tllLr.-. I.If= ~1Lr','l.; I f) I)
~
))
'a MVLI-- hiCA)e NUh)ElF) fe 4 ~ 0~ 12 '460 0~ ., 16 ~ 3140...
2 ~ 0~ 16eI) 720 I~ Oa ~ '21 ~ 0420
(
I L. NIAX lhlIIQ NONSlGNIF ICANT ieAIQGCS "UOSET SARI"LK NUhIOI=A I 4 . I
'; ~v rt; I trl h 4' ) I i) hti'at (t>><n f I tlti Citf)t. = 0 I itt)I I' <I ~ .l (1 tt 0 <)
tin<<'.I'. P
? ~ 'I')1) tt I~ > /'It) I~ 'I')tt(t 4 ~ ?.33'0 f)n VI'Lf) V t~'.;n I vn CAI=FI-IC1LNT nF vnRIAT ION Nl/h>i I I: ft I I 4 ~ 3') )30 ~ t. I 46 ~ 4l tii') I r'I / .'4 ~ 34 it I <t, ~ I / / ~ ~
'll>> I,'I/ ) ~ <o P ~
~
>1104c' / 10 ~ I <<
8 I 0'ia)l 7 .9. nf 8201217 5 2 7 ~ ti /
24 ~ 25 3D ~ 06 21 '5 G?02217 19 ~ 70 820:32 I 7 A204217 34
.32
'5
~ O'I 8205?17 ' II ~ 64 f330121 7 26 ~ 16 21 ~ 53 55+ 52 28 '8 8308217 I ') /6 t3.30 321 7 8~ t3,3
~S.COn 21 r ?? ~ >>i3 03052 I 7 3R ~ 02 4 I /) ~ t)5) 16 ~ 20 23 ~ 94
~<>
5nhif)LI'. t.if:- AV NUMt~h >t 0 ~ ~ 85? 0 0 ~ I< ~ 3480
'3 ~ 2~) ~ I 640
~ 0 0~ 27 ~ H<rfr0 5 0~ .31 ~ I AI30
~ aa V ~ ~~ ~ ~ ~ ~ ~ Sna ~ r ~ w ~ ~ ~ ~ n ~ ~ ~ ~ ~ ~
APPENDIX F CONCENTRATIONS OF CHLOROPHYLLS a, b, AND c; RAW DATA
- Explanation of sample code used in Appendix F:
Example: sample 8 1101185 1 1 0 1 18 5 a b c d e f a the first number refers to the sampling location; numbers 1 and 3 are upstream of BFNP, numbers 2 and 4 are opposite the intake.
b the second number refers to the boat collecting the sample (See Figure 4).
c the third number refers to the depth (in meters) sampled.
d the fourth number refers to the replicate.
e the fifth and sixth numbers refer to the day of the month sampling took place.
f- the seventh number refers to the month of sample collection.
I Sample 1101185 was collected (a} upstream of BFNP by (b) boat 8 1 from a (c) depth of 0 m, (d) first replicate, on the (e) 18th day of (f) May.
II 1
- e. 4 t<<
I'
~\
Q Ct(L()ROPIIYLL DATA ~
..ALI..VALI). 5. ARE .IN..MILI l.GRAMS /CUOI C M(=TER SAMPLE ". 'HLOROPHYLL A C HLOROPHYLL 0 CHLOROP IDYLL 3 " ' IIOIIE$5 '
3 4224 14~6076 72 '404 C
I
.5..1 Oc'.1 85....13,U~2044 t)'5
~ .4766...
0 ~ 0000 4.4490 I I0 $ 1 F 0000 4 ~ 44'> I 9
(II)
~
11111E$
I I I? I dr>
I I I 3 I 0 I I:.31 I (35:55, 5i 6 ~ 92 4
<) ~
~ (3
~
E52 I 0$
I ($ 7?.
142(3 0 ~ 0000 0 0000 F
0 F 0000 0 ~ 0000 0 0000 0
?
0 I
3 ~
~
F
~
~ I I 75 112')
5)0.31 0000 0000 I I 3.51 $ 5 2 ~ 79<36 000000 0.20 )4 Q =
11511($ 5 I ~ 050() 0~0000 I ~ 32<$ 9 I 15)r. I <55 2.4444 0 ~ 0000 0.0000
'I 15.31 05 2 ~ 7996 0 0000 1.<)260 Q . 12011<<5 -
7 ~ 50'00 0 ~ 0000 I ~ ')? 37 1?02 I U5 I 20'I l t(5
., 4 ~ 5)t.>6 0 ~ 0000 I ~ 0') 65
~ 5 14? 0 0000 (I ~ ($ 5 't I Q I? I I l<t!> 6 ~ <).$ 1 2 0 F 0000 2 ~ 7441 I? I? I t(a () ~ ')252 0 0000 0 OOOO 121 51 ($ 5> 5 ~ >315(3 0 0000 F I . 170<)
9 I?:$ 2 I U:) :5 ~ 142(3 0 0000 0 0000 5.. '......4
~
...I 2 3.'5 I T$ ~ .I 9.$ 4 0 ~ 0000 0.0000 125IIU5) 0 F 0000 0.0000 0.0000 9 1?5Z I t35
<<5 0 ~ '34 92 Oe0000 0.0000 I 2~) 51 I ~ '.3~)6)3,. 0.0()00 0~0000 I 301 1(35> I 0 ~ <)502 0~0000 I ~ 04 70 I J021<3 "i 9.5922 0 F 0000 0.00OO
$ 30 31>'.;- I Z ~ $ )6<.'<! 0.0(tOO tt 000(l
~
I I I I I ))') I,.! <
tt <<. <) <e ~ << >t >I f) ' <l > ~ t I:jl I I I <' <<<3) I? ~ <>(I 3<< 0 ~ 000(t 2 ~ )'t tt(t I 3 I ,3 I $.3'i I I ~ <7$ 60 0 F 0000 I s7 $ 16 1.$ 3? I U5 2 ..4444 0 ~ 0000 0 ~ 0000
,e I '3.3 3105 I 3'> I I <55....
2 0~
'444 0000 0.0000 0.0000 Oa0000 0 ~ 0000 I '$52 I t35 I 7490
~ 0 F 0000 0 7071 1.3'.> $ 1)3 > 0 ~ 0000 0 0000 0.0000 140110') 14.:5( 04 0 F 0000 0 '.i /03 I 14021<<5 14) 422. 'O.OOOO 0 6120 I40 I I <'5 5 I 3 3090 0 ~ 0000 0 0000 411105'?00496
' tl 0 ~ 0000
~
'? <<792 14 I > 30 6070 ~ 0.0000 7 c'r."')0 Q 141 JI U!3 '2+6760 0 ~ 0000 <) ~
o
?2F)2 I t< 5 I I >3'i 7 I <<7 0
~ 0 0000 Oa06'30 14 52 I t<'> 3. >34 12 0 ~ 000(t 0.0000 6 I 4 J 5 I tl.'> '.i ~ 9:$ 64 0 0000 0.0000
... 144 I I (35 I 4 4 r. I t35
... I ~ 04 76 020 0 0000 0 ~ 0000 0 F 0000
.'5 ~ 4 O.0000 I
F-2 C>(LO<<t.)> >~VL ~
OATh ht L V<<LIJF..'5 h >l t": I N . M I L L'I C~ 0 AM5/CUIII (. WC TE>t SAR(>LL. CI ILOAOPIIYLL A CIILO(t()>>1(YLL C HLflf(C)>>tI YLI I <<<<:3105 3o 7? 36 0 ~ 0000 3 ~ 7~)?Q 7101 I n'i I I ~ <) I '30 0 ~ 000(> >) o 10'io
'? I Oa.' >3'.i )~ r.r> (io n.oooo 0 ~ o>)<<2
'i 10 31'rl'i 'i ~ 9r. 0? 0 ~ 0000 I ~ I I'7>
r' I I I >3'i I I ~ 730(> '-0 ~ 0000 '> ~ 2 f JI.>
.! I I c'. I n> >i 10 ~ 7046 0 ~ 0000 0~0000 1 1 31t>!i I c> 0<<46 0 ~ 0000 (> ~ ') 7.3 I r' 31 I <35 .3 ~ (>412 O.onnn t) . On no r.' 3 r' <I 'i << ~ >t(litt'> 0 ~ 0000 0 ~ oooo r' I:3 I t> >r <<.~.IVC> , n.oooo () ~ 0 non 2 I ~~ I I I>') n. (.><J 34 0 ~ 0000 O.norm
? I '>~ I I)'.) I f<<60
~ 0 ~ 0000 0 F 0000 r.' <>'I I >I'i 0 > >>r) >3<< 0.0000 r) . i)noo r.' r) I I <I'i I r! ~ r. (>'3>2 0 ~ nnoo I ~ i(i i7
."'> r,' tt!i I I ~ 07'i<< 0 ~ nono 0 ~ 0'il 6
, r'f t) .> I >I'> I.. )C nr'.
n.ooon 0 ~ oonn r!r'I I I >I > '310>s o.oono I I 'I i)~>
ri ) r' alai 7. 3'5r>2 0 ~ 0000 (> ~ nn() 0 i'r" 1.3 I >>'.i 3 ~ ) li)r> n.norm n.nr)nn
,f.> I I I (>'s t. I r>?>3 r> . r) 0(> r> >>, r>r>>>>)
I'Ir>' > .':3 >> ~ >
~ >>r>r>r> >> ~ r>>'r>>'!
>' 'I I t.' (>. (>r) t)r> ~ >)nnt) r'r" I I >i')
> ~ f<<(in 0 ~ 00<)0 r) ~ 0 Jno
<! <"i" I ('>'.i o. novo 0 ~ nnno O.nnno r z'>EI(3 ,I ~ 0<< fr 0 ~ 0000 o.nnoo 2'301 I U:i 0 ~ <<314 0 ~ 0000 '0 Onno
~
<! 3 r) 3.' < >
> I I ~ I I 'I <'>
0.0000 0 ~ non(J It) 51>'*> I 'r! ~ (i f I>! r)~0000 t). norm r' l I I t!'> 11 I I ':if> 0000
')
0 ~ nt)00 i: 31 r! I I>'5 I I ~ '5 <) I r? 0 ~ 0000 0 t)nno i 31.31<3> >3 e <> 6 <52 000000 n.r)ono r' 3 I I >3!i 0> t>')9<< 0 ~ 0000 o.oooo I <(."o r) ..3<<92 n 0000~ O.onnn
.3.3 I I tr .> 0 ~ >'><)t3<> 0 0000 0 ~ ot)no
,> I I >3'.> I ~ 3') ('>,I n 0000 0 nono
<'332 I HG 0 t) 000
~ 0 ~ 0000 O.oono 2 J!>.3 I <5 0~0000 0 ~ 0000 o.noon 2'>01 I (55 ') 079? 0 ~ 0000 o.onno 2<<02 I IJ!i I n.of 60 n.oooo n ~ 0000
? <<0'5 I t'3'i t! ~ 3OO(3 o.oono, 0 ~ 0000
?411 I tl > I<< ~ 4192 0 ~ 0000 0 ~ ()non 2<> I I t>H 11 ') I 30 .0 ~ 0000 0 ~ nor)0 r.'413 I t>!i 1 7. ~,3<) 19 0 ~ 0000 . r).t>? 77 2<> .31 i'i >i> ') ~ 43<<4 0 ~ 0000 O.oooo 7<<37 I r>!i f ~ '33 3? 0 ~ oooo 0 ~ 0000 I
I"-3 il>> >>>>It'>t > trht <<
'<<> I '<<<<
Y RL,.(J
~
RIIL I'I >
I ft
~ -
'lf LL I (i
/(:LJIS I C fhf I'I";P.
c~A>hl>LLi C I )LOP f) Pl I YLL A C HLO()OSrtlYLL 0 CIIL()RQf>HYLI c? 4 3 'I I IJ 5 (j ~ 6348 o.nooo O.nooo 2<< ~ I I t'.5 ~ . ~, 2 ~ 4444 o.onoo o.oooo cf! 4 i2 I ~ 3 'i c'. ~ 0<)!J2 0 ~ 0000 n.oooo
'r>5 Jl >>>5 c.' 79.5 6 n>>onoo Or ~ 0000 2 it) I I ti 2>> 09'ic2 0 0000 O.onno i! '>0.51 (J'i .3 ~ 1428 0>>0000 0 ~ 'onno 2'~1 I I t35 2 0') 52 '.oooo 0 ~ 0000, 25 P.) ($ 51 .S. 0412 0>>0000 0 ~ 5) Ono.
2'i I .5 '$5 L~ 4 ~ On>.'$3 t) 0000 o.onno 25 Jl I 0!i .3 ~ 4920 0 ~ 0000 0>>0000 2'5 Si' V5 3>> (34 12 0 ~ 0000 0 ~ nnnn r 3'31)3cq 2 '936 0 ~ 0000 o.nnoo c2 5:.i I I >3 5 3>> 1428 n>>oooo o.oono i~55 ' J$ 5 2 ~ 79:36 '0 ~ 0000 O.onno 2!5 i.J I tl5 3 ~ 1428 n.nnoo n.noon
'.5101 ) <$ 5 >i ~ 6340 0>>0000 0>>0000 3 I ('i! I 0'i fi ~ ')900 n>>0000 o.nnoo I 310:5 I t.s!i I 4 ~ 'g6'64 n>>0000 3 ~ >5235 t ;5 I I I I c.l 5 I 2 ~ U9>38 0 ~ 0000 0 ~ 7 tl') 6 I ,.311 1)55 Lg ~ 06)5 0 ~ 0000 I I'bb I
<< 'I
.I I I 3 I f('i lr ~ 9150 n>>0000 0>>0345, 31 5 I 1(S5 5>> 'i902 0 ~ 0000 0 0000
.5) 3i' >55 5i ~ 9364 0 ~ 0000 n>>norm 313:5 I Cl5 5>>9424 0 ~ 0000 o 3)!31 L)55 I ~ 04 7fi 0>>0000 0%0000
- 515i!'I 85 I ~ 7460 0 ~ 0000 (' 0000 5 I 'i $ 1 U<<~i 2 '>936 o.nooo 0 ~ ooon
.LZO I I tl"r t( ~ >5350 o.ooon 0424 3 r, () c I >3 .">
t) I t) t54 0 ~ 0000 ~ Lc)L 9 32().I )r.'!i O.!i4 76 0 ~ 0000 I ~ 0260 321 L 105 I4 ~ 644(3 0>>0000 0 ~ nnno
- 32) 2 I )55 1 5 ~ 62 7' 0 ~ 0000 0 ~ 0000
..Sc.' 3 I( i c!>> 96 0() 0>>0000 0 ~ nooo
.Sc'3) I tl!i )>> 396<<5 0 ~ 0000. O.norm
.3:? '5 c I " "-r i 4444~ 0 ~ 0000 0 ~ 0000
.)c! 33 I t3'i 0 '074 0 ~ 0000 4 ~ .i4.'30 3251 I P)5 I ~ 74 (>0 0 ~ 0000 0 ~ 0000 3c>bcr I t)b I~ ')65'>>
0 ~ .i4')0 O.ation Ji"i.'I I H5 frn(34 0 ~ 0000 0>> () t) 0 0 3 501 I li5 4.1034 0 ~ nnon t) ~ 0>) t) 0
.5 Snc.' '5'j 4>>:i 4 '.>\) 0 0000 I ~ t) ) >'i 5 Sc) 31 >$ !j .S. 1>>2>3 0 ~ 0000 n. 000 >)
- J.S I I I >I'v I 4 ~ 0 ~ nt) 00 !) ~ Olin>l 5'5 1 i' >$ <<i 4)')i'4.4$
) I 0 o.onnn 0 ~ oooo I "Jl Sit<5 I 0 ~ ntr50 0 ~ 0000 0 nnnt)
p 4 C<RI ()itoP I IYLL l)4m ni L vnL I).=.. S AA(=. I nl h< I I L lcrtnh<srcuu IC I i=rf:It S>5M(>L<-. C)5LOPOS>HYLL A C)ILO(<OPH YLL 0 CIILQAAI>I(YLL (
'5.'531 I (S5 (So 3()nf) 0~0000 0 ~ Oonn I 5 321)5 "> 9 ~ .3(>(>A A.OOOO 0 ~ Annn
.5 5 3:51 H>5 3 ~ n<<1? 0 ~ 0000 0 ~ <) 0 0 0 5 Sb I 1<5'> () a 5 << '? i> o.onoo 0 ~ 0<)no
,I 5>5i' i".i O.i n)1<< n.oooo 0 ~ nnnn 5 5'> J I >5'> A~ 6') >3<< n.noon O.AAOO' 1<in I I 0'i fl a 7;3 '30 0 nnno OOOO I i'i <) >' >.<! > IO~ (> 3')0 o ()o no n.onnn
.1 'i 0 .I I ) 55 (> ~ 2 Ai,> (> 0 ~ 0000 0 ~ 0000 I<< I I I )5' I I ~ 0 I:30 .A>0000 o in~0 S >i I c.' Ii 5 1>5. 3>i 7<< 0 nnnn
~ n.Anno 5<<1:5 I I>'i ?0 ~ I 0'>5'i ').,'<< I/< A.AAAA A ~ i)A A A I<< li'I I>'3 I," . I >> >>>5 < > , 0 > 3 i i >) >I ~ <I'Ii>ii 1 i ) I I I,'", / I / 'll
~ ii ~ (I <) () <) A, (I(iOA
< I > I I 'I'> I>> )P /0 0 ~ Aooo () . 0AO(),
I<<'>i> I A'> '> ~ I I'7<< 0+OOOO 0 F 0000
,I<<>.'> I '> ~ 1<<2A AF 0000 0 ~ nnnn
~ ') I 0 I I '!'.5 H ~ 0;5 76 0 ~ 0000 0 ~ () Onn
~ << I ()c! I fili I0 ')')20 nioooo A.onno
<<1031 t35 '.7 ~ >7<<1 << 0 0000 nsnono
<< I I I I f55 I >> ~ i>i I 6 A.noon n (5><<>O 4 I I i! I <5! > 1.>.> ~ /I I 6 0 ~ nono O I:3 30
<< I I 31!'15 I:3 ~ 0750 0 ~ 0000 0 ~ 0000
<< I 5 I I )I!> I I ~ 3432 A ~ Onno o.norm
<< I Se I <).i I0 ~ <<?02 0 ~ 0000 0~ 0<700
<< I 3.51>I~i I 3 ~ 26')6 A~ nnon A.norm
'<< I i I I (5",i 0 ~,34 )? 0~ nnnni 0%0000
<< I '>i! I (I'i 0 ~ 09(34 0 ~ oooo O.nnno
<< I >~31 ')'> I ~ 3 )(>f1 A.noon o.nono 4?0 I I )15 'i ~ i? 'SUO 0 ~ 0000 0 ~ 0000
)i? n2 1)5'3 7>6024 0 ~ 0000, O.Anno
<<20 J I (55 I? ~ 2220 0 ~ 0000 A.ooon
<<? I I It)'i I0 ~ <<760 0 ~ 0000 o.nnnn
)> i! I >33:I > I ? ~ I 57? 0 Anno o.norm
<<> 21 31 85 ~
9e 07<)2 A ~ 0000 '
o.onnn
<<i 2:51 105 0~ 3<<92 ~ 0000 ' Oiooon
<<2321 t55 A. onoo ~ 0000' -A.(innn
)I >. 3.5 I i<'i I ~ O<<7h 0000 0 ~ nonn
<<f> 5 I I 0 ~ 0000 0 ~ 0000 0 ~ nnno
<< i ~i > I )'i n.oooo A.OOOO A.Anno
<<5~ I . I!i 0 ~ 0000 n.oooo 0 ~ '0000
<<1011 <)>> 4284 O.oooo 0 ~ 0000
<<302> I f<5 ') ~ 4 284 0 ~ 0000 0 ~ Oono 5 n . I I ( si
< 7 ~ 7 I /5 O.oooo 0 ~ 0<) An
F-5 CIILUPOP HYLL OnTn
<<<LL . V<<<L U~S . PAL .IN MILLIGAAMS/ CUBI C METER ..
."> A M I > L C, C ISLOAOPI IYLL A CH LOHOI>HYLL 0 CHLOHOI>HYLL C
<<'311185 1)3 ~ I <)56 000000 o.ooon na521o5 16 '702 0 ~ 0000 0 ~ 0000
>>,I I 'I I n '.> I 'I ~ 03<<n 0 ~ 0000 o.noon I Sl I <<5 I I ~ '52'Sb 0.0000 0~ 0000
<< I:S;-: 1!<'3 10 ~ 4760 0 ~ 0000 (I 0 0000
'<.3.'.5.51 H5 f) ~ C>3<< 8 O.oooo 0 ~ 0000 n,s!> I I 05 0 ~ 69 <34 0 ~ 0000 0 ~ 0000 4 '5!>2 1<55 2>. ~ 0952 0 0000 0 0000 I;) 'I I <Sfi 1 ~ 7 I< 60 0 ~ 0000 0 ~ 0000 4 <<0 I I I.55) => ~ 2 JISO 0 ~ oooo 0 ~ 0000
~ ~
<0? I H! 0 w OH<<0 0 ~ 0000 o.nooo I >>no JI 05 5) a 93(>4 0 ~ 0000 0 ~ 0000 Q~ 441 I I BS 11 + 0720 0 ~ 0000 0 ~ 0000 I
~ I I< 121155 1
'3 ~ !) 100 0 0000 o.onno I<<< I;I I <<5 I <<e? .)') 4 o.norm n.oooo
>> <<.'3 l I \<5 9>>? c54 0~0000 O.onnn 4<<52 I <3'i H~ 7300 O.oooo o.oooo 4 4.'S.S I <3~> 10 '268 0 ~ 0000 0 ~ 0000
<<n,il I <5 I) ~ <3000 0 ~ 0000 0~0000
<<>> ')~'. I <55 ,O,o 0000 O ~ 0000 0 ~ OOOO
<<<< 'i 3 I <55 n.oooo 0 ~ 0000 o.nnoo
>> 501 I <<!i 4 ~ '>.'I <) 6 0 ~ 0000 0 ~ nooo
>> '. <'. I <" '.) ~ 2 3 IS 0 0 0000
~ 0 ~ 0000 4!>0 I I <<'5 '.i ~ SH72 0000 0 ~ <Iooo
'<') I I I << II I I 15 )'I <<o no (< ~ <)
' /'<<< O
~ << <3 e <,' )<'e <5 ~ << ~ << <I <I I< I ~ ?<< In r< ) I,I I <5',) >< ~,') I ' () << ~ 00(30 0 ~ 000<5
>) ) II I IS!) .I ~ I I<'! <I 0 0000 0 ~ Onoo I< i 521 <<'i '> ~ I! SISO 0 ~ 0000 o.oono 4!'),'l.l I 0!> 4 ~ <3 <3 II 0 0 ~ 0000 0 ~ nooo
<<55) I I H5 c) ~ 0534 0 0 ~ 0000 0 ~ 0000 4 ))!>L.' <55 <> ~ ')on 0 0 ~ 0000 0 ~ 0000
>> ') 'i 'I I 8'i S.0412 000000 o.oooo
P-6 CitLule()PICYLL DA TA ALL VALUES .ARE IN MILLIG)eAMS/CUU I C MET Ele SAMPLE i CHLORAPIIYLL A CHLOR OPHYLL CHLOROPHYLL (
1301700 0~ 0000 0 0000
~ 0 ~ 0000 1302700..- ....... 0% 0000 ... 0 ~ 0000.- 0%0000 0000 1303700 0% 6984 0 ~ 0000 0 ~
131L700 1% 0506 0 ~ 0000 1% 1289 1312700 1 ~ 7520 .......... 0 ~ 0000. 2% 4237 I 31.1700 0 ~ 0000 I' ~ 0 ~ 0000 0 ~ 0000 3:I I 700 I ~ 0476; '.' 0%0000 0 ~ 0000 I 332 700 .....-..---1%3968- '- ---"-.
~ 0 ~ 0000 0%0000 -.
I 333700 0 ~ 3492 0 ~ 0000 0 ~ 0000 I 351700 0% 0000 0 ~ 0000 o.oooo 1352700.%... 0 ~ 7014 ......... 0 ~ 0000 I ~ 2948 .
I 353700, " I ~ 0476 0 F 0000 0 ~ 0000 1401700 ' 7% 1508 0 ~ 0000 1%6096 I ii 02700........6 ~ 4 494.. 0%0000 . 0 '948 1403700 6 ~ 03 "j4 0 '594 0% I164 I 11700 ii 6 ~ ')624 0 '336 J ~ 6099 I 4 12700..........7 ~ 0212 0 224 I
~ 0 F 0010 1413700 t3 ~ 62 74 0 '871 3 '912 I ii 31700 6 ~ 6700 0 '227 4%2201 1432700 , . 5 6892 0 0678 1.9O89 .
14337OO 6 ~ 0294 0 '790 n.oooo 210L700 2 ~ 38A6 0 ~ 0000 3 '742 2102700 .. . I ~ 9746 0%2196 2 ') 958 210 J700 9604 0 3843 3 '804 1101 700 1% 0506 0%0000 I ~ 1289 I 101 700..., .. "... I ~ 0506,..... 0 ~ 0000 I ~ 1209 1102700 I ~ 399A 0 ~ 0000 0%9630
<<OJ7OO 2 '056 0 ~ 0000 I ~ 6ii 76 1111700 .........,... 0 0688 0 ~ 0000 0 '033 112700 2.iihiih 0 ~ 0000 0 ~ 0000 111.1700 I ~ .7460 0 F 0000 0 ~ 0000 II)1700 I I!)68 O.nnoo r), nr)r)l)
I I I ' il !I I i It'i /ii Ii s II(rois liiOL) iili I I 3 3 700 2 1012 0%oooo 2 '578 I 151700 .. J ~ ii 950 0%0000 000000 1152700 3 ~ A472 0%0000 I 4203 I 153700 2 '936 0 ~ 0000 0 ~ 0000
... 1201700. 0 ~ 0000 0 ~ 0000 0 ~ 0000 1202700 () ~ 0000 0 ~ 0000 0 ~ 0000 120J700 0 ~ 0000 0 ~ 0000 0 ~ 0000
.1211700. 0% 0000......,. 0 0000 0 ~ 0000 1212700 0%0000 0%0000 0 ~ 0000 1213700 0 '522 0 ~ 0000 I ~ 4607 1231 700 ............0% 0000 0 ~ 0000 0%0000 .
1232700 0 ~ 0000 0%0000 0 ~ 0000 e
CI'LO(t(JP IIVLL Darn nLL, VALIJCS AAE'N MILL1GAAMS/CU8 I C hIE rER SAMPLE CIILOAOPIIYLL A CHLO ROPHYLL CHLOI(OPHYLL C lc J3700 0>>0000 0 F 0000 o.oooo I 251 7()0 0 ~ 69A4 . 0 ~ 0000 0 ~ 0000 12') 3700 O Sn >72 0 ~ 0000 0 ~ 0000 21>> lno 1>>7490 0>>0000 0 '971 2 1 127IJO c.'~ 74 38 0 ~ 0000 6 ~ '361$
211 J700 I ~ 7550 0 ~ 0000 4 ~ 0'i 03 21 J1 700 2 '966 o.oooo o 2132700 2>>9604..... 0>>3843 3 ~ f) 804
? I 3'I/00 3 ~ 4362 0 ~ 0000 2>>776 5
? I ') I l(JO 4 ~ 93?.0 0 ~ 7137 ~) ~ 0496 2 I:-ic. '/00 4>>069A 0 0000 ? ~ 0004 c! I!i3 700 4.7o6n 0 ~ 0000 2 ~ t1509
?201 700 l>>6204 0 '280 h 7AA3 220c!700 I ~ 4028 0 ~ 0000 2 '096
? 2(J 3700 I ~ 3998 0 0000 0 ~ ')630
?2 I I l00 I ~ .'I 300 o.oooo ?>> I 4',j I 2c! 12 700 I ~ 34 10 0~ 0000 1 ~ 7'/ 19 c231700 0. /onn 0~ 0000 2 ~ cJ214
?231700 I ~ 6314 0F 1182 6 ~ 4 I 4cJ 22 J2700 I ~ pn 76 0~ 0000 o.oooo 2c'.3700 ~ oofI2 0 ~ 0000 ("> ~ >) I I 2 c'c".) I 7 (If> I >>>>c.'4 ~ c >
~ II I) tl f>. I n f ir >3 2 / IJ !J I ~ IJ2 2? 0 ~ 000v ? ~ 4'JA I I! 2'I J lOO FI. n I >IO 0 ~ 0000 I . tS345 2 101700 n ~ /064 0 ~ 0000 ? ~ A.) 09 2 302700 n.OO0O 0 >> 0297 F 1027
>2'3OJ700 4 ~ .35 l2 0 ~ 0000 .3>>0168
? 'I I I 700 5 ~ 9766 o . n 68 9 J)>>oc'3 2312700 5 ~ 34 30 O ~ 0762 3.70ln
? 31.3700 ') ~ 7'34 0 0 ~0000 2 ~ I>i) 32
'3.31 700 n.64n6 0 ~ 3 1 26 4 '332 2 IJ J700 4 ~ '35 72 0 >> 0000 J ~ 0 1 otl
? I'3 I 700 I>> 72.36 0 ~ 0000 .I ~ 7929
@ J52/00 4 ~ ?,336 0 ~ 950 I ') ~ '3!I I 4 2J>J700 3~ 1458 0 ~ 0000 0 ~ 133) 2401 700 4 ~ 3512 0 F 1311 0 ~ 0000 2F>02700 .3 ~ 4>JAO 0>>0000 I ~ 59h2 2403700 4 ~ 4800 0 ~ 0000 0 '522 2411700 5 ~ .'In 00 0 F 1060 2 ~ 0748
?4 12700 !) ~ J9A 0 0 ~ 0000 0 ~ 0000
?4 I 370() 3 ~ 70c! n 0 F 0000 O.-Juno 24 31700 3.3096 0 ~ 2661 3 5145 2n 32700 2 ~ 74 08 0 ~ 0000 4.73n9
?IIJ3700 4>> 4 1 <JO o.oooo I ~ 0:345 ih' /OO I ~ 04 />3 0>>0000 0 ~ 0000
C) Il OII()) II IY DA TA ALL VALI)I:S ARE" 1N h11L L(GRAMS/COO IC METER.
SAh)PI CHLOROPHYLL A CHI OROPHYLL IT CHLOROPIIYLL C I'452700 1 ~ 7460 0 ~ 0000 "o.nnoo
?45J700 ~ - ~ .-..--2% 0952 0 ~ 0000 0 ~ Oono
?')0 I 700 4 '770 n ~ 0000 n.oonn 2502700 5 ~ 05?.6 0 ~ 0000 I ONI!4 2503700 4 ~ rob4 0%0000 2 8509 2511700 4 ~ 993f) n ~ 1944 J ~ I36 73 2512700 4 '316 0%0000 n.0101 2513700 4.416O 0%0000. 0 '079 2<131 700 3 ~ f34 12 0 ~ 0000 0 ~ 0000 2'3 52700 7.7 I? 0%0000 :5%2952 2533700 4%0050 0 '395 1 ~ 5561 2551700 4 ~ Of)90 0%0000 2 ~ 0004 2552700 4 ~ 57<)8 0 ~ 9417 .3% 5)309 2553700 5 '526 0 ~ 0000 I ~ 0504 S I (9))4 0 0000 0%0000
- S IOJ 76 0 '904 n.oooo 0 ~ noon 3201 7h 0 OOOO 0%0000 0 ~ 0000
.3202 76 0 ~ 0000 0 ~ 0000 0%0000
.3 n3 re, 0 ~ 0000 0%0000 n.nooo T.SO I 76 0 '904 0 ~ 0000 o.onnn
- I s 0 ~'. 76 n. 6<)04 0 ~ 0000 0 ~ nnoo
.5303 76 0 '492 0 ~ 0000 0%0000
,340 I 76 10%0620 0%0000 0 ~ oooo
- 34 n? re 7 '024 0%0000 0 ~ 0000 3403 76 13 ~ 03 I fv 0%0000 0 ~ 0000 311 I 76 0 ~ 349? 0 ~ 0000 n.noon 3112 rh n.onno n.oooo o.oonn 3113 rf) 0.3I) 92 0 ~ 0000 n.oono
.5 . I I rf'. 0 ~ nnon 0 F 0000 0 ~ ocnn I". I:! :) ~ Oo nn 0 nnI) I) () . 0 ii () f) i;li I) 7o'I r(I rh 0 oooo 3<) h)S
- o. b() t)0 0 0000 0
0
'j0000
() i) ()
.I I I ~ ~ ~
5312 76 n 6904 0%0000 O.onnn
.I 513 76 1 ~ 04 76 0 ~ 0000 0 0000
~
3411 76 5 ') 364 0 ~ 0000 0 ~ 0000 3412 76 6.6348 0 ~ 0000 0 ~ 0000 3413 76 6 ~ 9040 0%0000 0 ~ 0000
'31.31 76 0 ~ 3492 0 ~ 0000 0%0000 313c'6 0 ~ .34 92 0 ~ 0000 0 ~ 0000 313 J 're 0 ~ 3492 0 ~ 0000 0%0COO 3231 76 0 ~ 0000 0 ~ 0000 0 ~ 0000 32.'32 76 0 ~ 0000 0%0000 os 0000 3233 76 0 ~ 0000 0 oooo 0 F 0000
'5 55e 2 095 0 0000 0 ~ OCOO gg s
F-9 C I IL Ut) () V llVLL na rA ALL VALuE5 ARE I N MILL I GRAMS/CuH IC ME rEII
'SahlPLE CHLO ROPHYLL A CHLOHOPIIYLL 0 CHLOAOPHYLL C 3,533 76 I.an 76 0 ~ 0000 0 ~ 0000 34'31 76 .4 ~ 5396 0~0000 0 ~ 0000 3 i< 52 76 << I 90it 0 ~ 0000 0 ~ 0000 re '.i. 23)IO o.oooo 0 ~ 0000
.I I '-> I 76 2 ~ Oc) 52 0 ~ 0000' 0 ~ 0000
- 5 I '52 76 I ~ 74 60 ~ 0000 0 ~ 0000 3153 76 2 ~ 7936 0 ~ 0000 0 ~ 0000
- 52.'i I /6 , 0 ~ 0000 0 ~ 0000 0 0000 3? 5c.'6 0 ~ 3<<;) 7. '0+0000 0 ~ 0000
'575.1 7l< :Iit <)2 0 ~ 0000 O.oooo
.5,5<> I /6 <". ~ 0') Its~ O.oooo 0 ~ F< 512
.I 5!i2 76 ,I" 7460 0 ~ 0000 0 ~ 0000
;5 Iri 5 76 2 ~ nr) 0 ~ 0000 3 / I ll )
it 101 /e :I o' it 255 0~0000 0 ~ 0000 it 102 /6 c! ~ 7 <J;I 6) 0 ~ 0000 O.noon it I 0 I '/() i ~ 7') IF) 0 ~ 0000 o. titian
<I.'I) I //; it, I <)n<< n, I) I) I) I)
<c i) I, I <<,><5 0 ~ II I) I) I) tl On t)!)
it?t)S /6 it ~ t)I)F58 0<0000 0 0000 it '0 I /6 it ~ .)PQQ 0 ~ 0000 0 ~ noaa it 502 7/) ",i ~ ') 364 0 ~ 0000 a~oooo 4 503 7F) 7 ~ 3,3 12 0 ~ 0000 naonoa n<<01 ~ 'i ~ ') 364 0 0000
~ O.oooo
<<402 76 <3 ~ <) 36it 0~0000 n.oooo it <<03 ?6 6. <)8nO 0~0000 O.oooo il'ia I 76 ') ~ 23llo 0~0000 o.oaoo it!iac.'6 5 ~ 23)) 0 0 ~ 0000 0 ~ 0000
<<60 3 76 c) ~ r)t372 o.ooao O.nooo
<< I I I '/ti ;i.itnnn 0 ~ 0000 0 ~ 0000 4112 76 ? ~ 09)? 0 ~ 0000 0 ~ 0000 i)I 13 76 '444 421 it 712 I'6 2 207936 0 ~ 0000 0 ~ 0000 0 ~ 0000 0 ~ 0000 76 it ~ 53c)6 =
0 ~ 0000 0 ~ 0000 n: I 3 7e .5 ~ 1428 0 ~ 0000 0 ~ 0000 4 311 /6 ~ ) ~ 5H 7c. 0 ~ 0000 0~0000 4.51 2 76 4 ~ 3<)6 i 0~0000 0 ~ 0000 4 51 S 76 6 '856 Oaaaoa n.oooo it 411 76 r, ~ <) 872 n.oooo O.oooo 4<< I2 7t) )I ~ O.I I 6 000000 0 0000 F
4<< I 3 76 Fi ~ i) 'In )3 a.oooo 0 ~ 0() 00 it 511 7o '3 ~ 4 920 0 ~ 0000 0 F 0000 nsl~ n.loon 0 ~ 0000 , 0 ~ 0000 4513 /6 3 ~ I <<28 0 ~ 0000 0 0000 it 151 76 3i lit 20 0 ~ 0000 o.oooo 4 I 3c'. 76) 3 ~ I it 2 FI 0 ~ 0 0 0 I) 0 ~ 0000
Ct>LO>)OP t>YI I hLL VALUES htlF. I N M I L L I GtlAMS/C I C ME TEII Sh)IVLr; C IILOAOPHYLI A CHL'O OBOPHYLL f) CHLO>tOPHYLL i> I J.5 76 2% 7936 0 ~ 0000' o.onoo
<<231 76 . J 1<<28 ~ 0000 n.oooo i> r" 3i) f f) i) ~ 7>)36 000000 n.oooo
<<2.1 J 76 2 (O'Sf) 0 ~ 0000
~
O.ooon I> J,51 1t) << ~ 'i 5')6 0 ~ oooo 0 ~ 0000
/f) i> ~ g J')6 0 ~ 0000 0 ~ 0000 i> I 5.5 76 lt 4 i> I< 000000 000000
<<<<.51 .76 1% 7<<60 0%0000 0 '0000 i> I> I ! 7t) I ~ 74f)0 'n;oooo 0 ~ 0000
<<4 SJ 76 I ~ 74 fin 0 ~ 0000 n.oooo i> ') '5 I 76 3 ~ I it28 0 ~ 0000 0 ~ 0000 i> b.52 76 3 ~ 4920 0 ~ 0000 0 ~ 0000 453.5 76 <<. lOOn 000000 0 ~ 0000 it 161 76 3 1428 ~ 0000 I >52 76
~ 0 n.oooo 1904 000000 0 ~ 0000
<< I!i.S 76 20 7936 0 ~ 0000 4a"3 I 76 000000 50 1428 0 ~ 0000 0 ~ 0000 i> 252 76 I ~ J968 000000 0 ~ 0000 4 2'.>.I 76 1428 000000 O.oooo i> J'3 I 76 . 000000. 0 ~ 0000 0 ~ 0000 i> '5ba!
4 5!i3 76 06'ATS 3it92 76 0 f)9 )4 00 000000 0 ~ 0000 .
n 0000
~
000000 4;i ) I 76 4 ~ 1904 0 ~ 0000 .0 ~ 0000 it g')2 76 i> ~ I 904 0 ~ 0000
<< '.i'i3 76 ,0 F 0000 3 ~ 8i> 12 0 ~ 0000 0 ~ 0000 1101 U6. 0 ~ 0000 0 ~ 0000 0 ~ 0000 I I (>c! t>G 0' 0000 0 ~ 0000 0 ~ 0000 I I () 5 d6 0 ~ 0000 0 ~ 0000 o.oooo 1201 IS6 0 ~ 0000 0 ~ 0000 0 ~ '0.000 1202 OG n.noon 000000 O.oonn
~
1203 86 0 ~ 0000 n.oooo. 0 ~ 0000 I 301 06 0 0 .'5 i> 92 0 ~ 0000 0 0000 I 'IOc.'If) I ~ nit 76 n.nnnn
~
n.nf)nn I II'I I f), t) I) t) I) 'I 0 t) f) t) ti I).>)>If.:!I I i>>i I tlt) 4 (') ll')
0 0 ~ oooU t) ~ Oooo I << () 8 fl 6 .5 ~ n<<12 O.oooo I <<OJ 86) f) F 0000 I ~ 0476 000000 0~ 0000-1111 UG I ~ 7460 .. 000000 o.oono I I I2 At> I '396A 0 ~ 0000
~
0 ~ oono I I I3 tt6 I ~ 0476 0 0000 0 ~ 0000 121 I fS6 0 ~ Ji> 92 0%0000 1212 86 n.oooo 0 ~ 69(34 0 ~ 0000 0 ~ 0000 1213 86 0 0000 000000 n ~ 0000 1311 86 7% 62.36 0%0000 0 ~ 0000 I,l I 3 I0 ~ 1260 000000 0 ~ 0000
C( IL 0 > 0 ('P I'( Y L L DATA ALL VALVI.S AAC I hl /
tA ILL I (3 P h tn 5 CUD I C MF. TCH 5 A I(liLL CSSLOIIOSi)'I YLL A CH LOAOPHYLL IS CHI ()S)flPHYI I I '313 I! 6 10 '5?4 0 ~ 0000 0 ~ 0000 lnl I E)b 5 '872 0 ~ 0000 o.oono
'I 4 I c! (S (i :I ~ Un I? 0 ~ 0000 0 ~ oono I n I.S >>6 4 ~ 1904 0 0000 n.neon I IJI Ue P. ~ 095? 0 ~ 0000 0 ~ 0000 I IJd HG I ~ 3')() 8 0 ~ 0000 0 ~ 0000 I I 3J 06 2 4444 0 ~ 0000 0 ~ 0000 1231 UG 2 'l444 0 ~ 0000 0 ~ 0000 I ?:I Uf'6 2 ~ 0') 52 0 ~ 0000 0.OOOO
'952 i.'?
J.'I 2 o.noon O.ooon 13JI t(6 9 '792 0 ~ 0000 o.oooo I 3:I? E$ 6 I I ~ 4000 0 ~ 0000 0 0000 12;5 3 86 8 ~ 0316 0 ~ 0000 0 ~ 0000 1431 E(6 12 ~ 45.36 0 ~ 0000 n.oooo ln 32 Of. I0 ~ 82.')2 n ~ 0000 0 ~ 0000 I <<:(3 I'6 I I~ 2108 0 0000 o.oono I Iil UG 0~
n.noon 0000 0 0000
~
o.onoo 0 F 0000 nooo I I fl'c! Es6 0 ~
II > I Uu I- 0 I) fl psl (l.fl(~1)I)
I:: 'I r.nnnn 0 0000 O.onno I l'? (So I ~ 7460 o.oono 0 ~ 0000 I?'i 'I (lb 2 ~ 0952 n.oooo 0 0000
~
2101 U(3 0 ~ 0000 0 ~ 0000 O.onon c! 102 t(6 0 ~ 3492 0 ~ 0000 0 ~ 0000 2103 lSG 0 ~ 0000 0~0000 n.oooo 2201 U(> 0 ~ 0000 0 ~ 0000 o.oono 220? t3b 0 ~ 0000 0 ~ 0000 0 ~ 0000
?203 tie 0 3fl 92 0 ~ 0000 n.oooo 2 301 UG ? ~ 7') 'Se 0 0000 O.oono 2302 c)6 3 ~ 4920 0 0000
~ Oaooon 2 JOJ f((i I ~ 3960 0 ~ 0000 0 0000 2401 Is 6 J ~ 4920 0 ~ 0000 0 ~ 0000 2402 Ue I 4 2)3 0 ~ 0000 0 ~ 0000
?noJ c(fi I~ 4 920 0 ~ 0000 0 ~ 0000 2501 06 5 '300 0 0000
~ 0 ~ 0000
?502 VG 5+587? 0 ~ 0000 n.oooo P:>0.3 E)e 5 '872 0 ~ 0000 o.noon 2111 06 2 '444 0 ~ 0000 0 F 0000 c! I I c! t(6 0 3492 0 ~ 0000 0 ~ 0000
? I I,S ES (') 3 ~ 1428 n.oooo o.ooon
?211 UG 1. O47< 0 ~ 0000 0 ~ 0000 I! r.' 2 86 0 ~ 34')2 0 ~ 0000 0 ~ 0000 221 3 06 I 3968 0 ~ 0000 0 ~ 0000 2JI I ES6 3 ~ 49?0 . 040000 0 ~ oooo c! J I? E36 0 '526 0 ~ 0000 o.noon
t I II. III I I II ' IY IIA I A AI. I V A I. Ul AIIL I I'I M I LL I (clt AIIc~ i' I) <5 I C M I: T C II 5AM I'I IILOIt()PIIYI,I. A CIILrIII (II'llYI. I... Il (: I II. I) I I I I I 'I I V I, I
'I ~ c< I tl tl I) ~ II II I I (I tt ~ II lt tl II
~ "I I I I ~ It <I I (I ~ anon tl ~ nt) n(l rI I II 6 ~ rt 'I? 0 r'I O.onoo 0%(tnon cl. <<,3<<it r'!4 I .I I (> 0 ~ 0000 0 F 0000
?'>I I UU 5 ~ P.380 0%0000 0 ~ 0000 c?'5 I 5 ~ 5t. 7<.'7 0 ~ 0000 0 ~ 0000 r'513
~ r'714 0 ~ 0000 0%0000
?1Jl U6 . 3 1420 0%0000 o.oono
'c! 132 I ~ 7460 0 ~ 0000 0 ~ 0000 r! 133 Ua I ~ 7it 60 0 ~ 0000 0 ~ 0000 22Jl <J6 3. <<<)20 0'%000 0%0000
?232 U6 4 1904 0%0000 a.oooo
,2c? 3 J H(i it ~ 8808 0 ~ 0000 0 ~ 0000
?JJI 06 9 ~ 0204 0%0000 0 ~ anaa
?.I 52 Ua 0 ~,58 08 0 F 0000 o.onon 23 <'6 ~ 00:52 0 ~ 0000 53 I0 o.oonn 2<t.31 Ub 9 ~ 3 6 <) 6 0 F 0000 .0 0000~
24 Jr! f56 fl 671 2 0 ~ 0000 0 ~ 0000
- c. it 3 J 06 9 ~ JOIO 0%0000 0 ~ 0000
?53l 86 7%3332. 0 ~ 0000 0 0000 253? tlat H6 5%9364 0 F 0000 O.oooo c;3 S 86 7% 271(t 0 ~ 0000 ,0 ~ 0000
'1'i 1 86 0 '492 0 ~ 0000 0%0000 r.'I 5L'53 86 0.6904 0%0000 o.oaoo 06 0%0000 0 0000 0 ~ 0000 2cVi 1 1%0476 0%0000
'(t 0 ~ 0000
~ c) 2 86 I ~ 04<'6 0 ~ 0000 n.oooo
? ccci J (36 I ~ 3') 6>> 0 ~ 0000 o.naoo 2,"55 I J'(< 8 ~ 6652 0 0000 . O.oaoo
?.552 86 5 '872 0 ~ 0000 0 F 0000
?35J 86 8 ~ J030 0%0000 0%0000 2it51 06 J ~ 0412 0 ~ 0000 0 ~ 0000
?r it 5r.'!
it c.t.l 86 i'910 0 0000 0 F 0000 1% <<c)? n 0%0000 0 ~ 0000 c'>I Ub v ') 222 0%0000 0 ~ 0000 2'2 06 5%?380 0 ~ 0000 0 F 0000 r'55 J 86 6 '886 0%0000 n.oooo 3101 Ub 0%0000' o.oooa ,
o.oaoo .
31 ac! fl(I'I6 ~ 0000 0 F 0000 O.noon
'5 I0J 0%3492 0 ~ 0000 0%0000 J201 86 I ~ 04 76 0 ~ 0000 0 ~ 0000
- I? 02 86 0 F 0000 0 ~ 0000 0%oooo 320J U6 0 ~ J<<c)2. a%oooo 0 ~ 0000
~ 3 Ja 1 ISO 3%<<920 0 ~ 0000 0 ~ 0000.
5 Inr! Aa <<1904 0 0000 0%anon
C I II,. () I I ()IIlIYLL Dhfh ALt V AL UCa Afll: I N MI L LI(;AAI 8 /CUU I C FLI TCf(
AAMPLf Clll OAOPHYLL A C ISLOBOPHYLL 0 CHLO()OPHYLL
.5.303 06 19O<< 0 ~ 0000 0 ~ 0000 3<<01 U6 9 <<3th 0 ~ 0000 0 ~ 0000 3<<ng I'6 I 0 ~ I?9(3 0 ~ 0000 0 ~ 0000 5<<03 9 ~ 3636 Oonoon 0 0000
~
.Sl I I IS f> I e 0(i76 0 ~ 0000 0 F 0000 3 I I? I'6 l) ~ 590<< 0 ~ 0000 0 ~ 0000 5113 )56 0 ~ !>') 84 0 ~ 0000 0 ~ 0000
- 321 1 86 3 ~ (I 920 o.onoo 0 ~ 0000 Ic' 2 0fc 0~ f>c) 84 0~0000 0 ~ 0000 Sdt 5 II( 0~ 0000 0~0000 0 ~ 0000 3 51 I 06 6~ 2856 o.ooon 0 ~ 0000 3 512 06 '5a5072 o.noon o.oooo 3.31 3 06 4 ~ 1904 0~0000 0 ~ 0000 3(i 1 1 06 in'680 0 0000
~ 0 ~ 0000
'5'I I e Af> in'112 0 ~ 0000 n.oooo 3<<13 06 9 '792 0 ~ 0000 0 ~ 0000
,31 5 I 06 I 0<<76
~ 0 ~ 0000 0 ~ 0000 3 I:32 fl tj 0 '904 0 ~ 0000 0 ~ 0000
'313 5 06 2 '952 0 ~ 0000 0 ~ 0000
- 3c' 1 86 3 '428 0 ~ 0000 0 ~ 0000 I:6 2 ~ 79.36 0 ~ 0000 o.nono 5233 HG ~ 7936 0 ~ 0000 0 ~ 0000
- 5 3.5 1 l3 F, (I ~ 03 16 000000 0 ~ 0000
- I '3:32 06 10 '760 0 ~ 0000 0 0000
;33 5.3 06 6 ~ 90<< 0 0 ~ 0000 .0 0000
~
34 31 56 7 ~ 333? 0 ~ 0000 D.onon 3<<3i.' 16 I 0 ~ 0062 n.onnn I) ~ fl )nn i(i I I )I> 'I / / /I)
~ il ~ l) I) ll 0 I) ~ Dniin II' II 6 I ~ / I I I) ~ II ~ I) 0 0 0 II ~ I I I) ') ()
I I ';> >16 I l<<60 0 ~ 0000 0 ~ 0000 c.'1'i:I I! ('> ."I ~ 1428 000000 0 ~ 0000
.3?ci 1 dG F 0412 0 ~ 0000 0 ~ 0000 3262 06 2 '936 0 0000
~ 0 0000
~
.'3.' 5 fI f> 3 ~ 1420 0 0000 .D.noon h 101 86 h ~ '3396 0 ~ 0000 D.noon
<<102 06 3 ~ f3412 0 ~ 0000 0 0000
<< I O.S 06 (i ~ 1 904 000000 Dunno(t
<<201 86 3 ~ 2300 0+0000 0 ~ 0000
<<? 0'J 86 hi e 0888 0 ~ 0000 0 ~ 0000 4 20.5 ub 6 '34A 0 ~ 0000 0 ~ 0000 fi 301 Hb I '5 ~ 720A 0 ~ Ooon 0 ~ 0000 4 302 06 13 ~ 7238 0 ~ 0000 naoooo 4 .503 fS6 14 3544 0 0000 0 ~ 0000 4401 06 1 0 ~ 8?52 n.oooo 0 ~ 0000 h<<02 II 6 12 ~ 7960 0 ~ 0000 0 ~ 0000
C I II(.))t() li) IYLL I)A TA ALL VAI.Ltt 0 Attt.' tt M I L L I GAAMS/CUI) I C ML't:.A
~ ~
SAMPLE CIII OftOPHYLL A C IILOIROI'IIY L L )3 CWL())tC)tit<VI L '
'yl) >>03 06 I 3 ~ 4952 0 F 0000 C
r<
~ 0000 I
>>501 Hb I O.9H~~O 0 ~ 0000 0 ~ 0000 4'.I02 oh I I ~ >>010 0 ~ 0000 O.oooo 4 'y() 'I :) ~ () t)? a.' 0 ~ 0000 ~) ~ <) 0() 0 s I I I (: t. I 'I lp'I () IJ () I) ()
~ ~ () ~ () 0 () I)
>> I I 2 ))6 'I
~ fin I? O.oooo 0 ~ 0000
<<113 06 5 '300 0 ~ 0000 oo0000
>>211 86 n. 19on 0 F 0000 0 F 0000 Hb .I ~ 1428 n.oooo 0 ~ 0000 4213 06 r) << 'i 396, 0 F 0000 O.oooo 4 311 db I >> ~ 760r( 0 ~ 0000 O.oooo 4 3 I? 06 14 ~ 0002 0 F 0000 0 F 0000 4 513 06 I 4 ~ 6418 0 F 0000 0 0000
>>nil Ub 52~8804 17 '429 3 ~ OH07 4>>12 Ub II 3302 0 ~ 0000 0 ~ 0000
>> 4 I 3 t'.6 I I ~ 1126 0 ~ 0000 0 ~ 0000 4511 . Qb 9~ 3666 0~0000 Oaoooo r)512 06 9 3696 0 F 0000 0 ~ 0000 4513 06 da7330 0 F 0000 0 F 0000
>>131 .06 04 I'2 Oaoooo 0 F 0000 4 I 5? 86 I ~ 7460- O.oooo 0 0000
>> I IJ t)b F 1420 0 ~ 0000 0 F 0000
>>231 06 19on 0 ~ 0000 O.oooo
>>232 Hb 6 ~ 2856 0 F 0000 O.oooo
>>233 t)h 5 '364 '0 ~ 0000 0' 0000 4'33 I 06 12 '366 0 ~ 0000 0 ~ 0000
>>.I 32 Hb 13 '842 0 ~ 0000 0 ~ 0000
<<33.) HU 13 '7lb 0 ~ 0000 0 F 0000 4r(31 86 10 '090 0 F 0000 0 ~ 0000 4 431! 06 I 3 ~ 7178 0 ~ 0000 0 0000
>>>>33 86 I n. 40r) 0 0 ~ 0000 Oeoooo RSJI 86 . 9 6540 0 ~ 0000 0 F 0000 4 5.)2 H6 <) I 71HU 0 F 0000 0%0000 4033 U6 12 1632 0 F 0000 0 F 0000 4 I 5l c!6 2 ~ Or)52 0 ~ 0000. o.oooo
'4 152 06 2.4444 0 ~ 0000 0 ~ 0000 4 15J 06 4 '396 0 ~ 0000 o.oooo 6 '252 l
4251 86 0 ~ 0000 o.oooo' 42 ic'6 5 'R72 0 ~ 0000 F 0000 4253 86 t3 ~ 7300 0 F 0000 0 ~ 0000
- nr)51 Qb 12 ~ 4476 0 ~ 0000 0 ~ 0000 4452 d6 I 2 ~ 3?4 0 0 ~ 0000 0 ~ 0000 4>>53 06 12 ~ 38S8 0 ~ 0000 0 ~ 0000 4551 86 10 F 4142 0~ 0 F 0000 4 'i'j2 Hb I) ~ 0346 0000'~0000 0 ~ 0000 I
i I
<< <I <II<< II'I rI I l<h < I ~
<>I I V<<I << I li <<III I II I I <
l<r>11'<<<>I>I
~ / < ) II I I < I '. I I II I < II Is)< I I I < I I P I I II I!<' I ' l I. l:i I I< Ill!i<I I I l l
<> ~ > (I ~ 0 0 0 0 () ~ 0000 7,102 ~
)<3 I).r> )Un 0 ~ 0000 0 0000 7 l<>3 <) (J () ~ conn 0 ~ 000() 0 F 0000 I?701 ')6 > ~ <<(>or> I) 0000 I ~ 3.)68
?~02 ')6 ~ !) ~ 1 I 7r< 0 ~ 0000 I ~ 50P. 7 2?03 9(> << ~ <I') r< II 0 ~ 0000 n.9306 PJOJ <) 6 3~
'l. 1488 I 45(l 0 ~ 0000 0 '335 230'.'?30 96 n.oooo I ~ 760 I I 96 p ~ <<47<< 0 0000 0 ~ <<65>3 2<<01 ') 0000
~
>6 ~ (>4 <<7. 0 ~ O.onon 24>)2 96 n ~ 76))2 n.oooo I ~ 66drp 2<<O.I 96 << ~ 5456 nenoon I'965 7 ~01 () r I o 3')6U 000000 0 ~ 0000 2502 96 I ~ 3960 0 ~ 0000 0 ~ 0000 7'>0 3 ')6 I ~ 7<<60 0 ~ 0000 I) F 0000 P1 12 i)f r) ~ 6') 84 0 ~ 0000 O.noon 2113 I ~ r460 0 0000 n.noon
?211 i)6 5 'UOA 0 ~ 0000 I ~ C> I >2 221 c', ') (> 4 ~ 7717 0 ~ 0000 3 '95P 2213 '.) 6 C ~ 51 7?. 0 ~ 0000 2+4657 7 311 <)6 ?.450<< 0 ~ 0000 :! e 0') I ')
P.I I 7 ')e P. 7996 0 ~ 0000 I 9260 i'? 31 3 96 2 ~ 0982 0 ~ 0000 >) ~ 6312
'<< l l ')6 .3 ~ <<980 0 ~ 0000 1 5942 p.r< 1 7 96 P.nnnn 0 ~ 0()00 o.oono 2<<13 96 2~44 r< 4 0 ~ 0000 0 ~ 0000
'"> I I i)A ~ 7966 0 ~ 0000 0 o?')')4
?512 96 7 ~ 09.>2 000000 0 ~ 0000 2'>13 96 I ~ 3960 0 ~ 0000 000000 21 32 96 1 e I9(>8 0 ~ 0000 040000 2231 96 '5 ~ 1174 0~0000 I ~ 5077 2232 96 3 '266 0 ~ 0000 5> ~ r< 195 2233 96 3 '<<58 0 ~ 0000 0 F 1335 2331 96 7 '982 0 ~ 0000 0 ~ e.I 12 2 332 Je 1 ~ 7r< 90 o.oooo 0 '971 2333 2 ~ 44 74 0 F 0000 0~4653 2<<.S I \) 6 2 '952 000000 0 ~ 0000 2<<32 96 2 ~ 4<<44 0 ~ 0000 o.oono
)! I< 3 3 'E) 6 I ~ 3 )60 0 ~ 0000 0 ~ 0000 7531 ') (> I ~ 7460 o.noon 0 ~ 0000 2'> 3P ee 1. rn6>0 0 ~ 0000 0 Gnon
? >)3 96 l. 7n6o 0 0000
~
0~0000
.151 <)6 :I ~ I 458 n.oooo 0 ~ 13 35 2152 96 3 ~ 0840 0 ~ 0000 I ~ I15>A
? 153 96 5456 0 ~ 0000 1+0466 I
G<
C WL)JR OPIIYLL 'A T ALL V at UES Attt= 1N M LLL 1 C)RAMS/CUB 1 C ME TER SAM))LL C I IL OA OPHYLL A CHLQI)OPHYLL 0 CI5L(lRAPWYLL'C 2251 96 3 '472 0~0000 I ~ <<?I) 3 2252 96 3 7236 0 ~ 0000 3 79?9
.96 3 ~ 4 .592 0 ~ 0000 4 ~ <<031 2 351 96 I ~ 04 76 O.oooo O.OOOO 2352 96 I <<02!5 0~0000 2 5896 2 553 ')6 0 ~ 0000 0 ~ 0000 0 ~ 0000 2551 'j6 1 0<<76 0 ~ 0000 0~0000 I 5'"I 96 1 ~ 8968 0~0000 0 ~ 0000 i5')I 96 1. 3968 0 ~ 0000 0~0000 4 I ol '.) e 2380 0 ~ 0000 0 0000
<< I 0>>.' 96 6 ~ 2 JQ.O 0 ~ 0000 0 0000 LOJ ()6 4 5396 000000 0~0000 n2Ot <)6 <<. I )On 0 0000 0 ~ 0000
<<202 96 be2056 0 ~ 0000 0~0000 I)20J 96 4 ~ et!)38 0 ~ 0000 o. ooo'o
<<,501 )6 I 7<<60 0~0000 Oaooon
<<302 96 1 ~ 3968 0 ~ 0000 0 ~ 0000 I) '}03 96 2 '95?. 0 ~ 0000 0 ~ 0000 n<<019 00 bo 7!i<<0 0 ~ 0000 ? ~ '55 3?
<<<<.0~. ')6 () ~ ? Ilbh 0 ~ 0000 n.oooo
()(i() I ') () << . I ')0<< 0 ~ 0(I (10 (I. I) unn
~ ) '))) I t. ~ ) It "I) Il i (It) II (I (I ~ t)<)(ttt
<< ')I) 5 ~ I <<211 0 ~ 00 tl 0 0 . 00nn n!30 i' 7').16 Ooooon 0 . nono .
411 5 ~ )872 0 ~ 0000 0 ~ 0000 411 2 96 4 ~ 5396 0~0000 0 ~ 0000
<<11 J c) 6 8~ 0316 0 ~ 0000 .0 ~ ocoo
<<21 I 96 4. III58F) 0 ~ 0000 0 ~ 0000
<< 'I I '.) ~ 2 380 0 ~ 0000 0 ~ 0000
<<21 .5 ~) () 7 ~ 27 7.4 n.oooo 0 9516
<<.3 I 1 96 ?~4444 0 ~ 0000 '0 ~ 0000
<<.I I 2 96 0 690<< 0 0000 0~0000
<<31 .3 96 I ~ n<< 76 0~0000 0 ~ 0000 4<<I I i) 6 6 ~ 9252 n.oooo 0 ~ 0000
<<<<I 96 9 '188 0 ~ 0000 0 ~ 0000
<<n I J "\76 ba5760 0 ~ 0000 0~0000
<<51 96 ?. ~ 7936 0~0000 0 ~ 0000 451 2 96 3.495o 0 ~ 0000 0 ~ 0000
<<51 3 96 3 AD <<9?0 0 0000 0 ~ 0000
<< I 'I I 'i 6 << ~ 3'888 0 ~ 0000 Oaoooo
<<13 9()' 3 ~ << ~)20 0 0000
~ 0 ~ 0000 3 96 <<+5396 0 ~ 0000 0 ~ 0000 423 I 96 '
~ (5888 0 ~ oooo o.oonn 423 96 2 ~ <<<<44 0 ~ 0000 0 ~ 0000
<<2:5 i) 6 <<ob:59() 0 ~ 0000 0 ~ 0000
(.' cl. I7(L I II 'I I YLL OA Th
,aLL V ALuLS ATOLL" I N I I L L I Gl(ASS/CUU I C h(F TEIL 5A I L tli ~ Lc CHLUILOPH YLL A CHLOAfiPHYLL A C HLOR()PHYLL Ic 3.51 96 0 ~ 0000 0 ~ 0000 0 ~ 0000
<<3 52 9b 0~0000 0 ~ 0000 0 ~ 0000 Ic 3 'l.l c)6 n. $ <<)2 0 ~ 0000 0 norm
<<FIJI 06 7 ~ c>2 3b 0 0000 n.oooo 4/c $ 2 c) 6 cs. ($ 350 0 ~ 0000 2 ~ 0 fc ? 4 4 cc 3 3 ') 6 H ~ )532 0 . 0 ~ 0000 0~<<L Rfs
<c551 96 2 /c/c/(4 0 ~ 0000 n.nooq 4532 96 2+0952 000000 0 ~ 0000 (c '.> 3J 96 .I ~ 1 4 2H 0 ~ 0000 0 ~ onon Ic I5 I . ') 6 3 ~ !$ 4 12 0 ~ 0000 o.ooon (c I 'i 'r' b 2 ~ 7036 0 0000 0~0000 4 L-SJ ') ci ~ 793c> 0 F 0000 0 ~ nnnn fc c..) I ') 6 n ~ 0000 0 ~ nnnn
<< ') C) I!. 4/(44 0 ~ 0000 n.norm "5i.'8 i.l )6 ~ '. Oc)52 0 ~ onnn n.norm (c ')c> 0 ~ '$4 ') 2 I). non 0 f) c (Inn n II c I I lfc
~ ~ tt, fttt )ct
~
ct c cttt!It)
'c 1" i I 'I 6 ct. c)c)n(I, () ~ 0000 0 ~ nn00 tc 4 ')6 f> ~ 2(c 02 . o.noon 0 ~ I) 096 4<<52 ')6 U ~ 2572 0 ~ 0000 O.nono 44 "i 5 ')t: 6 ~ c) r")2 0 ~ 0000 0 ~ nono
~c I 2 ~ 7c7 J6 0 ~ 0000 n.nnnn 455m ')6 2 ~ <<<</I<< 0 ~ 0000 n.oooo
/c 5b.$ 9(i ,
I ~ 3'>6($ 0 ~ 0000 0 F 0000 I Lnl 57 lory 3544 14 ~ 0 0000
~ O.oono I I 57 .21nf 0 ~ 0000 0~0000 oa.'103 5'/ Ill 9100 <<28 0 ~ 0000 0 ~ 0000 n
0
~ 0000 F 0000 12i) I 57 3 ~ I I?0<? L 7 p, 0952 O.oono 0 ~ 0000 I 20;5 57 2 '952 O.OOOO n.onon I;50 I 57 6 ~ c)364 0 ~ 0000 o.nono I 302 57 fc ~ 7652 0 ~ 0000 0 ~ n<<20 I 30:1 FJ 7 5 '072 o.nooo n.onoo l<<n I 57 / 2126
~ 0 ~ 0000 0 '07'5 1402 5/ 5 '224 0 ~ 0000 n ~ nnnn I <<0.$ 5/ 5+5254 0 ~ 0000 0 ~ 0000 LLLI 57 I f) ~ 64 b(5 o.onno o.nnnn 1112 ci 7 I f>.193<< 000000 0 0000 I I 13 57 9626 0 ~ 0000 0 norm I 1? I I ',1 7 5 ~ 4920 n.oooo 0 ~ nnnn 1~12 5 '/ /c 4 /c 4 O.nono 0 noon 1213 !i7 2 '952 0"0000 0 ~ 0000 I sl I 57 7. 96c7(s 0 ~ 0000 0 ~ 0000 1.$ 1 2 ",i 7 7 ~ !) 6'7(3 0 ~ 0000 0 0000
~
I3L 5 !i7 cS ~ c) 526 n.onno 0 0000
CI<<. (I()()l I IYLL I) A ( 4 AI.l. VAL1)I; '.i A fit'., I (I II I I. l. I Ci() AMbl(' III I I C H, I I', I (
'.)hl4l'I I (, I II. (I((()I I I ( Y I. I A (: III. Ol(rll)ISVLL r.i~> Ot(()r >(VLL I it I I 'j7 f. )00n 0 ~ 0000 n.onon I it 12 57 f ~ 0462 0 0000 o.oono I << I I <if 7 o? ()tS<< o.nnoo 0 ~ 0000 I I 'll 'i7 it. I nnit 0 ~ 0000 0 ~ 0000 I 1.)r.'13
!) ~ 5)0 7?. ,o.onno O.nnoo I "I"f n ~ ') )')f) 0 0000 0.0000 I <! 31 !) 7 '>
~ i'I it << it O.oooo ,0~0000 I r')! !) f ~ . II'0 ~ <, () . (It () P ()
I I I ~
))):I I) ~ 0000 0 ~ 0 I)!) 0 I ll ')f )) 51 12 0000 0000 I JJ'7 S ~
!i ~ 2 JAO 0
0 F
~ 0000 0
0 ~ 0000 13.3 J 57 ho (S I 2(3 0 0000 0 ~ nnon ln J I b7 ) I<) 6 000000 0 ~ 0000 I it '.32 57 :i o 5072 0 ~ 0000 0 ~ 0000 I t)S ')7 <<.19a<< 0 ~ 0000 0 ~ noon I 151 57 I.n<<76 0~0000 o.nooo I 15is 2 ~ 0<)!i 2, 0+0000 0 ~ 0000 1153 b7 3 'n?0 0 ~ 0000 0 ~ 0000 12!i I 5 1 0 ~ ()984 0 ~ 0000 o.onoo 12b2 57 1 ~ oit 76 0 ~ 0000 0 ~ 0000 12b3 57 0 ~ 6904 0 ~ 0000 0~0000
?101 57 I4 ~ 7400 0.? 110 1~2702 2 I oc! 57 I it ~ (le 7it 0 ~ 0000 0 ~ 53?.2 210 J b7 15 ~ 1510 0 ~ 0000 0 ~ 0000 2?.o I '.i7 3 ~ 0472 0~0000 1 ~ <<2(33 2204. 57 << 0330 0~0000 ?. ~ I 129 220.3 5 7 4 ~ I 9'34 0 ~ 0000 o.oonn
? tol 57 5 ~ 5?. Hit 0 ~ 0000 () ~ I .i it b 2 Joc'. b7 it ~ 7064 0 ~ 0000 2 050')
2:30 J !)7 4 ~ 54?.6 0~0000 0 ~ 0000 2itn1 57 5 '776 0 ~ 0000 0 ~ 0000 2it 02 57 6 ~ it 524 0 ~ 0000 2 021n
?<<n I 57 'i ~ 4 070 0~0000 n.)<<s7
?;io I .) 7 ?.n952 0 ~ 0000 0 0000
?502 i f
~
2a0364 0 ~ 0000 I ~ 0135
?50J 57 2. 3(356 n.oooo I ~ 64 76 57 20 ~ 6)104 0 0000 I ?5eH 2112 57 17 '926 0 0000 4+6569
?113 b7 20 ~ 43.30 0 ~ 1()90 0O57 c"-' I !i7 0300 0 0000
<< ~
- 0. it (3'63 2212 57 5 ~ 0(306 0 ~ 0000 1~6152 2213 57 n 0soo 0 ~ 0000 o.n0r3
.2 Sl 1 57 9 '952 0 ~ 0000 0 ~ 5203 2J12 b7 7 ~ 7074, 0~0000 2 ~ <i<<01
'I I b7 7 ~ 90!i 0 0 0000
~ 0 ~ 0000
CHi OII(if>IIYI.L r)A'r 4 fiLL VALVh 5 AAL= IN NILL I GIIAMS/'CUIS I C HE rEA SAMVL(i C IILOP Or II YLL A CHLOIIOI>HYLL CHLOAOI>I'YLL
.2411. 57 a. I)442 0 ~ 0000 0%0000 24.12 5 f 5%1174 0 ~ 0000 I ~ 5027
?. 4 I 3 '.i 7 4 ~ >5i I 6 0 0000 4 ~ 34') 7 2 ">11 )7 2 ~ '$056 0 0000 I %6476
'> I c.'J 7 2 ~ 6 f30 0 ~ 0000 ?%6640 c'5 l:I '.i 7 I ~ 39c)($ 0 ~ 0000 0%')6'30 2131 57 3 ~ 4 9c)0 0%0000 1 5942 21:52 !>7 3 ~ 4 950 0 ~ 0000, 0 ~ 0000
?I $ 5:i7 I. ~ 7966 0 ~ 0000 0 ~ 2') 94
'i'1 b7 3 '920 0 ~ 0000 n.oooo
?d Sd 57 c'. ~ 7c) Sb 0 ~ 0000 0%0000 22.5 9 57 3.n95o 0 0000 o.oooo
? $ 51 5)7 7$ ~ I 366 0 ~ 0000 2 ~ 3 74?.
23J2 57 7'%4292 0 ~ 0000 o.oooo 2 333 !i'/ ') ~ I Ion 0 F 0000 O.oooo 24 Il 57 5-1022 0 ~ 0000 I ~ ')470
?4 32 v7 6 ~ lboo 0 F 0000 i~ f>3 I fi 2
?43.5 !i f 6 ~ I 0.52 0 ~ 0000 c' l I'73 I I ci.f 6 ~ I nn? n.oooo n. ia,nf
.' I..'i "7 ~
f c /i) i) ~ (II) II JJ ~
%)f Ji ~
~
I I
~ '.I "s ~ il i) ii n ii ~ IJ (I IJ (I ~ ~ ) IIII
~
f 0 ~ 0000 O ~ OOOO 2 I ') c! 5 f I ~ 0476 0 ~ 0000 0 0000
? 15;5 57 1% 04 76 0 ~ 0000 0 ~ 0000 2?51 57 I 7490 0%0000 0 ~ 7171 2252 5/ 2 ~ 4474 0 ~ 0000 n ~ 4(i'i3 2?!3 i 57 ;i. nnn2 0 ~ 0000 0 ~ f>31?.
? 5'i I !i7 6 ~ 226(5 0 ~ 0000 o.noon
'j/ 5% f5 150 0%0000 I ~ I 709 2353 57 6 ~ ".$ ($ 4 6 O.OOOO 0 ~ 0000 2451 57 5 ~ 91 18 I ~ 0980 2 ~ nfl I 0 2452 c 4 ~ 1346 0 ~ 0000 2 4447
- >7 52an 0 ~ 0000 0.$ 545
?'>!>1 >7 4 ~ .$ 5 72 0 ~ 0000 5 ~ 01 f>f5 c.'!'> c! 5 7 n. 7Obn 0 F 0000 2 ~ J!5 nn 25!i.l ~> ~ 0556 0%0000 2 ~ f) 050
- I I 0 I 'i I I0 2208 0%0000 o.nnno 3I 02 !)7 9~ 0'f bb 0 ~ 0000 0 ~ ooon Sl 0 I 'i7 9~ i274 0 ~ 0000 0 ~ 0000
'5:)Ol 57 13 ~ 05')6 0 ~ I 7.$ 7 2.5nno
-Si202 5 7 I 1 ~ 3754 0 ~ 2454 2 ~ 1912
- $ 203 57 I 1 ~ )5402 0 ~ 0000 0 ~ 0000 330 1 >7 II ~ 4990 .0 ~ 0000 0 ~ 0000 3302 57 13 4646 0 ~ 0000 0 F 0000 3303 57 10 '780 0%0000 0 0000
'I Q !
F-20
! 'I e!!%!!e)
CI SLOI(OP I IYLL DATA ALL VALUF S ARE I N MILLLGRAMS/CUB1C METFA SAMPLF. CHLOROPHYLI A CH LOAOPHYLL 0 -CHLOAOPHYLL J40'I 57 8 ~ 0688 0 F 0000 0%3033 3402 57 (5 I ')8 0%0000 I ~ I 709
$ <<0.5 57 7 ~ 1470 n.oooo 0 ~ 0630
.Sl I I !i7 ?<< ~ l<<16 0 ~ 2376 0%<<656
.5112 57 15 ~ 15<<8 0 ~ 0000 1 ~ .5486 3113 )7 17%))<<H<< 0 F 0000 0 ~ 2214' 3211 57 1<<743(S 0 ~ 1020 ~ 8968 J? 12 .57 17 '036 0 F 0000 o.oooo
.5? 13 !) 7 17 '826 I ~ 216H ?. ~ 7134
.I Sl I 57 t3 ~ 1,$ 36 0%0000 0 7<<76 3J12 87 7 ~ YtS74 0 ~ 0000 2 ~ 5~) 01
.5 '51.5 s/ 0 <<0!i8 0%0000 ? ~ 2083
'.5<< I I 57 !i ~ 4666 0 F 0000 I ~ 3360 34 I c'! 57 6 0016
~ 0 ~ 0000 I ~ (!555 S<< 1.3 57 6 ~ 5760 0 ~ 0000 0 0000
$ 1.31 !i 7 '7 ~ .3070 0 ~ 0000 0 ~ 0000
.$ 1 J2 0 '960 0 ~ 0000 0 (SGO L I 3133 5 (3 ~ I 3b6 0 ~ 0000 2.3742
'3231 57 '7 ~ 0 796 0 F 0000 0 F 0000 I 32 J2 57 .. 11 '146 0 ~ 0000 0 ~ I) 36(3 52 S.'3 !)
7 t$ 4 0?. tl 0 F 0000 0 ~ 'i017 33JL ') 7 l. 3 ~ I' 9(3 0 ~ 0000 1%0299 J '32 57 I!i ~ 62 76 0 0000 0 ~ 0000 3'333 !i7 I I ~ 563(S 0 ~ 0000 0%2709 3431 57 1$ % 0710 0 F 0000 I ~ 9?99
'$43~ 57 . 10 ~ 1670 0 ~ 0000 0%9345 5<<.S 3 !g 7 9 ~ <<) 716 0 ~ 0000 2 '929
$ I %i I !') 7 6 ~ !i 76(S O.oooo 0 0000
.I I:)2 !)7 () ~ 229 (3 0 ~ 0000 I ~ <<r(<.$ 3 515 5 i7 !) <<6()() (I ~ (I 0 (I (I ) I $ $ 5)]!
- 5. ~ w I !) 7 $ $ ~ I '$4<< )) ~ ()000 I ~ I 'I I rl
.'32') 2 !) 7 () e tS 0 I () 0 0000 I ~ 8555 32':~ S 57 !$ 300 0 0000 0 ~ 40(') 3
<<lol 57 I'3 '20<< I ~ 195 I ~ 3?36
<< IO2 7 15 '202 0%61?9 2 ~ ?.066 410 J li 7 I '.) ~ 379<< O.74<<O 2 '502 430$ 57 ? He 8822 2 '280 5 '049
<<202 57 31%0336 3 ~ 4425' 4 ~ 6)095
<<2PJ !)7 $ r) ~ 7'262 ~ 56'i.7 6%2190
<<.50 I ~
) 7 '7 ~ ()%7 () P 0 ~ 2073 4( 5)O
<<502 57 I 0 ~ J($ 9() 0 0007 I ~ 5066
<<J03 57 11 <<372 0 F 0000 I ~ 00(39
<<401 57 6 ~ 739H 0 ~ 0000 '3 '378
<<<<02 7 7%0090 0%0000 2 '5719
<<<<0.5 7 0 ~ 3622 0 ~ 05) I 0 4 ~ ') 7?9
C>ILUV I Ir) I IYI I)hrh ALI. VALUL5 AA<. I N M I L L I G13hhIS/CUI31 C I>C TF.A 5 hh>ti LL C I.ILOA OPI IYLL A CHLOIIOPHYLL 0 CHLrJROPliYLL
<<1>0 I 5f f /P.Sh 0 ~ 0000 0 ~ 0000
<<502 57 3 ~ 1428 0 ~ 0000 0.0000 4 ') 0.3 c)7 2 ~ 7<)36 0%'0000 n.norm
<< I I I ci / t <).31n6 I 3731 I ~ fin'39 4 I I 57 18 6162 ~ I 60') 5 I 93 f7 c'11.5
/5 16 ~ ?90<< I ~ P005 7. ~ J610 n 'lt 'i 7 27 ~ I Of36 6 '370 5888 10~3131
<<212 57 2 ts ~ 6626 I ~ I fs6 3n 4 21.5 lo 7 26 '262 I ~ f3 f385 0499 4 "jl I 57 ' ~ 00.30 0 ~ 0000 I ~ /) 266 4 31? /i 7 9 1072 0 ~ 0000 3 ~ 'i031 n 51.'3 '1 7 I Ac 73813 0 ~ 0000 I ~ 3407 nnt I D 7 cg ~ 7 70P 0 ~ 0000 I ~ 5<) ft I 44 I 57 9 ~ 4 06fs 0 ~ 0000 2 e 4/>86 c'<<13
)7 f. 7137<< Ocoooo P ~ 'i<<01 4 ~
il I 'i/ P ~ 38 o6 0 0000 I ~ >)4 /6
<<512 o7 I, ~ I /> 8 I.3 0 F 0000 I ~ 7601 n51 J ') 7 c' 4504 0 ~ 0000 2 ~ 09 19
<<131 )7 17 '86f> 0 ~ 0000 I ~ /> 03'7
< I J .5 ~
)7 ltd'598 I I ~ 4 J.72 0 ~ 0000 ~ 0 0 ts 9
<<)31 g7 15.:) 1 2O O.onoo 0 ~ 0000
/I ii 'I 57 I 5~ 94') 4 O.oono I ~ ') 185
/>'5 57 16 '698 0~ 4 779 0 0000
<<5.31 c)7 9 '560 0 ~ 0000 2~?AP7 433' 57 17 '606 2 ~ 4918 5 <<102 3,3J <J 7 0 ~ 7563 I 5f' 0 n<<31 4'7 8 7 70P. 0 ~ 0000 I ~ 5')81
/> 'I 52 57 f' c) '350 o.nono ?. ~ 0 <
hn 33 c) f 10 '700 0 ~ 0000 ? ~ ~)h I I n 5.s I o7 4 F 0110 n.oooo 4> . I! 0 c) 3 4 ) J/". ') f 5 ~ I <<58 n.oooo 0 ~ I '/$
/c ) I 4
/ i' /I+i 4 ',037/c
<< I;i I ~
) 7 /> ~ << I)? 0 0.0000 3 <<611 c
<<152 57 '.i ~ 75i/> 0 0 ~ 0000 2 ~ 353P I <<153 57 4 ~ <<1<)0 Ocoooo I ~ 8345
!D' npo I 57 c) ~ I 842 000000 I ~ 87,f:5 4 25c'. 57 11 '372 n.oooo I ~ 0089
<<2'iJ 57 I:I 6962 0 '566 5 ~ 3 <) 4 ")
4 3'i I ',i7 I 0 ~ 39P.6 0 ~ 0000 3 ~ 1332
<<J5c' 5 7 I I ~ I I'.)<) n ~ !3/> 'i I 6 ~ >)267 35J 57 0 ~ Cooo '0 ~ 0000 0 ~ 0000 n 4:-. I /3 7 7 '874 0 ~ 0000 P. ~ >3<<01
~ ~ 4452 D7 0 '76P 0 ~ 0000 I> ~ f5513
<<<<5J ".) 7 <) ~ 691 2 0 ~ 3171 I + f33f54
C I II.. I):1 0)) HYL OATA ALL VALUL' AAL' N M I L LIGAAMS/CI)H I C Ml= TEA SAMI)LE CHLOAOPHYLL A CHL OHOPHYLL CHLOROPHYLL C
<<5<) I 57 5 s 0222 0 ~ 0000 4901 57 3i7206 0 ~ 0000 2 i 1663
'.) 7 5 ~ r'! 16<< Ir2?46 <<<<3)4 1101197 I .1990 0 ~ 0000 0 ~ 96 30 I 102197 2 '982 0 ~ 0000 0 6512 110 5197 I ~ 5998 000000 0 +9630 1111197 I <<028 0 ~ 0000 2.589e I I I c? 197 I io<<76 o.oooo 0 0000 111 Jl')7 04 76 0 ~ 0000 '0 F 0000 I I '31 197 I ~ 0)I 76 0 ~ 0000 '0 ~ 0000 I I 3c! I r) 7 1 ~ 04 76 0 ~ 0000 n.oooo.
I I:531')7 I e 050() 0 F 0000 I 1209 I 1<)1197 152197 I ~ 74 90 0 0000 0 '971 I I ~ 3960 000000 0 ~ 0000 I I '; ~ 3197 1012 0 ~ 0000 P. ?578 I c'0 I 197 3,1<<88 0 ~ 0000 I ~ 7601 I .? 02 I 97 2 ~ <<<<74 0 ~ 0000 0 ~ 4653 I 20 J I r) 7 3 3744 0 ~ 0000 I ~ 9508 1211197 3 ~ 0840 0 ~ 0000 I ~ 3158 I
I IZIZI97
'r?
I 5197 I I ') 7
. 2 2
'936
'504
- ) 79 36
~
0 ~ 0000 0 ~ 0000 0 ~ ogoo
0 F 0000 o.nooo 0919 I 2 Ic'. I 'i 7 2 '444 0 ~ 0000 0 ~ 0000 I i! 3 3197 3 ~ 1488 000000 1.7enl 1?51197 3 ~ 145)8 0 ~ 0000 0 ~ I 3'35 1252197 2.<<4<<4 0 ~ 0000 0 ~ 0000 I )53197 4 II <<<< Oioono O.oooo I 301197 2 '966 0 0000 9 ~ 29')4 I .IOZ 197 c2d 7966 0 0000. 0 '99<<I I .! 0 'I I 9 7 0 ~ 0000 0 0000 ocoooo I 31 I lr)7 ~ 0952 000000 0 0000 1.312197 2 0982 0 0000 Oi6312 I 51 51') 7 0 ~ 0000 0 F 0000 0 ~ 0000 I .I 5 I I ') 7 I ~ 1)I 88 0 ~ 0000 1.76nl I .I 3 c.' ') 7
'I I I I ') 7 2 ~ 7c) 66 0 F 0000 0 '99<<
I <! ~ <<474 O.noon 0 46 ).3 I') f f <) / I! f 4"?>>I ') ) f) f) f) f) I): l.f fh I .I 3c' 8! .I ~ << I) I3) 0 0 F 0000 0 0000 I I'I 31') / ~ 7') 66 0.0000 o I <<01197 7 '226 o.nnoo r". ~ 0958 I <<OZ 191 0 ~ I) 0r.'ll 0 ~ 0000 0 ~ )817 I <<03197 7~ 7074 0 ~ 0000 b<<01 1411197 7~ 5000 0 ~ 0000 I ~ 5237 1<<12197 8 ~ <<240 0%0000 3906 I <<1.1197 9 <<068 0 oooo 2. <<<<I,6
F-23
(.IIL))I)()PIIY I)n Tn nl L VALU!: 5 AIIE I H Ir ILLI GRAYS /CUIS IC I>F. TEA
.'nlrb!)l. L CHLCIROPHYLL A C HLCIROPHYLL 0 CHLUI(OVHYLL 1>>.31197 9.nOr)e 0 ~ 0000 075?
1432197 OS56 ~ 0 F 0000 2 % (> >3 c) 0 I >>:I S I <<) 7 ~ 7. ()578 0 ~ 5070 I ~ t>515 i.' I) I I ') 7 I 7520 0 ~ 0000 2%r)237 10r! I ')7 0 0000 F 000000 i' 0 'I l ')7 2 ~ 7')6 ) 0 0000 0 ~ ?')')4 r? I I 1197 0%0000 0 F 0000 o.oooo 211 c.' ') 7 2 ~ rln 74 0 ~ 0000 0.<<653 21 I .31') 7 2 ~ 4 t) 7< )3
? I Il lr) ? 7')66
% 0 F 0000 O.?9c) <<
2 I 32 I ';.) 7 2> ~ <<474 0 ~ 0000 0 ~ <<633 c' 3 .5 I ') 7 r', ~ 09 I32 0 0000 0 ~ $ > 512 r! I!) I I 'i 7 ? ~ 7') 6f> 0%0000 0 299r>
15c'197 I ~ I<<60 0%0000 O.OOOO 2 I 'i,I I 'I 7 c' t> Son 0 F 0000 r! <<0'719
.! c 011') 7 i! ~ 1012 0%0000 c ~ r> 5 7t'.
? c' c. I 97 I 7n')0 0 ~ 0000 0 )7l 2 <<? 0:I I <) I I ~ 7490 0 ~ 0000 0 ~ 7971 2211 I c)7 ? . 036>> 0 0000 I 0I 35.
? '? I
~ ~
<<) 7 I ~ 7460 0 ~ 0000 o.oooo c'c! I S I ') 7 2 '444 0%0000 0 F 0000
?? 31 I r)7 2 ~ f 37(3 0.0000 1 I ot! 3 2<<'r' ')7 'c.' n 4 74 0 0000 0 r"..2 33197 r.' 0952 o.oooo O.OOOO
??Sllr)7 2.447n 0 F 0000 0 '653 c".? Sr.' 97 2% 4 4,74 0 ~ 0000 0 ~ c> t) 5.3 c'co 31')7 2 ~ 09)32 0 ~ 0000 0 ~ t>312 2.301 197 06') IS 0%0000 2.ooon
<<! 30r! I r) 7 .I ~ I> 900 o.oooo I ~ 5942 2 '303197 ..I ~ I 4 SIS 0 ~ 0000 0 'J35 23 I I I ')7 3 ~ 8472 0 F 0000 I ~ 42R3 231 ~>1 <<77 .3 ~ 4 332 O.OOOO I ~ 1499 2 31 31'97 ?%7966 0 ~ 0000 0.29nn
? I 31 I ')7 .I ~ 7794 O.oooo o.oooo 23.3 ' ') 7 2 'nnn 0 F 0000 0 ~ 0000
'3197 ? ~ 7966 0 F 0000 0%?994 c>.351 I:) 7 q.pnno 0 ~ 0000 I ~ 3158 2 3521')7 2 ~ 44 74 o.oooo 0%4653 r','3531 r) 7 c! ~ 796(> 0 ~ 0000 o. 29')n
? <<01 I ')7 7> ~ I 002 0%oooo 0 ~ S>607 r" r) 0 2 I 9 7 ;I ~ 7 A 24 0%0000 O. 7.",<<0 2<<<< 031 <<77 3 7 7<<)n 0 ~ 0000 O.OOOO 241 I I ') 7 c2 ~ 44 74 0 F 0000 0 4653 2)I I 2197 2 '966 0 ~ 0000 0 '994 2)) I;5197 I F 7<<60 0 ~ 0000 0 0000 0'
CIILO>>r)PI IYLL I)A Tn ALI. VALU AAI I <4 MfLL I ('>>AM~/CU(3 I C Mf: TE'I(
<) A Mr> I. I CHI 0 >>OPIIVLL A CHLOA()r)HYLL 13 CI~LOII()r)HVLL O.ooon Oo 133!i
)? <<.I I I ') /
P<<SP I,') 7 d.300 0 ~ nonn 0 ~ 4 I36 '3
?I< 531)/ ; ~
~ /9 <ih n.norm I) .?<<<) 4 rl, I) III)n i I /gl
,'4 1 I I 'I / I (<) F)
<':~' '< ) '< ~ /<< )<< <) +oooo
'><<r< 3197 /'i<<o n.oooo P ~ 1') 32 2!io I I c) r) ~ 1174 0 ~ 0000 'I ~ ')OP7 25oc'. I 97 4 ~ 7ti82 0 ~ 0000 I ~ F:() )36
>0 3197 'i 052
~
t'i 0 ~ oono I a 0584
"'i I I 19/ 'i~ 1762 0~0000 0~noon
<! gl 239/ <<77(I 0~0000 0 ~ 0000
- ! i I 31') / <<. 1934 O.oooo 0 ~ 0000 P.(i31 I ') 7 J~4920 0 0000 0 F 0000 25 J2197 3 ~ 7824 0 ~ 0000 0 ~ ')e40 2:i 33197 :3 ~ 84 72 0 ~ 0000 I ~ <<2FI 3
?'-<51 I ') 7 3 ~ <<302 0~0000 0 ~ 0000 2;52 I ') 7 3~ 0472 0 ~ 0000 I ~ <<283
~
r))) J197 << ~ 1934 0 ~ 0000 0 ~ nono 1101407 6 ~ 3876 0~0000 I ~ !i7 71 I 102207 6 '730 0&0000 0~0000 110 J2() 7 165O 0 ~ 0000 ,. I ~ 00 )0 1201207 ti F3016 0 ~ 0000 I o 85r)5 1202207 7.3<<7(3 0 ~ 0000 0 '630 1203207 7 ~ 4970 0 ~ 0000 0 ~ 0000 I 301? 07 10 ~ 0434 0 '891 '3e?991 1302207 Ioa3J926 0 ~ 0000 3 '332 I J0 3207 <) ~ <<06t) 0 ~ 0000 4<</36 I <<01207 13 ~ 121<< O.oooo I -3b37 1<<02207 12 ~ 48 78 Oeoooo 2 ~ I:370 140 3207 1 3a<<736 0 ~ 0000 2 '224 1111?07 7 '874 0%0000 2.5<<OI 1112207 6~45?4 Oaoooo 2 '214 IIIJ207 6 'r)24 0+0000 P ~ 0214 1211207 I) ~ 3846 n.oooo o.. oooo 121220 7 6 ~ 798() 0 0000 Oa2289 1213207 7 '73<< 0 ~ 0000 2 '617 I;31 1207 8 '084 0 ~ 0426 2 '804 I J12207 8 '702 '0 ~ 0000 I ~ 5901 I 31 J207 )'I. V928 0 ~ 5535 2 1702 I<< I 1207 13 IP<<4 n.oooo 2 I)P<< 3 1412207 I:I 839(3 0~0000 I F 0299 I <<I J207 I I~ 0596 0 '737 P ~ 'j<<40 1131207 3~ <<onn 0 ~ 0000 I 594P 1132207 . 3a 7824 0~0000 0 '8<<0 I I;I J207 '3 ~ 0 f)70 0 ~ 0000" ? 942<<
F-25 CIILOAt.lPISYLL 0 ATn ALL VALUt) 5 AAL I hl N ILL I GRAYS/ CUB I C h>E T(=R 54N,PI C I IL OAOPHYLL A CH LOAOPHYI L H >LOAOPIIYLL C I c! 3 I? 07 1 ~ 0')00 0 F 0000 <<%'ib')0 IP!32207 :3% 71 76 0 0000 0 ~ '> 197 I ".I 5? 0 7 c.' /996 0F 0000 I % ')Pf)0 1.$ ;3120 1 'I ~ I 3.36 0, 0000 0 ~ 74 7/)
IJ.S2207 HE 7702 0 ~ 0000 I 'i9P I' I '$3 5207 70(3<< 0 ~ 04?6 ~ 780<<
I /I 51201 I 2 ~ 07.30 0 ~ 0090 I ~ 0594 1432p07 I2 ~ '/1.54 0 ~ 1021 << ~ 3 3C)5 I 4.3.$ 207 I 0 ~ '3>)26 0 ~ 0000 1 ~ I 332 I I '.i I? 07 I ~ 6c) 02 0 F 0000 .3 ~ 6060 I I ~c.'c! 01 2 ~ 799 f) 0 ~ 0000 I ~ ')?60 I I ' '5 P 0 '/ . 1.7nf.o o.oooo' 0 0000F CS, I ii I 20 / J ~ <<332 ~ 0000 I ~ I <<99 I 2') 220 7, 5 ~ OIS4 0 0 F 0000 I ~ 31'iH 12'> J?07 I ~ 49HO 0 ~ 0000 I 5')<<P 2 I 0 I P.01 'i ~ 7<< 00 0 0000 0 ~ 0000 2102201 4 '930 O.Ion<< .3 ~ I tb 7 3
? I0 5?07 6 ~ I 0;3P 0 ~ 0000 ? ~ IH73 Zc'0 I 207 ') ~ 6P 1/) 0 5(371 3 '912 220c! 207 6 '384 0%0000 I ~ 7<< 30 220 3207 f) ~ 962 4 0%6336 3 ~ f>O')9
.Ol ZO1 :) ~ 0 I 7cj 0 ~ 0000 I <<1004 2302201 I I ~ 709<< 0 '<<0000 2 '696 c'.30.'I P. 0 7 I 1% 95:$ 2 0 '370 5 H506 2/>01207 10. 3,S00 0 4902 4 '155 Ill 3704
~
II c.'40c.'P U 7 0<<1356 'I ~ 61 10 2<<0 J') 07 I I) ~ .3)3') 6 0 ~ 0807 I ~ 'iob6 2>io I? 07 12 '370 0 0000 I ~ ') 119 250c'207 Iles I I ~ 15<<2t.t 0<<r)ooo I ~ f>191
'.) 0 .3 2 0 7 1.? ~ 0 7C) 13 0%0000 3 ~ 4!360 "111201 1 jnt) 0 ~ Of) 00 P ~ S!) SP 2 I I c.' 0 1 :i r fs')22, I) ~ 0 0 () () I ~ J 5 ),)
~ 'I I Sr'fl/ Slt << t. s) . (I IS ft >I I ~ >! ~ >
- ~
.". I I."01 'i ~ 7'if> () 0 ~ 0000 2?1220/ 7, 02<<2 0 ~ I 143 P ~ c>P 16
?213207 6 ~ '/:39(3 0 ~ 0000 '1 ~ 03 7(3 c".$ 1 1207 I0 ~ 39?.b 0 ~ 0000 .3 ~ 13 J2 2 31 2207 ') ~ 3<<20 0 '353 P 00<<3 P.;$ 1 .'$207 10 '926 0 0000 3 ~ I:5 32 2<< I 1207 9~ 0606 0 ~ 0000 Z<<1 2<<$ 2,20'1 IZ F 0150 0 ~ 4 I )35 4 ~ (>()P. 3 2'I I J207 12% 0150 0 ~ 41 05 /> ~ 66P 3 P'i I I 207 2206 0 ~ 0000 3 '900 251 c.'207 I? ~ 2602 0%0000 3 I')P.3 P'i I 3207 12 '722 0 ~ 0000 I ~ 5276 I
G
F 26
( I (L" f)Ai,)liI I YI I.
cXLL V A I t)ti 0 4INL I N M I L I IGAnMR/C()(3 1 C ME'C.A 5 Rl~il'LI= C IHL()A()IiHYLL A C ISLOAOPHYLL I) CI>LOAOPHYI L 21 31207 PE 7996 n>>bono 1 ~ 9260 2 1.322 07 .3 ~ 3744 0 ~ 0000 3 95RR 2133207 3 '096 0>>2661 3 51<<5 c"! J l?0 / 2 ~ /3 /R 0 0000 :I ~ I ORB" 2 c? .I 8 c.' 7 3 '71<< ,0 ~ 0000 c? ~ 3322
?.2,3.3? 07 3,>> ne 70 0 ~ 0000 ? ~ 9424 2 J 31207, 4 ~ />2?0 0 ~ 0000 J ~ 4611 2332207 cJ ~ 05 I) f> 0>>0000 7> ~ 31 16
? .I;3 320 7 f> ~ f>7f)0 0>> 12r.'7 <<i ~ ? 201 c! <<51207 I I ~ 7c)?4 n.oooo <<.n )f.2 2ri 3 c! 2 0 / 10 ~ 1002 o.ooao 3 ~ 74,34 PCi 3 J207 7 ~ ri JR2 0 ~ 0000 '2 7060 25.31207 ll>>7?46 0 ~ 1272 ?. ~ 0253 25J2207 15 '900 0 '9J6 10<<3
? "i.) 3 c' 7 1 << ~ 7<<3fl 0>>lo?0 ?' f3 96 e r' '> I c'I 7 ;.'. <<sn<< 0 ~ nnno >>0919 r
' '. ) c', c'. 0 '/ r'!>> 1012 0 ~ noal) ' >, gf>
r' '.> I2 i. / '3 ~ (I (I!) (I 0.(); l'()
? i' I r'(I 7 S,,S /n<< 0 ~ 000() . I ~ ')!r l)U c! c>52207 ,".. <<so<< n ~ 0000 2 ~ 0919 c'.'3>.3? 07 3>> I << fIf) O.oono I ~ /nn I
? 351?07 7 'R7<< 0>>0000 ::. 3rin I ri2? 0 / 6 ~ 7;390 0 ~ 0000 .I ~ 037(3 2353207 / ~ 376<< '0 ~ 0000 3.eence 5 1 20 / 6 ~ 7368 n>>0000 I >>4112 2452207 U ~ 0130 0 '692 738R-
? <<!> J? 07 / ~ 1500 n.oooo I ~ ('> f39 6
? 'i 5 I c'. 0 / 14 ~ 1720. 0 ~ 0000 2 '906
~> 5 1 i 2?. 0 7 14 ~ 39<<6 0 '202 :3 ~ 06? 7 2 5'a.l 2 0 7 12 '7??. 0 ~ 0000 I 5276
.'I I 01207 c". ~ 79 J6 0 ~ 0000 0 '0000
.31 022'07 ?>> 0952 0>>0000 a.oooa 3l 0 3207 2 '952 0 ~ 0000 o.nona
,3?01207 I ~ .396e 0 ~ 0000 0 F 0000 J?02207 1 ~ J9() 0 n.oooo 0 ~ 0000 520 Jc'07 I ~ 04 76 0>>0000 0>>0000 3.30 I 20 7 ? ~ 7936 n.oooo n.oooo
- I J 0 c.' 0 7 :I ~ t)4 12 0>>0000 0'>> 0000,
.I .3 () .'I? 0 7 .I ~ ri 332 o.aooo I I ri<)9
;s<<o I? 0 / :3 ~ 43 '3c'. 0 0000 "I >> I ri 99
- 5 ri 0 r".. 2 0 '/ ri >> '/0.34 0~ 0000 ,IMP?<<3 5<<0 J?07 .3>> R<<4?. 0~ 0000 0 0000
- 311 I? 07 3>> 0?5? 0>>0000 << ~ 12<<7 31 I c!207 1>> 7460 0 ~ 0000 0 ~ 0000
;51 I:3207 I >> 7460 0 ~ 0000 o.oonn
F-27 C)iL(SAOI~) (VLL OATA ALL VALUI-. 5 r>>ICE I N M I L L I G(l AMS/C()(3 I C NC TFA
~
SA)>>l>LI: CI.ILOHOPHYLL A CHLOAT)VHYLL 0 CHLOE(3$ >)(YLL
.Sr.' 120 / I ~ J9 6tS 0 0000 0%0000
$ 21220/ I $ 960
% 0 ~ 0000 0 ~ 0000
.5 c':I? 0 7 I ~ 7<<60 0 ~ 0000 0 0000 3 $ 1 I?07 J ~ I <<'i0 0 ~ 0000 0 1355 5 $ 12207 3% 658)3 O.. I <<r.) 5 ~ 54 ($ 6 I: S I '.I? 07 :3% I <<5(3 0 0000 0 I 3'35
'Sr> I 1?07 4 <<770 0 0000 0 ~ 0000
;5r> 12207 2 ~ 73r> 8 0 ~ 0000 I ~ <<($ 17 3:> I S207 n. 1.516 o.noon 0 ~ () I >>51
.$ 1
'I 1?()7 c', ~ 09'.i2 0 0000, 0 F 0000 3 I Sc'2 0'/ I ~ .3960 0 ~ 0000 o.nooo
- 31 J.520 7 I ~ .S') 6A 0 0000 F 0 ~ oooo 5 i!,.5 I 207 I ~ 7460 0 0000 o.onoo 32.5c.'207 cd 0952 0 0000 n.oooo 32 3.520 / I "$
960 0 0000 0 ~ 0000
- 3.$ I I 2() 7
'/ ~ 0890 0 0000 ~ P/lc)
$ 3.5 c>? () 7 <<. >Sano 0.0000 Cj ~ r> t) f> '3 3 5 $ .5c'07 C> ~ '$0 7(> 0 ~ 0000 I ~ '>'/71 S<<$ 1 >'0/ a ~ << t'> St; C> . OOOO I>,') <) O>)
- > ).';>>/ 1<< ' . ') () >f () () c/>/ 1?
5>> ),Sc'() / I ~ r>9r! 0 rc) ~ nooo O ~ OOOO 5 I '> I? 07 ?. 0') ".i 2 n.oooo o.oono S I '> r".? 0 / ?. ~ 0952 0 0000 o.norm I I 5.$ 20 7 ? ~ 0') 5?. o.noon 0 ~ 0000 3?! I r! 07 2 '936 0 ~ 0000 0 ~ 0000 3252207 2 '318 0 ~ 0000 o.onnn 52>s Jc! 07 ~ 7996 0 0000 I ~ 9260
<<101207 4 ~ I:516 0 0000 0 ~ Alnl
'> 102r! 07 '3 ~ l<<>$ >5 0 0000 I % 7T>0 I
<<103?o 7 << <<000 0 ~ 0000 0 65?2 4 >501207 3 ~ 7? 36 0%0000 3 ~ /929
<<202207 5 ~ 0870 0%0000 2 ~ >)r> 24 4>'.0 S207 3 ~ 08<<0 0%0000 I ~ 3158
<<301?0/ <<. 13<<6 0 ~ 0000 ?.<<n<<7 4.,$ 0? 207 3 ~ 3714 0 ~ 0000 2 ~ 5.3 2?
<<30:$ 207 3 ~ 7206 0 ~ 0000 ? ~ 1663 4'>01 ?.07 5 '048 0 ~ 000.0 c' 5191 4402207 << ~ <<030 0 ~ 0000 2 ~ 27>$ 8
<<<<0 SP07 4 ~ I 904 0 ~ 0000 0 ~ 0000 4501207 7 ~ 3146 0 ~ 4 056 5 0706
~
<<"02207 ).' 3 (> 2? 0 ~ 0510 4 57? c) r>>'0.$ ?.07 7 ~ 1500 0 ~ 0000 >)(5 )T
<< I I I c! 0 / .S ~ /054 0 0000 ? . t> I nt>
<< I I 2? 07 5 ~ <<.c) 50 0 ~ 0000 0 ~ nnoo r> I I $ 20/ 7($ ?, << 0%nnnO C) ')8<<O Q
F-28
~ <<<<<< <.> ~ '.!',><I< <<.;<,:<
CIILOAOPIIYLL DATA ALI VALUFS AAI=. I N I> I LL I GAAMS/CUt3 I C METEII SAMPLE C HLCAAPHYLL A CHLOACPHYLL 0 CHLOAI)PHYLL
<<21 1207 .3 ~ 371 4 0%0000 2 ~ J37.2
<<21"207 .3 a 0252 0~0000 n.12<<7
<<213207 I ~ .5744 0 F 0000 'I a <) ) t) 0
<<.31 1207 4 '728 0 F 0000 3 '270 4 31 c'.207 .'5 ~ 650 d 0 ~ 1479 .I ~ 3<< 06
<<.31.3207 3 ~ .56dh 0 0000 0>> 70;i6 hh I 1207 5 '932 '0 F 0000 0 '908 4<<12207 .7~ 7226 0 F 0000 2 '950 c< << I 3207 7:3704 0~ 1059 '0 ~ <' ) I
<<5I 1207 7 ~ Of$ 50 0~0000 I ?4'.i.3
<<51+207
- 6 '700 0 F 1227 '<<+220 I 451:3207 7~4 302 0~0000 ?. ~ 7060
<<131207 << ~ 0690 0~0000 2 '004 ht3c;207 3 ~ 785 0 F 0000 !2+6106
<< I SS?O7 3 ~ .3714 I) ~ 0000 .2 ~ 3 3c? 2 R,'? 3120 7 2 '340 0 0000 I ~ 4))17
<<232207 0 ~ 7206 0 F 0000 2 ~ 1663
<<23J207 3 '36?. 0 F 0000 2 '765 43:51207 4.4190 000000 I 0345 I
t<332207 4 ~ 7602 0%0000 I ~ 66!36
'i ~ 7!ih 0 I'i 32
~
<< '3.l J207 0 F 0000 2 ~
<<h '.31207 t) ~ f) 4 66 0 '619 ,:I ~ <562 7, c< 4 Sc!207 7 ~ 376<< 0 F 0000 . 5 ~ 8f<83 h<<33207 8 ~ 42<<0 0 F 0000 3 ~ 3906 4 ci 31207 7+0090 0 F 0000 c' 8719 4 532207 7 ~ 4940 0 F 0000 '0 F 0000 4 ~.S J'? 07 ' ~ 3622 0 F 0510 .4 "
'i 779
<<151?0 f 4 ~ 00 ISO 0 + 02'-) 7 . I ~ I'I!? 7 I ci2207 3 '589 0 ~ 1479 J:34 I!6
'liO c<
<< I 'i 3207 4 0.0000 h ~ ISOQ 3
<<251207 .5 ~ 0222 0 F 0000 ? ~ 49tt I
<<252207 .3 ~ 0? 22 0 F 0000 ? ~ 4')I31 4 c."3 5207 5 ()50tt 0 ~ 147') I ~ Sct t! r<
<'. I I.'t
'< I . I .! ~ < I . I). Itt..' 'i' 'tf E t
I 'I22') t I I~ ')65b 0 F 0000 'i <<7') l2.
<<S!i J20 7 ( 7256
~ 0 F 0000 '.I;722<<
<<<<51207 )\ ~ <<210 0 F 0000 I ~ 7640 4<<52207 7 '630 0 ~ 2874 << ~ <)0<<7 h<<5)3207 < ~ 9796 0 ~ 3591 4 ~ 5519 4 '!) I 2 0 7 0%0000
<< '2 20 7 7 ~ 4;30r?
7 ~ 5)61 0 0.0000
? <<7 Of<0 0 ~ .54 14 4 55J 207 7<< 150tS 0 F 0000 I ~ 6896 I I0 I2 I7 2 '400 0 F 0000 ,4 e 7 349 1 I 0 22 1 7 , .,...?. 7370...
~ 0 F 0000 '3 10)33cc I I OS? 17 2 '902 0+0000 '0, ~ t)312
F-29 C I IL GR CIR IIYLL DATA ALL VALUL= 5,AH/ I N fd ILL I GRAMS/ CUBI I C ML TEA 5)AMPLL-. C HL CIH CIP I I Y L L A CH LOI40PHYLL CIILDRCIPI IYLL C 120L217 2.n504 0 F 0000 2 ~ 0919 I 20 )21 7 2 '996 0%0000 I ~ 9260 IP0.32 I 7 2 '370 0 F 0000 3% I OI33 I J01217 0.6094 0%0000 0 F 0000 1302317 0 0740 0 F 0000 '3 ~ '.) 5f) 5 I 50J217 7 '382 0 F 00'00 2 ~ 7060 1401217'<<02217 6 'OJ2 0%0000 P ~ 1873 U~ 0380 0 F 0000 3 '690 I <<OJP.17 9 '606 0 F 0000 I ~ i?663 I I 11217 2 '304 0 F 0000 0 F 0000.
I I l?217 7 OO 0 F 0000 0 '971 1113217 2%0902 0 F 0000 0 ~ 63 I?
I P,. I 121 7 2 '902 0.0000 0 '31P.
1212217 2%1012 0 F 0000 2 '578 12.1 5217 .4504 0 F 0000 ?%0'I 19 I 311217 3 ~ OR <<-0 0 ~ 0000 1% 315I3 LJL2217 3% 1450 0 F 0000 0 '335 I JI 3217 .- '3 ~ 4.362 0 F 0000 2 ~ 7 765 I <<11217 9.0606. 0 F 0000 !) ~ 241 I 1412217 9 ~ <<060 0%0000 c' <<486 14 1 3P. I 7 . 0 ~ 4240 0 F 0000 ,3 ~ '3906 11;3121 7 P. ~ 7966 0 F 0000 0 '994 I 132217 2% 7378 O.OOOO 3 I OR
~ 3 113J217 ?%4504 0 F 0000 2 '919 1231217 PE 7348 0 F 0000 I 4017
~
1232217 2 '730 0 F 0000 2 '640 12 JJ217 F 10'L2 0 F 0000 2%25)78 I .3 .3 I 4.' 7 6 t3664 CI 0000 ? ~ ?090.
I '532P. 17 6%5820 0%0000 P ~ 91OQ 13'33217 6 452~p 0 F 0000 2 'P14 I 4 JI217 9 '606
- 0 F 0000 4 ~ 2411 I << '52 P. I 7, 9 'P24 0 F 0000 3 0588 I <<3 JP. I 7 2490 0 F 0000 2 ~ 3208 2101217'1022I7 2 ~ 7340 0 F 0000 I %401 7' 2 '982 0 F 0000 ~ f) 312 210J?17 I ~ 74qO 0 ~ 0000 II ~ 7971' 2201217 P. ~ 4444 0 F 0000 F 0000 2202217 3.0040 0 F 0000 I %,'3150 2?OJ217 2 '996 0 F 0000 I ~ 92() 0" P J0121 7 2 '348 0 ~ 00,00 I ~ 4817 2 502217 2 '474 0 F 0000 0 ~ <<65.3 2.30:52 I 7 2 '966 0 F 0000 0 '994 2401217 3 0870
~ 0%0000 2 '424 2402217 3 '362 0 F 0000 7765' 2403217 :3 ~ ORIO 0 F 0000 F 0000;.
F-30 e~t,.'4 t.'+I')'Lc'LL /It>>l?11! It'.<.) c)QI',)))LIW)I/t?>!>>.: i ~~
CHLOROPH OATA
~
c )>> ~ ... ALL..VALUES. ARE, .IN H,ILLI GRAMS/C UB I C METER
.N SAMPLE CI.ILOAOPHYLL A CHL OAOPHYLL 0 CHLOROPHYLL
?501217 6 ~ 1002 0 ~ 0000 0%56n7 p 5 n p. p. I 7 ~ )5% 5400 0%1060 2%0748 2')0 J21 7 5. 5400 0 F 1060 "..O740 211 Lr~ I 7 2. '.5856 0%0000 I ~ 6476 P.I122L7 ? %4444 0 ~ 0000 o.onoo
~ t) r'.113217 3 ~ 1400 0 ~ 0000 1.7enl 2r" I 121 7 ;.. 45o4 0 ~ 0000 ? %0919 2?.12217 ? ~ 0952. 0 ~ 0000, 0 00'0 0 P.? 13P. I 7 r.'%01? n.oooo ?,% 2578
>> ~
2 Jl I?17 ? ~ /996 0 ~ 0000 I ~ ') r260 2 J1 22 1 7 3 ~ 1450 0 ~ 0000 0 ~ 1335 r'3 l 32 17 c'. ~ 4474 040000 0%4653 r'. /I I I c2 I 7 3%6580 0 1479 3 ..5486 2412217 6.5142 -.- 0 ~ 0000 0%0391
?41 521 7 9 ~ I')942 0 ~ 2073 3 ~ r) 650 Pc) I 121 7 5 ~ 4070 0 ~ 0000 4 '457 2 512217 5 ~ 7540 0 ~ 0000 2 '532
'I 2!i 1.521 7 '.) ~ 75 10 0%0000 0 ~ 7266
~ >>
213121 7 LING2 '504 0 ~ 0000 P. ~ 0919 2132217 . 2%101?. 0%0000 ?%2578 c! I 3 J217 2 '378 0 ~ 0000 3 ~ 1003 223IP.I/ ?.4474 0 ~ 0000 0 '653 2232217 .5 0840 0 ~ 0000 I ~ .5150 2233?17 r2 ~ 796 6 n.oooo n.2994 c'331217 3 '408 0%0000 1%7601 23 3 2 P 1 / .... 3 0040.. 0%0000 I ~ J158 P 3 J .5 ? I7 3 '332 0%0000 I ~ 1499
?431217 9 ~ 7560 0%0000 c' 20?7
~.') .I r.'2 I 7 4402 0%0000 2%6355 2433217 4 ~ 64 16 o.4224 r) ~ r) 066 P531?17 6 '016 0 ~ 0000 I ~ 0555 2532217 5 '540 0 ~ 0000 2 '532 25:5,52 I 7 7F 1508 0 ~ 0000 I ~ 6?I 96 c.' 5I2 I7 3~ 0840 0 ~ 0000 I ~ 3158 215221 7 2 7966. 0 ~ 0000 0 ~ 2994 21!i J217 2 ~ /996 0 ~ 0000 I ~ 9260 2c!51 21 7 3%1408 0 ~ 0000 1.76nl 2252217 3%1488., 0 ~ 0000 I ~ 7601 2PSJ?17 I ~ 7460 0 ~ 0000 0%0000 2 I c) I r' 7 2%7966 0 ~ 0000 0%c'994 I
2 35221 7 3 '480 0%0000 I ~ 7601 I ~ 2.5537 I 7 3 ~ 4362 0 ~ 0000 P ~ //65
-1 2451217 I 0% 0434 0 '891 '5
~ ?99 I L,... 2452217... ..., 1 0 ~ 1052 0 ~ 0000 2 ~ 1,168
~ '>>
245 J217 ~
9 ~ 4068 o.oooo 2%4486
(.I li. (3) t l) I') ll VLL i)n rW ALL VALuI'5 Aftt= I N M I L L IGAAMS/CUI$ I C Mt= TE(t Sf)M&I r. CIHLOH(JPII YLL A CHLOI(0$)t(YLL t3 C 3L () IZ ()P I 5 Y L L C 255121 7 6 ~ 73)) 8 0 0000 J ~ 0370 2552217 6 '750 0 ~ 23?.5 2 5935 c?i53217 'i <<04(3 0 0000 ~ 5) I ') I 31ni?if P.
I .on 76 0 ~ 0000 0%0000 3 10%!2 I 7 n. 6<) ttn 'n.oooo 0 ~ 0000
'l I 0:52 I 7 1,$ Jf)H o.oono O.oonn 5'c?Oi 21 7 O. ()904 0 ~ 0000 0 ~ 0000 Ji! 022 I 7 I ~ 3c) 6t$ 0 ~ 0000 0 ~ 0000
'5 ().3i I 7 I ~ 3 elf) 0 0 ~ 0000 O.oono
.$ .30 I 21 7 9% 31 Ot3 0 ~ 0000 I ~ 13PS 3 Joc'2 I 7 b ~ 5760 0 ~ 0000 ocnooo
.5 JO:3? I 7 7 ~ 9110 0 ~ 0000 0 17'.iS 340121 f 9% P4 f)O 0 0000 0 ~ 6942 3'i 0221 7 9 ~ 65)40 o.ooon 0 ~ 0000 540 J217 t3 ~ 9586 0 ~ 0000 0 ~ 0000 JIII217 I ~ 04 76 0 0000 O.noon
$ 1 11!? I f I ~ 5') Ii t$ n.noon 0 0000
~
3113?17 I ~ 04 7f) 0 ~ 0000 () 0000 F
32112 l,7 I ~ OSOG o.ooon I 1289 5 c'. I c'2 I 7 I ~ 0506 0 ~ 0000 I ~ 1289 3? I J217 0% t)904 0 ~ 0000 0 ~ 0000
;$ 3 I I2 I 7 0 ~ 4 t320 (l ~ 0000 0%5)317 331?217 )3 ~ I 9'in 0 0000 0 ~ ncoo 3.51 J21 7 0%482(3 0 F 0000 0 St$ 17
- $ 41 I? 17 0 ~ 03PO 0 nnoo 0% 4 150 J412217 9 '9?? 0 ~ 0000 0 ~ nnno 54 1.52 I 7 9 I I )c () 0000 I .n.$ 2?
.31 31? I 7 I ~ 04 76 0 ~ 0000 o%oono 31J?P.17 I ~ 3960 0%0000 0 ~ nn(ln 31 J JP.17 I ~ 7460 0 ~ 0000 0 ~ 0000
- 523121 7 0 ~ 6904 0 ~ 0000 0%0000 3232? I 7 I ~ 7460 0 ~ 0000 0%0000 3P.;I:3?. I 7 I ~ .3960 0' 0000 0 ~ 0000
.33 31 21 7 7 ~ 6?36 0%0000 0 ~ 0000 3 3 .5 c! 2 I 7 6 ~ 9870 0 ~ 0000 0 oooo 3 33.$ P.17 7 ~ 97PR 0 ~ 0000 0 ~ 0000 34.$ 121 7 9. 1194 0%0000 I ~ 4 3?2 j 4) 32 c. I 7 10 '288 n.oooo o.ocon 3)i.l JP I I 9 ~ fi 60 f) n.oooo I .? f:63 n 101217 c' 0 902 n.oono cl ~ f) 312 4 I 0?? 17 . ~ 3($ o6 0 ~ 0000 'I ~ ? 74 P.
4 1 0J21 7 09t)2 ~ 0000 c? ~ 0 0.~31?.
4? 0 I P. I 7 2 ~ 44 74 0%0000 0 ~ 4 65).3 4202217 I ~ 74')0 0 ~ 0000 0 7971 4203217 I 0476 0 ~ 0000 o.oono t
F-32 Cl>LOROP HYLL OAT/>
ALL vnL UCS ARL ttd MtLL I GRAMSr<C UU I C I/O I I;R SA)4PLF. C HL OR t)P 5 YLL A1 CHL n>IOPHVL'L O CHL 0>lOP,IDYLL 4> '$01217 t>>7490 0 ~ 0000 0 '971 4:3022 I 7 ~ I >>9746 0>>? 196 ? ~ 99 )t) 4 30.$ 21 7 I ~ (>? f$ 4 0 ~ 22>30 4 ~ 7>3<33 r> <>0121 7 ). f)2no 0 0000 ? 1270 nno't 7 I 0 ~ 0434 0 '891 3 '99) 4403217 8 ~ 071 9 0 ~ 0000 I ~ 9299 450121 7 6 ~ 1062 0 ~ 0000 3 '139 4502217 n>>t)330 0>>0000 2 ~ I 129 I.nn93 4 5>).32 I 7 6>> 2?9'3 0>>0000 4 I I '12 17 i? ~ 09$ 2 $ 0 ~ 0000 0 ~ 631?
4112217 2 ~ 1012 0 ~ 0000 2 ~ 25/6
<<113?17 I ~ 74 60 0 ~ 0000 0 ~ 0000 nr" I 121 7 I ~ .3998 0 F 0000 0 ~ ') 630 421J217 I 39613 0 0000 0 ~ 0000 4> I I I? 17 312217 2 ~ 45J4 0-0000 3 'tt)5 4 2>> r>4 74 0 F 0000 0'>> 465:3 4;31.5217 2 F 1012 0 ~ 0000 r>57t3
'unit?17 AD 7762 0 ~ 0000 4 ~ !35 I 3' 44122)7 9 '294 O.O3en ~ 0207 4/> I J21 7 ..9 '042 0 ~ 0000 I ~ >3 765 4'i I 121 7 6>>1032 0 F 0000 2>> 1873 4'it2?17 7 ~ 1479 0>>0000 0 nf>.30
<>51 J217 1 ~ U49? 0>>0000 I ~ .I'> /l3 r>1312t7 I ~ 7490 0 ~ 0000 0 ~ f'911 4 I '52 <! I 7 2 ~ 1012 0 0000 2 ~ 2 )71$
'4 I 3.$ 21 7 l>>4028 0>>0000 ,2>>6896 nr? '31217 n. f>9154 0 ~ 0000 O.OOOO
'4 23?r? I 7 I. on 76 0 ~ 0000 -0 ~ 0000 42 3.$ 217 I 74') 0 0 ~ 0000 0 ~ 1971 4331217 2 ~ 1012 0>>0000 ? ~ r.'578 4 3:$ 2217 2>>4504 0>>0000 '2 ~ 0919 433J217 3 '362 0 ~ 0000 ?>>7165 4 4.3121 7 5 ~ 1204 0 ~ 0000 '3 ~ 1293 4432217 2 '3026 0 ~ OOQO 3 ~ !i 526 4 r>.3 J21 7 0 ~ 0710 0 ~ 0000 1.<)299 nti31217 >> ~ 1032 0 ~ 0000 2>>'I t)13 r>532217 F 5000 0 ~ 0000 I ~ 5237 453J217 6~ 04> 14 0 ~ 0000 '3>> 36')6 4 151 r' 7 2.n504 0 0000 ? ~ 011 <)
4 I5?r? 17. ? ~ 0 ') '.i?. n>>oooo 0 ~ >)>)>)O r> I )$ .'I / :! ~ 0 3')I> 0. nor) 0, I r>n<) I
<<r" 9 I r" I / I. 74 )0 ,0 F 0000 0 ~ '/9 /I n?5?r'I1 2 ~ / $ 4)3 0 ~ 0000 I ~ nl!17 r>253217 5'i $ 21 2 ~ 60$ 32 0 '123 <', ~ 2197 4 7 4>> 771? 0 ~ 0000 J ~ 29'i 2
F-33 I:I ILL)ttOI?tIYI L DATA AAh IN I> ILL I GA AMS/CUI) I C ME 7 EA
'S ALL VALU 5 A M I> L I'. CHLOAOPHYLL A CHLOAOPIIYLL H CHLOAOPHYLL 4 35 c'. 2 I 7 r.n 502 0 F 0000 2. TO(in 4.5<> J2 I7 7 ~ 7226 0 ~ 0000 2. n<758 I I3% 4210 0 ~ 0000 I ~ 7640 4 4!.ii:? I 7 T< ~ 7 7.32 0 ~ 0000 3 '247 4'4 5 J:! I 7 4190 0 F 0000 I ~ 0345 4 'i'i I c' 7 <> ~ .5') oe 0 ~ 0000 3 ~ 20 '57 4 'g!)c.'?. I r (i% 7.$ <)t3 0 0000 3 ~ 0370 ci'.)5 J2 I 7 <> ~ /.$ 6 I$ 0 ~ 0000 I ~ 4112 5101? I'r I ~ fn )0 0 ~ 0000 0 ~ f ') 7 I
'il 0221 r ')776 0 '098 )?? 4 510 J? 17 I ~ no? t) o.nooo c". ~ 5
'i201 2 I 7 0 ~ 7014 0 ~ 0000 I ~ c!9<i <$
5< 02?17 I ~ 05 0t> 0 ~ 0000 I 209
'i20321 7 1 ~ 4 02(I 0 F 0000 ? 5096
!> 01217
$ r52O o.onoo c' 4? '$7
'> 50?? I 7 I. r5so 0 ~ 0000 n.0~os 5 $ 0.5? I 7 ,? ~ <>0<32 0 ')l?3 2 2 I 'll 5401?. I 7 6 ~ I 0'32 0 ~ 0000 ? ~ 1873
<>40c.'c! I 7 .') ~ (I.'i 06 0 F 0000 4. 5116 5>i 0321 7 (3 ~ 934 0 0 '630 4 ~ ') 791
!'i I I I?. I 7 1.7n )0 0 0000 0% 7<771
.> I I c" c? I f I ~ 607? 0 0000 I ') 7')4
') l l J?17 'I ~ 40213 '0 0000
~ c ~ UI> 76 3? 11? 17 .3. n900 0 0000
~ 4 56') 0 5 i,' <<?. I 7 ? ~ 7 9 <7 6 0%0000 I ~ c)2fio 3?1321 7 .3 ~ 02.? 2 0 ~ 0000 ? ~ 4901
'.i;3 I I2 I 7 7% 7074 0 ~ 0000 2 ~ 5401
'.i.I I 22 I 7 5 ~ 6092 0 '670 I ~ <>0>>9 5 J I J c.' 7 4 ~ 4160 0 ~ 0000 0.?Of9 54 11217 L 0 ~ 6000 0%3'720 4 F 1496 541?21 7 0 '920 0 ~ 5535 ? ~ 1702 5(i I 321 7 Ln.elu 0 '913 5 I'519
!) I $ 121 7 I ~ 7550 0 ~ 0000 n.o"io 3 5> I J?% I 7 ~ 0J94 0 ~ 0000 3%4401 51JJc'17 I ~ 974 I> 0 ~ ?.1<)6 ? % <)<) 5t) 5? 1217 $ :5 ~ 1420 0 ~ 0000 0 F 0000
!)2 5321 7 3 '950 0 F 0000 0 ~ 0000 5J 3121 7 I I TI564
% 0 ~ 0000 0.>>430
'i '3 I '? I7 I2 ~ ?. 034 0 ~ 0000 c' 74 <30 55.$ J?l 7 I0 On(in 0 ~ 0000 4 ~ <7? )7
'.in.3 I 2 I 'r 10%6000 0 ~ 3 7c'.0 4 ~ I 4 ')>
5<<5.5217 I '3
~ t! I ')t3 0 ~ nonn I ~ 0%')')
!>I'>lc?LT c' .)t)ci(> 0%0000 I ~ cin 76
'i I i 2 2 I 1
'. 2 ~ f $ 4<5 0 ~ 0000 I ~ n)$ $ 7 Ql
Ctit'S<I)r) ISYL I On I' ALL VALUF. 5 . ASIL I V M I LL I GrtA MS/ COOIC MI=-rert SAMPLI: C I SL OAOPt I YL'L A CH LOHOPISYLL CWLnnnr HYLL
'.) I 5 I2 I 7 P ~ .I IS5b 0 ~ 0000 I ~ I'>47o
!$ 251217 4~0728 0 ~ 0000 J otiP 70
')c?5%2 I 7 3 ~ 65)$ 0 0 ~ 1479 :$ 4 8f
') 7!i3P I 7 3 '222 0 ~ 0000 2 ~ 49 I I) 1012 I 7 >? ri 504 0 ~ 0000 2.0919 610221 7 2~4 504 0 F 0000 ?e0919 v IOJ217 I ~ 7460 0 ~ 0000 0 ~ 0000 G201217 ' 0252 Oioooo 4 '247 6201!P I I p ~ 4!i04 0 0000 2 ~ 0') 19 tic! 0.$ % I 7 2 ~ 0 c) 02 0 ~ 0000 0. r> I I P t> 301217 8 ~ 0740 0 ~ 0000 3 F 5565 65t)22 I 7 11 ~ J f54 0 2454 2 ~ 1912 6.50'I? I 7 I0 ~ 7~) I r5 O.OOOO P ~ ')C 73' C) ni 0 I2 I 7 10 ~ 4544 0 0000 ~ 9509 ~
t>ri 02P I 7 ') ~ 4 6 t$ 6 0 ~ 0000 I 2f>63" r,ci0.$ 2 I 7 I n.. 0434 Oa0891 3 '991 t>>',0121 7 9 ~ 6c)h 2 0 '073 'So 4C) )0 t ) ' 0 >! >! I I I 0 ~ 00,56 O.oooo I ~ 7050 t>!50.$ 2 I 7 SOD 1022 0 ~ 0000 0 ~ rc c) I)?
bill%17. ~ 095?. 0 ~ 0000 0 ~ 0000 i':11%217 P ri Jon 0 0000 0919 t> I I $ 217 c! ~ J t$ 86 0 ~ 0000 'I ~ 2 742 bi~ I 121 7 J ~ 723G 0 ~ 0000 '5 ~ lc) 2c) .
f)? I 221 7 4 ~ 0720 0 0000 .I ~ 6270 b213P.17 '3 '206 0 ~ 0000 2 ~ 1663 t).$ I 121 7 10 '39riC) 0 ~ 0000 '4 a 7598 I> Sl i'?17 10 6ISOO 0 '720 1496 '
6,$ 1 J21 7 11 ~ f924 0 ~ 0000 ~ 0962 .
t)r>11217 I 0 ~ I!0 J6 0 ~ 0000 I ~ 7850 br> 12217 ') ~ 9 f ttf) 0 '182 85n8 t>413217 I 0 ~ 67ri 0 0 'i916 0 '964 b!) I 121 7 9 '060 '0 ~ 0000! 2 ~ ri 486 6!)12217 9 1224 0 F 0000 3 ~ 0 5 IS IS 6!'>1.5c' 7 0 ~ I 36t) 0 ~ 0000 Pa'$74P ul 31217 2 ~ 73fH 0 ~ 0000 ::5 '003 6 I '3
>? 2 I7 2 ~ 3IS>S6 0 ~ 0000 3 274P.
fi I,S.SP I 7 p. 44 74 0.0000 0 ~ 46'i 3 "
t) 2.$ 121 7 3 ~ 7236 0 F 0000 '3 ~ f c) P 9 t '3c'21 7 'i ~ 76 OP. 0~0000 I ~ 6686 As! '3:$ 2 I 7 h ~ 9968 0.0046 t:'.3 $ 1217 I? 0150 F Oen18'i ri ~ 66 >I:3 i).S:5? P. I7 11 ~ 7P76 0 '174 '3 ~ C)519 t)3 332 I 7 12.36n? 0 3003 4 '02h bn 31217 9 '590 0 oooo 5 ~ 90') 3 r>ri $ %2 I 7 I I) ~ '$.500 0 ~ 4') 0? ~
n ~ 31!i5
F-35 CIII OkUP IIYLL DATA ALL VALUES Akh I hf hS I L L I GAAh!Sr'CU I) IC h)ETEk 5 A h$ I~ L!-. CIRLOAOPISYLL A CHI Or I)OPISYLI 0 CI$ LOAOPIIYLL C
<c(i 3 321 7 I? <<230 0 ~ 0000 I (r9 S~i
()',i31217 1 I 1490 0 0000 Oeoooo
()~.$ 2? I 7 I O.<<wn<< 0 0000 I ~ 0'i 09 6') 332 I 7 c). 756n, 0 ~ 0000 ? o?(s? /
() 15 I 23 7 J ~ <<382 0 0000
~ I I <<99 (i I 5 4 c". I 7. .'I 4 362 n 0000 2 7/65
()I ) 5217 ? 7340 0 ~ 0000 I ~ <<017 6)~".) 1 c) 17 7 ~ << .5 i)2 0 ~ 0000 ? ~ 70/>0 r)i.'ac? c'. I 7 <<c 76'i2 0 ~ 0000 0 ~ 0 <<?0
()g )3217 Ac 13<<6 n.oooo 2 ~ 44(i 7 t>3JI?I7 I I ~ 7?.76 0 ~ 0174 .'3 ~ 6 ) 19
().Sci??. I 7 9 ~ 7') 60 0%0000 2 <<? f527
'() I!)321 7 1$ ) 7<<<<(3 0 ~ 0000 << ~ ~)9 $ 9
()<<c31? I 7 10 ~ 1670 0+0000 0 ) 3<<'.i~
Ci<<!ic? I 7 I 0 ~ '51 32 n ~ 0000 O.noon
/r << 'i .$ 2 I 7 12 197<< c) ~ 0000 (;.nnoo h '3 'a I ?. I 7 I0 ~ 04 3<< 0 '091 I ~ r?99 I 6!i!)c.':! I 7 f3 ~ ($ ..$ >0 0 ~ 0000 ?. ~ OA 2<<
6') c) J r! I 7 ($ ~ I 366 0 ~ 0000 ? 3 74?.
7I01217 ? ~ Oorq2 0 ~ 0000 0 ~ 0 0 r) n 7102 I 7 I ~ 3960 0 ~ 0000 o.onnn 7103? I l I ~ 04 76 0 ~ 0000 0 ~ 0000
/111217 3 ~ U<< 12 0 oooo o.oooo
'l'112? 1/ << ~ 5426 0 ~ 0000 ocnonn 7I I 32 I 7 :3 ~ 4920 0 ~ 0000 0 ~ Onnn
/ I J1217 J ~ 143(3 0+0000 0+ 133()
71 $ 22 I 7 c' 79 36 n ~ 0000 n.'oonn 71 3.521 7 ,5 ~ I 4 0(3 0 ~ 0000 I 76n I 7151217 '3 ~ I 792 0 ~ 0000 n ~ .3? 0<<
/ I,r) 221 7 1420 0 ~ 0000 0 ~ noon 7153?.17 ? ~ 09!) 2 n.nono 0 ~ 0000
'/20121 7 09') 2 0 ~ 0000 0 ~ 0000
'/ 8 I) ( '
2 I 7 ? F 0902 ~ 0000 n.63)?
lr'0.3? I 1 2.<<i<<7<< 0 ~ 0000 0 ~ <<(;5 5
/? I I?.17 3 V<<72 n 0000
~ l,<<?I!
lr'?? I l 5
<<. Is'$00 o.oooo 0 ~ <<i!$ 6 'I 7r' Sr' l << ~ (i I nn i) ~ nnnn I i'(i')
/I')r" l I 5 c /)'."e<< I)in)(I r
~
I'r I I) 6) l .' r l I. <<'ir!n 0 ~ 0000 J
I
~
~ > 'I Ii?
lr'.$ 21 / J ~ <<3 I? 0 ~ 0000 I ~ I 4 <I<)
7 r".5 I 2 I l 3 <<9fsn 0 ~ 0000 I ~ ')c)A 720c?21 7 3 '332 n.coon Icl<<'ln 725 J?. 17 .I ~ 70') 4 0~0000 2 ~ () 100 7301217, f) ~ 4 c)i54 0~0000 3.( <<uo 7.$ 022 I 7, HE 7702 0 ~ 0000 I +5901
F-36
~)
C !<I. (I A(1 I) 15YLL OATn nLL vnL Ul-. S Al)E. I N M I L L I GAAMS/Ct)(S I C MF. 3 (- Ir SnM>>LC CIILOHO()ISYI L n C HLOAOPIS YLL 13 CIILOBOI)IrYLL 730.1217 ') <<0'i 76 0 ~ 0000 ? ~ 6145
'I.i>>?17 9<<1224 0 0000 :5<<or P.R 7 312r' 7 9<<5:son '.oooo 0 'R40 7 I I:5?.17 10 0434 0<<0091 3 '991
/331 c'. I 7 I << I! ri h 2 0 ~ 0000 o.nono I 5.52c! I 'I R ~ 95 t'.6 000000 0<<0000 7.'3332 I 7 0 ~ (I 350 0 ~ 0000 ? ~ 0 n?.4 7401? I I ? (i <<8450 3<<0285 ,3 ~ 99 )4
'/4 02?. I 7 22 ~ 60 50 I ~ 2297 r.' l l 15 Ino 5?17 7411217 2 '5 ~ 0322 I ~ 1115 ';.. Inde
? 7 << I r.' 2 3 ~ 6492 I ~ I586 74 12? 17 2'I ~ .30 n.4895 2 ~ )176
'663 Sc.'r) 74 I 5?. I 7 <<4906 3 0 ~ ')OR I
/4.512 17 14 '242 0 ~ 0000 3 ~ 9513
/4 5221 I I ci ~ 5070 0 ~ 0000 3 ~ 00') 3
/43J?17 I 4 ~ 'r)(3 0<<0000 0 ~ 0000 U I () I rc? I7 2 ~ 0902 0 ~ 0000 0 ~ 6312
<<5 I 0 r'.? I7 ?. ~ 44 74 0 F 0000<< 0 <<46r)3 I'l l) 3217 2 '952 0 ~ 0000 0 ~ 0000 R111217 ...6 1650 0<<0000 1<<0050 t' I r'?. I 7 6 ~ nnri4 0 ~ 0000 o.oooo Ul I J21 / 6 ~ 4524 O.OOOO 2 ~ 0?. 14 8 I.512 I 7 5 '556 0 ~ 0000 '2' 685)0 R I 5221 7 3 ~ 1458 0 ~ 0000 0 ~ '1335 ll I 33? 17 .;I.r)n9 0 '392 5) ~ .)916 Il 15121/ 3 ~ 7(15 n 0 ~ 0000 ? ~ f) 106 i' 'i r! c' 7 ,S ~ I 4!iR 0 ~ 0000 0 ~ I;I Iri)
)s I ') I ~
I / ri I'e /.' rl, r)rl 0 ll , I .'i I rill il..'() I r' / li!I I )I 0 ~ 0000 r' ')4 r~n t I.! () c.' I I '. ~
'~ 9604 0 ~ 304 3 .I. 6Unn U?032 I 7 ?. ~ .I U56 0 <<0000 I ~ 6476 ll<<! I 121 7 7 ~ 0 2 n <<.' 0 ~ I I4 3 r? ~ 4276 R212217 <<1934 0 <<0000 0<<0000 Ur'13?17 7 ~ I r)9R 0 ~ 0000 6.5694 U 2.'5 I 2 I / . /r ~ 4830 o .0ooo ?. ~ 27r)(3 i<2:322 I 7 7064 0 ~0000 r' 0509 0233217 b<<4048 0 ~0000 ~ 5191 Ac'51217 ...3 <<,7854 0~ 0000 2 ~ 6106, rlr")2? I 7 4 ~ 3(i 0?. 0 .ooo0' 4 ~ r) 4:34 il I I?. I 7 S I O. 4) 5) 7n .0o00 3 ~ 5775 0 53221 7 lo<<6000 0 ~ 3720 n. In9s (S,5 33?. I 7 10 '44R 0 00000 4 5r)'9
~
R Ir)1217 U<<1366 0 <<' 0 0 0 c~ ~ 3742 1535221 7 . / ~ 3734 0 %0000 ? <<?617 I',I ).I? I / ') ~ 4 696 0~0000 r' 'r() In
F-37 l l ll I II<< tl'I I Yl I l>h I h
>ll I VAI l>l hill I ll tl I I I I>lthth'>/<<ttt Il I)l It Il
'.I>> )t>l l l Ill Ill>Ill II II I
~ > III I)Ill)I'IIYII Il l I II l It>ill'llII I l Ilail lt I ,' / ~ ~ ~
(t I I I' / I '>'I
>> "I ll .' I / >' ~ 't ll 'l f. I ~ 4 t.f> I .', t> 4 I I
>> ~
>> I,>
~
I i Il ~ I~ ~ >
I II ~
t I>> I rt I>' ll
>>r> I )r I'/ " ) I')00 I' 7701) ? ~ / )4
<lrl I 22 I 7 r.' ~ 6 r' I 0 13 i4 6'>V )
t>41.)21 / 30 ~ f)4 rt 0 3 '076 2 ~ 2<)0 ')
;)rt.) I? I 7 14 I 132:
llew 0 0000 '> ~ 2995 V. <l 3 I! 2 I 7 1072 0 0000 2 0463 l>rl I )217 I I ?t)?4 0~0000 r? ~ '>ll 7 7 t)4',)121 7 II ')!i6 2 0 2/06 I ~ '.) 197 l)rt 52? I 7 7 e 7tl /4 0 F 0000 c '>40)
II'>532 I 7 7 ~ 0492 0 F 0000 I .)578 0 'i 0 I ?. I7 9 ~ 4008 0.0250 0 0000 II502217 5020 0 0000 I ~ 4532 I!'iO )2 I 7 10 '0f)2 0 F 0000 .I. /434
>>>= I ),217 ') ~ f.),? 00 0 0000 r~ ~ 72 70 I>'>1 ~? 1 7 10 ~ 0404 0 19<39 I ~ 6725 I! Ii I .)? I 7 10 '300 0~0000 I ~ )40 7 0 "~ 3121 / 1 r.' 3582 0 '199 1 ~ ?49?
A532217 13 ~ 8190 0 F 0000 I ~ 0?99
> "I J3? I 'r ) 4 ~ 045It 0 3304 2206 I>!i>i ) 21 7 5070 2 ~ 1243 5~ 3)40 It 5')? 2 I / I 1 ~ 0512 0 F 0000 I ?>)73 t) ">>'3? I / ',10 ~ 1640 0 F 0000 0 F 0000 I
I
4 APPENDIX G PHEOPHYTIN a CONCENTRATIONS AND PHEOPHYTIN INDICES
- Explanation of sample code used in Appendix G:
Example: sample f/ 1101185 1 1 0 1 18 5 a b c d e f a the first number refers to the sampling location; numbers 1 and 3 are upstream of BFNP, numbers 2 and 4 are opposite the intake.
b the second number refers to the boat collecting the sample (See Figure 4}.
c the third number refers to the depth (in meters) sampled.
d the fourth number refers to the replicate.
e the fifth and sixth numbers refer to the day of the month sampling took place.
f the seventh number refers to the month of sample collection.
Sample 1101185 was collected (a} upstream of BFNP by (b) boat f/ 1 from a (c) depth of 0 m, (d} first replicate, on the (e) 18th day of (f) May.
T~ ~
I li 1 J
G-1 I'tft-'I)fitIY I Itf DATA
. A L L V A L UF 5> A 8 F-...I N. H I L 4 I Gft Am 5 cc C V II I C MI= T f= tt S AMP L L PHEOPHYTIN INDFX P I I I=. E) P I I Y T I ct A I I 0 I I )3!3 .;.;4 ~ 0000 7 369?
...., I 10c? I itch 4 ~ nnnn -19 7047 I IOJlt!5i 0 ~ 0000 - I >>.?? <<n I I I I lt)5 I ~ 4 P.f56 3 ~ OI> 38 I I I;> I t>r Ocoooo - I I.?Inn I I I Jlft!i "* lc5000 2 c 8 II3ti 9 I I NI I)35 I 132 I tt~i P. ~
.0.0000 2500 lc762?.
')?<<n
...,, 3 I I 33 I <I5 0~ 0000 -I) c <<otto I I >I I U'j 0~ 0000 -2 0<<30 I I cic' I>!i 3+5000 0 !Lln I I 'i J I ftci 0 ~ 0000 -6 ~ 4 080 9 I c! O. I I 0!i 7 ~ 333.'I 13 '36<)
1202185 13 F 0000 -9 051:I I c OJlft5 3 '000 -8 105 ~ tc I? I I IA5 F 0000 10 ~ 5732 I 2 c' tl5 e.ee67 -11 ~ 0 I<<9
'. 'i 1
I 213105 ~ .', 5 ~ Ei667 -9 ~ 5319 Q I 2 3 2> I f1 5 ~ 0 ~ 0000 -7c 20')0 I ? .I:I I (I 5 .6 '0000 -t> ~ Aft fin I c!>"i I I 85 0 ~ 0000 0 0000 6 12521 85 125i31 85 0 ~
O.OOOO 0000 -O.AOIO
-3.2040 I J01105 P. ~ 0000 3 ~ cln 4 tt 9 ,1304! 185 2 Et 0 00 -8 8110 I303105 3oeooo.. -15 '190 I 311105 ~ 4545 15 4 >c)3 O 1312185 4.5000 ; It> tIA07 I I I J 105> 5.oooo -18 5031 13321 85 0 ~ 0000 60 70 Q . 113 3 I 85 0 ~ 0000 5>> 6070 1.351 I 05 o.oooo 0 ~ 0000 1352185 0 ~ 0000 -n.OO50
' I 3531 8!i 0 ~ 0000 o. ot)on 1 n0 I I 8!i,. .2c 6250, -II ~ Hgntt I 402185 3 '300 15 ~ t) J>>')
In OJ105 ~ >
2 '000 -10 01:lci
,1411185 3 '777 -c2 ~ 74 8 I4 I2 I t'I 5 2 '555 -30 ~ 8 IHS 9 1413105 I 431 I t)5 I<< 1111 F
5 ~ 2500
-0<) ~ 4717
-lb ~ HPIO 14 321H5 I ~ 5714 0 '?09 I<< JJIII5 0 0000 13 6170 I..., In)>1185 I <<n.' A~
0 0
~
~ 0000
~ 0000
-2. no
-ts
~
~
1o 0 I nt)
~ 8 ~
G-2 Iit ll.(JI>I(Y I IN I)ATA At L VALuc.5 Arer= IN w I LL I GA AMSrr cul) I c wrrt=.le I
5AM( Lr:. PI IC (3 P I'I Y T I N I NI)I=X Pt tr)AI>IIVr IN A
~hi l<<<<JIU5i 0 ~ 0000 -0 ~ 81 10 r?IOIIP5 I ~ 7500 -0 ~ An I 0 r' 0 r! I (15i 2 ~ 07 t>9 -3 ~ r) i~<<
..' 0.5 I 'S5 2 ~ '35 71 -I> ~ << t(tl I r' 0 F 0000 <) ~ 3 ') t') I I I I <<5 2 I I i? I ri 9 ~ r)6(i (:
0 0000 r'. I I J I (55> 7000 -r'Ii e 0 100 r'. I .'I I I <55i r' .Ir' <(5 2 '500 -3 .'56)n 2
~
0 ~ 0000 <> rri>7
' I:I .31 SI5 0 0000 - I "I 77<< 7
'> I I A"i 0 0000 I 6020
~
I 5 <' I I'i 0~0000 -H Or)01 21 > Sl t(5 0.0000 ~ <)t) 57
<'0 I I <i') 5 I <<<> <) I 'S ~,3 0 ri I c'.)r' I<'~ r! ~ )231 -12 7 55<)
a'r 0.3 I >I "> 0~ 0000 -I2 ~ 7".I'1:)
>21 I I <I'i 2.aHnn 5 ~ r.'. t I!)(>
'r" <! I <! I >5 5 I 90r) I -I H<<2'I 2<! I J I t!'> 2 ~ (33.'53 -5 n () ~ ni <>
2r 'I l I t<5 .s. noon -J.<)2<<) .
2 < . I c.' I! 5 I ~ 666 7 -0 'r>07 2r'.l I <>'.i I ~ 7500 -o. <<e.or 2"'~ I I H5 5 0000 -2 ~ r>4.5 I 2 b2 I H.> 0 ~ 0000 0 F 0010 2 <', > .5 I <55 000000 -0 0010F
.'011H "i I ~ R571 I ~
'r'021H >
2 1335 ~
7<>/<.'5 2 ()6.<
- .'<l 31 t(5 2 ~ n t>(>7 -9 21 I ')
~
.!,5 I I I )>:) I ~ A(3 r> n -2 ntl 51 2 I I 2 I tS!i I .I I 5".>
2 '625 r! snA33
<<.I><<AH 3 ~ 6 A n Ii
.. S 31 I ts'. 2.nooo -0 2rin I 2 I J.! I <5 r) 0 ~ 0000 -O.tin I ~
I I I H'>
r.'
O.OOOO -n 3g "in
~
2:('> I I t!5 0 ~ 0000 -:5 2 0ri ()
I 2 5<>2 I (551 O.OOOO -I a.l/> I 7 0 I?
<'<<0 RJ I <35 0~0000 -I 3r>l 7 I I I (3!i I ~ A571 I lr)&r>
"<<(I'!5'> I ~ 93 5,3
~
-2 ~ t(0 3'i r'lI 0 I I '<'1 6667 2 -0 ~ <)iitl f
<" << I' I <l ~ <)0 <) I
" I I'i 3 ~ Vol<<(>
r' I >
.Ia IAIA -tl ~ ) <) I
.!<< I I I >(5 2> ~ 00'00 -n e Jr">n r'n I I I <i'>
r'ri (r' t)
I ~ r) r'l <>
~ ')r< Ii>
I ~ ')0') I I ~ >)ri r'
"r,( >'<) ~ ~
I ~
G-3 I
l>III III'IIY I tin rn I ' .'
I IV r r hI.L ~ V hL(IL'5 h(t). I N h>>> I LL I GP AM5/CUU I C h<F. TC)t I Shhli~L<= P)4<= IOP 15Y T I N I N I)FX iPI II= APIIY T I hl A
<<>> ' 243 31<35 2 ~ 1111 -? ~ 9(> 5 f
?441105 0 ~ 0000 6070 c'4 i ~
I >><> 0 F 0000 4 ~ fi(I< 0 24'i 51 ti'> 2 ~ I'>6(i 7 >>'>>r 0 ~ <ir< 0'I I)
~
I ~.I It+ <.'.>0,5 I t'r!> F 0000 -3 ~ I>>'.
r 2!il 1105 (> F 0000 4 44,5 r51 <."I (55 2 '500 -3 3642~
r.'i I I I.II'j 2 F 0000 - I o>5:.> I
~
? >.51 1(55 2 '3000 r'r>>r>>
>>. o .>< ~ 5 ~ .
I e 03.5.5' 0 ~ 640<5
'667, -?.. ~ '.I c!?, I <
y>> i>>>>'> I I 155 d+0000 -:5 e I? 5'I t
?55? 165 F 0000 - 5~6A46
'500
(
+>><>r>>><<~<>>>>W>>><r>><
?'i:> I 7(
I y 5101 I "5 5
- 510>>! I I< "I I <.I'.i 2 2~ llll 6 ~ h6<'>7 - I
~
~ 0'. I r I . <)! 4<)
~
?>>'>>.!
.5 I 0.5 I 0!3 ? ~ 02 >0 gI I I,lr>4<1
.5 I I I I <55 4 '222 ) -<3I 8 I it?7
, 31 121 I'5 ?, ~ 0526 ~ 37 I I 5 I I:I I I!5i 4 '000 0300
.5 I 5 I I tl ~r 0 ~ 0000 -11 214('
;51 li'. 11>>5 2 0333 .l ~ 4 r< c> tl
>>) jt ~ ;5 1.5.> I 05 0 ~ 0000 q 1.5+6170
.51 5> I 1555 0 0000 ,-2.4n 50 51321 <55 0 ~ 0000 31;> '51<55 0 0000 ,'6 ~ 40!50
.5? (I I I i! '.i 3 '143 I I ?I)41
,5>>>>! I <I!i F 0000 -0 ~,3304
.520 3 I <55 4 ~ 1667 ,' I (55r<I!
321 1 I H>'i()
..3 '857 t 7:52?
3>>! I .5 I f55~' >
353 ~ < ~'I') I" 2 .5 I I I,'L:W 0 ~ 0000 5 ~ ? () r> (r I? Ir I 0') 0 ~ 0000
-'i ~ 6(57 0 3c! 5'31 05 0 ~ 0000 .-5 ho 70 3?5IIu5 O.oooo -4 00:)0
~
3'>>>>3' I IJ<g 0 ~ 0000 I -8 8'!>) I
.5; 'i.5 I <"..i 0 ~ 0000 I f>0<" 0
- 5 I 0 I I 0 'i 0 ~ 0000 'J ~ (>> I '> 0
'I Ior. I )5-.i 0 ~ 0000 '- I 0 ~ 4 I,'
3 50.11 05 0 ~ 0000 -7 ~ ? I)<)0 fl <
) ~ .> I i>>I>>
- I;31 I I 05 F 1000 - 53 f>420 3.51 21 05 .20?105 ~'7 7n<)7 ~
- 5 '5 l 31 <)<i 2 '000 'j-2 3.'? <)0
~ 0>'
( >
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1 r~ v
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I 4>>
G-4 P) )L'OP))Y I I N OAT A hLL VhLL)LS hRI; IN MILLI G)IAMS/C Uf) I C Ml:T~)f SAM)il PHEOPHYTIN INO I=X Pl (): OPHY T I t( A 33 I 1 0'.i I'I 3 4'? l)6
+ - I <) ~ 2<'4 0
'3 $ 32. I (55 2 ~ 54 5i4 -f> ~ f>4 f(.3
) 53.)10'i !i ~ !iooo -f> ~ 0 ') 7(>
I 5<> I I "9 0 ~ I 6(>7 -V.> nlo I I ><> I t('i 0 ~ 0000 - I
- b() PO I ") '> I I (5 > O.noon -lo(>0?0
)<in I I i)5 3 5714 -10 4 <>.I I
~
)lip ] 3 ~ I () () 0 -I l <~ I (i 0 I <<0 3 I <5'.j <) ~ 0000 -II. (> (( <<('>
34 I ( I '5'i I ~ 7<500 0 ~ nooo
(<<12 I <)5 2 ~ I fino ? 11:i
.5<<1 .5 I 05 2 ~ 0344 / ~ /FI<) '/
.5431 I A5 2 ~ 0 76<) -f> ~ 4 Al) I I<> I (5~> ? i l!ion -t) ~ I 70?
.I 'i 5 3 I 'I > 2 ~ i)75>n -4 ~ 4 f)5>(>
I/I!>1 I <5'3 2 ~ l)5'/ I 0 F 0000 54, ~ <.' ) "i 4.2500 0 ~ nooo
- I 4 '> 3 I I(5 4.5000 oaonno 4 1()1 145> 3 (3.5.5:5 -10 2".>2(5 4 1021(>)5 2 ')n:) I -I0 ~ (>5i1:I
F 9000 - I0 ~ ('i'>.53 4> I I I I d'!i I ~ <)f>00 -5 ~ ? nfi'i
'i I I? I I(""> c'~ I 15i4' -13 f>50 A 4 1 I 31 (35 ~ 03H<i -7 ~ 04 i'l 4 L.l I I 0<> 2 '385 - >3 ~ 7,50')
(i I I<.' A'i 2 ~ 727 5 9 a 0!i I 3 4 I I'I l f)'i 2 ~ ')2 30 -I2 ~ 7 ('.i')
4 I i> I I f<i 0~0000 -0 ~ )50 I 0
<< I 'ic> I >55 naonoo -I ~ f>02()
41 ..510" 0 ~ 0000 -.'5 ~ 'r'0 <<0
/i 2 0 I I P '> :I 0000 -5 ~ 20(>!i 420<.' f)b i' /5 00 -I7 ~ (>c'20 4 20:51 05 :3:I:I 3 -7 e h(1.9~>
'<2L L L>5 ? ~ 5000 7 ~ E>> t<)<>
4 <.' <! I A'i 2 '075 -6 ~ 24 7l(
4213105 2 '000 - I ~ <)?24 42>3llb5 0 ~ 0000 -- I ~ <)<'24 4e.(" I (55 0 F 0000 -5.44(>a 4 'r!,5 ) I A!i 0 ~ 0000 -2.40,50.
425 I I (55 0 0000 -3 ~ ?>5<<1 '.
4 <! >2 I (3!) 0 ~ 0000 0 noon 4 <!!i .I I 3.> o.nono 0 e oi)n()
4 30 I I!3!i ? ~ 7000 -A ~ 01 ()0 4 In? I )'5> 5 ~ 0000 -0 'I/)7 I 'i )A
/i I 0 5 I <'3> << '/'> i~ ~
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~
<U<<'>I IF ()li(IYT I A fsh I'h hl L VAL<.I<. <<~ n:e L- LL I ( <eh(d~/CU<'I I L')I=TCI'(
5h<<<PL I PIILOP I I Y r i I I I Nl) I: X Ii) IF I IPI IY T I 'I h
(<.5 I I I Cc~ 2 '200 -ts ~ (< I 0 "3
-I<31%1)t<<3 2 '(570 7 I 2(.s<)
II '5 I c) ~i 2. (Oon -I<< . 4< I t)n
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e< 3,3'!!!i 30/7 -0 Si')7~
5.5:5 I ti'> 3 ~ ) 6(>7 -7 0<< ts>s
~
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~
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<<c< I I I I) 5 1.1 333;3 <<<>
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<<< I i't)5 4 ~ (3 7!i 0 -.! 0 i .3 4 '>4
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n<<51) t55 0 ~ 0000 0 000D nn >% I t!6 000000 0 ~ onoo 4 i'< '> '3 I (s "> 0 ~ 0000 0 ~ oono
<< '>0 I I t!!i 2 ~ I C)(>'<> - c.' ? (< i'
<< ~O" I U'3 .2+5000 - 5 ~ ts<<<<<t 4 <<in.s I (I!i I ~ 7000 (I ~ Onon
(<'i) I I A<<i I ~ 7 )00 -t) ~ 320 <
4 '> I 'i I (' 2 '750 4 5,> <<'>4 4 ~ I S I t)!i I ~ 62:>0 0 4 nn(i
<<i.t ) I >3'i ) F 5000 0 ~ <<)0 I <<~
<< '>.5? I () ',i I (. 6(>7 0 ~ ?(<0 5
<< "i.5.3 I (3.> I+7500 -O.:I'On
<<;i'> I I fs'5 F 5000 -5 I 2(>.i 4'i i2 I 0.> ? ~ AS 71 -(i 4 >l!s )
~
4 5v".51 0'5 I ~ 37'50 2 ~ n(< 2(>
4p 4
G-6 IiIi I I (I P H Y T I N DATA
....... ALL VALUI=S .ARE ..IN MILLIGRAMS/CUOI C METER SAMPI E PHEOPHYTIN INDEX PI$ EOPHYT IN A
- I:$ 0 I 700 0 ~ 0000 0.0000 I...........,.. 1302700 .,... 0 ~ 0000 0 ~ 0000 1.303 700 0 '020 I ~ 6020
. 1311 700 0~0030 -?. ~ 4 0:$ 0 I J12/00 0 '050 -4 '050 I 31 $ 700 0 ~ 0000 0 ~ 0000 IJ31700 Oo0030 2 '030 IJ32700 0 ~ 0040 -3 '040 I 3$ $ 700 0 ~ 0010 -0 '010 I 351 700 0 ~ 0000 0 0000
~
, I 5 Ii 2 7 (l 0 ,0+0020 -I 6020 ~
I:$ 53700 0 '667 22 ~ 1076 1401700 2~6250 -5 9274 ~
. Ino 700 2 '750 -4 ~ 3?. 54 1403700 4~5000 8 ~ 971 2 1411700 ? ~ 6250 5 ~ g2 f4
. 1412700 , 2 '333 -4.56i57
'I 141.$ f 00 2 '250 -2.723n.
14J1700 F 0000 -2.n030
..,...... 1432700. 2 '286 -4 '05il 1433700 F 0000 -2alfi27
$ I' 8 2101700 3 '000 -2eAA'36 2 102700 F 0000 -3.nnn h 210 3700 4 '000 -n. 4 osfi 1101700 I F 5000 n.:$ 204 1101700..
pc 700 I%5000 0 '204 I I 0 0040 :$.20no e I 1(L5700 F 0000 -n.?453
. 1111700 ?. ~ I 018 -4 24 i3
~
1112700 2 ~ 3333 Ia5219 I 113700 I ~ 2500 I a441A 1131700 I ~ 3333 0 +001 I I 1.$ 2700 F 0000 on 1 3 I JJ700 6~0000 -3a444 5 1151700 . I ~ 6667 0~ 1602 II52700 0 F 0110 -0 Allp~
I 153700 F 0000 -5 '463
...., .I 201 700 .0 ~ 0000 0 ~ 0000 120?700 0 ~ 0000 0 0000 e I 20.5700 0 ~ 0000 0
~
~ 0000
....... 12 1700. I, .0.0000 0 ~ ,0000 12 I 2700 0~0000 0 ~ 0000 1213700 0 F 0010 -0 0010 F
1231700 000000 Oo0000 ~
123?700 0 ~ 0000 0 ~ 0000
G-7 I) I: I tl I t) I I Y T I N l)ATh ALL VALUL) S ARK I N MILLI'CiBAMS/CUOI C MI: I F H
!)AMI'Li PI IC APIARY T I N I Nl)t: X PHI-:f35>II Y T I N A I P 5.5100 0 ~ 0000 0%0000 I r?5 I 700 0 '020 I ~ f)nc) s)
I .? 'i. 5 7 00 0%ooln -n. IIO I O 21'I 111>0 I ~ 2tion I ri ri 10
~
2112 /00 2 '667 - 2 2 ')
P. ~ .5 21 1.5700 5 ~ Oonn -c)%f)<<'I I P. I:5 I 700 I % f>000 O.<<On5 2132700 1.5OOO 0 P. I 5 5 I'00 2%0000 -I ~ 201'i I!> I 700 2 I <<2') -2%<<U sl 2132 100 I ~ 71<<J -0 0 ISO I
~
I 5.5700 1%75)00 -0 ..32nri c I 1 00 'i F 0000 f) 4 .}.3 2202700 n.oooo - I . It<< 23
- .'Ptt -5700 ~ 0 00<<0 P (lrs 0 2r? I I 700 n% 0040 I ~ P ft 4 0 PP I P. 100 0 ~ 00<<0 -3 2040,
'2:5 I '100 0 OOP.O -I rioPO 2P J I 100 % F 0000 -r" ~ (')4.3 J P2 Sc.'700 3 0000 -I ~ 0<<I J 2r'.5700 6 F 0000 -3 n<<4'3.
% c'!) I 700 3 ~ 0000 - I ~ IP 5')
c? r."ir'00 2 '500 -I ~ 1 i > c'.'
is? .) J7(30 2%6000 3 ~ 60<<ri)
?,50 I 700 2 '333 .I~ Ors 50
? 302 r u'0 2%4000 -2 ~ Uo;55 2 30 J700 I ~ 62'.i 0 II ~ 4>>ttr.
"311 700 F 0000 ,1627 c! J1270II 2 '057 -3 ~ 2t.'4 I
- r. 33 '5 100 I r'50 P ~ '1P. 3<<
c.! .5 '3 I700 2 '3J3 -3 ~ 04 .'IU
).I J J100 0571 -0 ~ At) I I
'.Sc') I 700 I I} 533 - 0 ~ f.) 4 0 ti r..)2700 25OO -4 ~ ctf;f)2 P 3'>.5700 3 0000 I P.3')
P<<II17OO 2 ~ 1667 2 ~ 2 4 c,'3 r.i OP 700 I %6661 0 ~ I Gni.
2<<0.5 700 2 '667 -2 ~ P <<c'.0
'r! << I I "1 0 0 2 '057 I ~ Pt?4 I r'i I c.'1 0 0 ;>.nooo -I <)P.24 2<< 1.}700 I ~ 033:3 -0 s><<00 24 J I 700 I ~ 6>667 0 F 160?
243c! 700 F 0000 -0 r)61p 2<<J3700 2%6000 -3 t)0<<5
~
r <<51700 n.oo3o -c' 4 030
G-8 I >I:) II)I>)IY I IN VATh Al L VALut 5 nnL I N M I LLICnnM iCuuIC MCTen 5 n>cLC Pill= Q PHYTIhl INOEX P)ICOPI5Y f IN 4 <
2<<52700 5 F 0000 -? e bh:$ 3 245J700 F 0000 -0 7209 2')0 I 7l) 0 I i/)250 0 F> 1306 c' i 0? I l) 0 ? a 14?,9 ? ~ 4< A'31 2'30.$ 'I 00 ? ~ 53;SS - 3 ~ On:50
?'> l, I 700 2 ~ I F<? c) -2 ')$ 51
?!) I 4 700 I o 714;3 -0 ~ 0001 2:i I .'5 700 201667 -? 24?I3 ~
?5.51 Il)0 I @333 -0 Ano<) ~
*c"),5 c', 7 0 0 2 ~ 3,533 I ~ On 3)3 45J J700 F 0000 I ~ I<)< 10
, >>>700 I ~ 7143 ~0 ~ l) 90 I
? .i5? 700 I ~ 7!300 -0 ~ .5 c'04 2'.i> J 700 2 '000 5 ~ cln<<U
$ 101 /6 0+33 33 3 ~ ?Oh I Oc. I 6
~ ~
.$ 1 I F 0000 I ~ I? Ig<,
.I IOJ /6 I F 0000 I ~ I? I 4 "IL'f.
- 5201 76 0 ~ 0000 0~0000 5? Oc'6 0 ~ 0000 O.OOOO J?OJ 76 O.oooo I) o 0000
,f 5 SVI /6 0 '000 .I.O<<4.3 .
t 5 Soc'6 0 ~ 66 67 ? ~ 4<< 51 3,30 I /6 0 F 5000 I ~ ')22<<
~, "3<<0 I 76 I ~ 4500 c< iOA50 3 F< l) c' 6 I ~ 5714 I ~ 44 I c.
t 3<<OJ 7() I ~ 5333 AO?5
;Sl I I 76 I F 0000 o 5/o7 Sllc'6 0 F 0000 n.oooo J I I J 76 0 '000 I ~ ') 2? h Jd I I '/I> 0 ~ 0000 I 3(~17 Jc'14 76 0 ~ 0000 000000
.$ 21 J 76 0 ~ 0000 0 ~ 0000
'3 II I 76 F 0000 -n. n <306) 3 $ 12 7/> 0~5000 3.>>nn)$
JD I J 7f) 0 '500 I ~ OF< 5c5
.3<< I I 76 la3077 <<.no~I 3<<12 76 I ~ 3 )71 3 ~ I! F<F<FI
- Sh I J 76 Iv4?06 1 ~ l) 4 5 I.l I 76 0 '000 I 0?.? 4
$ 1 '5? I( 0 '000 I
~
~ ')c?h J I S,S IF) 0 o.$ 333 c'ln 5 ~ I 3?.5 I 76 0 ~ 0000 I ~ 361 7 32.32 76 0 ~ 0000 2o/?34 323 J '/6 n,oooo O.oooo
.SJJ? 76 I F 5000 0. F>4< 0>>
I l
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,G-9 i)I II()PI I Y TIN nnTA ALL VALUL. 5 A)tf I N M ILL It)AAMS/CUII I C MC TF.It 5AMI'Ll-.. I> HF. OPHYTIN INDC X PHFC)l)HYT IN h 33 5J 76 0 '500 .3 ~ 0<<.J)3
.I'i.l I 7C> I ~ I 0 I (5 4 o!>f)'.)7 5<<l >
76 I' 2000 fi ~ 0 0!30
'l<<'5 I ft> I ~ .It> J6 2 ')6 J'f
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'f ?0')
3 I '.>>> /6 I ~ 2!>00 I '<>5 I 76 Oioooo 0 ~ GOO I) 5?5>2 f6 0 ~ 0010 -O.>>010 52').5 f >: 0 ~ 0010 -I) 0010~
.I 3b I 2 o Oot)0 -0 /i'I)j)
~
3 3')2 76 2 '000 I 2P.16 II')I 76 I ~ 75)00 -0 I ti02 fi 101 '/6 0 '000 6 40(50 fi I o~ ff> I ~ 1<<r') 3 ~ 12 39 410 5 7C) I.OOOO 4 ~ << II5C>
fi!20 I /I> I e J333 ' Ci<<33
<<20? 76 I ~ 0000 ") ~ 04 f> J
<<?0.5 7!> I ~ 2727 'I ~ //>4 7
<<Jo I 76 I F 0000 7 ~ Ilfj')0
<< '.0>> f I) I ~ 4 16/ 72 5<<
<< 30 I 7( I ~ 6154 0 ~ )>I> I I
<<i <<0 1. '/ 6 I ~ 88I39 -I ~ lt) I 7 4 <<02 '/I> 3 ~ <<000 -6 ~ i'0(I51
<<40 3 7!> 2 ~ .>000 -'i 12t)<<
<<501 '/6 5.oooo -7~ j) 29 )
4 '=it) 2 76 I 5) 0000 C'.I 3 I
>j '.i I) 3, i'6 0 0160
~ - I? ~ I> I I! 0
<< I I I 76 0 ~ 8750 5 ~ 28t)t)
<< I I c' C) I ~ 0000 3 ~ .I ti<< 2 4113 76 0~0750 5 a 2I>6C)
)i 21 I /6 I ~ 0000 4 ~ <".i 7
<<r' 3 'f 6 I ~ 0000 5 ~ 0<<f> I
<<J I I /6 I ~ 230)5 4 )l I'.!) I
<<'.31 2 f6 I ~ 0000 7 ~ ?(I>) I
<<515 7() I ~ 1250 7 ~ 5692
<<<< I I 7!i 2 ~ C) 667 << ~ f. <<5>3
<<<<12 /I) 2 '000 -<<.nOS n 4 <<1,3 /6 2 ~ 5750 -4 .3?5<<
~
'>51 I /tl O.OIOO -O ~ 0100
<<512 7(> 0 '120 9 ~ (,120 4'll 3 fe Ie2n57 P ~ '32?9
<<131 76 0 '500 9 ~ I JI <<
<< I 5>i 7t: I ~ 0000 5 0<>63
Ps)Ill)f)I I Y T I lt l)A TA ALL VALIIL)S A>(4 I N ILL I GICAMS/CUI31C M> ME I'Ffl S <<MPLf. P IRC OI>IIY T I N I NDF.X PI IE OPHY I' N 4 is 1.3 J 76 0 ~ HP,I39 5 fl<< 73 is 2:31 7ti I 0000 5.on6J 76 I ~000(I << I I 56 is>i 5 5 7() I ~ 1429 3 ~ I? <9 cs 3 .I I '1 I'>
I ~ 6250 0 ~ 4 II ot>
<<3.32 76 I ~ 3000 J o i~040 l
is.'l 3 76 0 F 07')0 !) ~ c! Hf>f) is<<31 76 5>. oooo -?. ~ t) i) 3;3 76 I 6667 0 QUQ I is << 33 7f 0 '050 -is . n(>>o is!) J I '16 I ~ 2Q57 ? ~ 3?c"I is 5 52 '16 1~0000 5 f>070
<<.)53 16 2o<<000 )30 35 is 151 7v Q. C5OOO 6 ~ is QI30 is I 'i . 16 0909 I ~ si ~ .3667 i)15J 16 0 ~ f5 c5H9 'a>I<< 13 is 25>1 /6 I ~ 2(35 7 ? 32?9
.is 2's2 16 0 ~ 571 is 6 ~ 3? 7'I
<<253 76 I ~ 5000 0 ~ c)612 s 351 76 Oooooo 4 ~ QH.) I '
'16 0 ~ 5000 ~ tl 4 4 H I*i 5 7 (> 0 ~ OQIQ -0.)lo I t) is "') I 1() I ~ 7343 -0 Of'tl I
~
4!3 ".i e 7b I ~ 7143 -0 ~ OHOI
<<'.35 J 76 I ~ 8 333 0 et'><<OP.
I 101 86 0 ~ 0000 oooooo 1302 06 0 ~ 0000 O.OOOO I I O.l H(> 0 ~ 0000 0 Qt)00 1201 >>6 0 ~ 0000 o oooo l?n2 CC> 0 ~ 0000 o.oooo I 20 J 06 0 ~ 0000 0 ~ 0000 I Jo I V6 0 ~ 0010 Q ~ f>01 Q I '302 Hh 0 '030 -2~<<030 I. 30.5 U6 000000 0 ~ 0000 I 's 0 I I.'6 (3~0001 -5 ~ 04 (> 3 I i>02 06 5 5000 -6 a Q(57b li)OJ U6 0 '030 4030 I I I I 06 0~0050 -4 ~ 00'50 I I I C.')() 0 ~ 004 0 .-3 c'04 0 III I Qh 0 ~ 00 30 -2.
~
is O'IO 1?ll UQ Oooolo -0 AO I 0 1212) 86 O.OO2O -I ~ f>020 I 21.5 Hb 0 ~ 0000 0 ~ 0000 1311 06 2 '000 -<<+0050.
1312 U6 2~01lis -<< ~ If)52 I
l)t:lit)PIIY T I N F)ATA AI.L VALUI:5 AAI=, IN MILLI GAAMS/CUOI C METCR S AMPL)= PISFOPHY T I N I NDEX P HI= 0 P H Y 'T,l N 13IJ H6 2 '077 -r) ~ ."52 7c)
I <<11 fSe .3~ 2000 -ri 00 75~
I << I 2 c)fi 2 '500 - '3
~ 3r)4 2 Ii(I.I Hr) 2 ~ 4000 ->. ~ (c 0 3S I I .S I tl 6 0 0060 -4 '$ 060 11 '32 06 Oi0040 3 ~ 20<<0 I 133 t)6 0~0750 >) ~ ~~
I\hf 12.31 86 3.SOOO -2 '3036 I c! 5d Hb beoool -3.<<n<<:5 l?J,S t56 3 ~ 0000 -c! ~ 0)326 I 3.31 06 I ~ 8'.i 7 I - I ~ 7r)22 I:I:32 bb F 0000 -I I ~ 4'. c 3 I 33 06 I ~ 9167 0(926 l<<J I "tlb I a 7143 -0~2403 I <<.32 f56 2 ~ 2 143 -5 7612 ~
14 3.5 Of; 3 ~ 1667 - I << . Oc) 7e I I!'i I tlb 0~ 0000 I ~ J()17 1362 Ae o.oooo n 0000 I ISJ 86 0 F 0040 Ji20<<0 1251 06, 0 '070 -s.coro I c?!i2 c36 0 ~ 00'.io -4 ~ Doso I ZS.S H6 0 ~ 0060 OOhO 2101 L)(i 0 ~ 0000 0 0000
? 102 46 0 ~ 0010 0 ~ t) 0 I 0 210.5 He 0 ~ 0000 0 ~ 0000 ZZO I f36 0 ~ 0000 0 ~ 0000
>'202 f56 0 ~ 0000 O.noon 23! 03 c56 0 ~ 0010 -0 ~ tl 0 I 0 z301 06 1.6000 0 ~ <<DO'i 2.$ 0 c.'56 3~3333 -:3 ') c'.4 g 2>.$ 03 Ue F 0000 I a cli<? 3 2no I I ~ 0000 ') ~ h070 86 I ~ 12iO ub'<<U2 3 ~ I> ~
34 t) 2!<<n J tscp J+ 33') 3 ;3 ~:)24 9 2."in I Or> F 0000 -'.) ~ 206>i
~
? 502 c)6 ? F 0000 l ~ c)?.? 4 2 ".) I ) 3 tI 6 2 '057 ZO<< I c' I,l f)6 0 '070 "- a ~ fi070 2112 clb O O010 -O.ISO I 0
? 113 c3() 4.5000 4 ~ 4 fl y()
221 I )56 0 '030 -? ~ <<DJO
- 22) 12 t36 .O.OOln 0 ~ tlo I 0
?? i? I 3 f36 . 0 ~ 0040 -3 2040 ~
2311 Ue 3 '333 3 ~ or'! <<9
." 31? 66 2olb67 -n.nnsb
I'I.lIO I>I<Y I IN unra A I I. VALUI;5 AkLc IN tr ILL I (i ltAhl<5/CUSS I C tie I'I='l SA'I~VLE V'Hl='nPH YT IN INDFX PHFOPIRY T IN A 2313 86 3 ~ 7r) 00 -f) 5602~
2<<l 1 Uti 0 ~ 01 10 -tk ~ U I 10
?<<12 l)6 10 F 0000 -6eh(<H J 2)< I:I ('6 I ~ ') 206 2 e ')6.$ ?
c'51 I 1.3 I) 3e0000 -'.) 206')
") I c>
tk(> 2 ~ 28>57 - ?0<<l 5 ~
I 5 (s6 2 ~ .5333 -<<e5657
? I;5 I >56 0 '090 - 7 a?0') 0
~
I .S c. I I ('> 0'050 -<<e 005io
? I 'l.k I 5 f) O.oooo -4 '050 2231 (36 3 '333 -3 e <) c2 <<9 r3" (I (} 4 ~ OOOO -5 ~ 5>2fi9 223.$ IS 6 :3 ~ 5000 -5) ~ 76 72 c!3JI 1$ 6 F 0000 - J ~ I 2.39 r'J 32 8(> 2 ~ 18I$ 3 -<< ~ 2<< ') 3 I)6 2 ~ 0/14 -4 ~ I ()52 r".4 J I ?:n545 -6 h(<83~
?(< 3<? <>
() 2e5000 -6 ~ 000 4<
2)< '3;I Ikf: 2 ~ 4545 -f> ~ f>4l53 253l 66 3i5000 ->3, ~ b500 ci 'i 3 c.' t!6 2 '250 -r ~ 7?34
- 5) .'$.$ t36 .5 ~ 0000 -7 ~ 2 IS'.I I c! I 5 I tko oeoolo -O.801O 2 I 5c'. I') 0 F 00?0 I ~ 60?0 2I53 ,Ub 0 F 0000 0 ~ 0000 2c.'5 I 06 2?'ire F 0000 -I ~ 041.3 U6 0 ~ 0030 -c~ 4030
? r",i.$ 06 o..oono 5 2040 2 l'i I <I fr 2 ~ 2727 -o'e On <i3 23'.i2 06 F 0000 7 ~ 3 6 <)?.
?3'> 5 IS6 e.oooo -15 ~ I 3t$ 9
?.r<51 (I () 5e5000 -6e OI376 2<<52 lkf> 2e0000 - I ~ bt321
<< i 5
~
t$ 6 .3 ~ 33:I 3 -,3 ~ 9? 4 <)
. r..'>5 I 8fi 2 '571 -6 '001 c".i 5 r.'~c>
86 r! e 5000 0 r< 4 8 J tk () ?. ~ 0000 2 e 16'r!7 3101 86 0 ~ 0000 0 F 0000
.I I Ikc! I'6 0 ~ 0000 Oe0000.
I I 0.5 t<fr O.OOln -0 '<OIO S r') I 0 ~ 00;$ 0 -2 e 4 0 "IO I a' cr 06 0 ~ 0000 0 ~ 000()
Jc!0;S IS 6 0 F 0010 -0 tlolo
~
J 01 $ ISO 3 '333 -3 ~ ')c'49
.I .502 06 2.OOOO I ~ 4 (< I <5 I
~ I
0-13 t>t:ti()PI S Y I' N DATA C<<LL VALUES ARE IN MILLIGRAMS/CUBIC METER SAMPLE PttEOPHYT IN INDEX PHEOPHYTIN 3 303 H6 n.oooo -5 '269
.340 I H6 ~
2 ~ 4545 (>~64H3 34> 02 I)() 2 '300 -5 '269 340 J ti6 2 '545 -6 ~ ahfi3 J I I I ts6 I) ~ 0 030 2 c> 03()
.i I I 2 U() 0 0020 -I t)020
'31 I J <<')6 0 ~ 0020 -I ~ f>020 3211 0(> O. O I On 0100 c'S(i 0 ~ 0020 I 6080
;52 I 0 ~ 0000 ~ 0000 3<! I:5 ti6 < -f> ~ 00 f5 J:$ 1 J t<<6 &F 0000 I ahhltS
.Sh I I <<ic> 2 ~ 230(5 -5 52<<)9 54 I 2 <<6 2 '000 -7 6996
- i c> I .'5 <<I('> 2 '000 r 8 09')
Jl BI "6 0~0030 -2 4030 31,52 06 0 '020 -I ~ 6020 31 3.$ U() Ia5000 0 (>40(5 0~0090 ~ 2090 323 I J>(>
- Sr 3<<? (i 6 t3 ~ 0000 5 ~ Oc> 63
.52 '..5 06 0 ~ 0090 ~ 40HO J 331'() 2a3000 ~ 0060
.I 5$ 2 <<56 2~727 3 ~ 051J
;I S.i J >5() 2 '000 ~
> I 2>)4 I 9091 /<<4 2.5
'5c> J I 86 ~ ~
ih.i2 HO 2 4167 -6 ~ t<<t>ia<<)
HO ~.onoo ~ '!<<)h r" J I a I <<6 Oa0050 4 ~ 00 io "51')2 U6 o.ooso ~ 0050
.;5 I!5 J t56 0 '090 ~ I 090
$ 25 I t56 5 '000 .narc 3 '>'.) 2 t3<<) 0 OOHO C> ~ h Ofio Sr") J U6 2a2500 7622 4101 I$ 6, J 2500 4 <)b()2 4 102 H6 J.6667 ~ 725'I nloJ H6 4 F 0000 5269>
4201 06 3 '500 -I I
~ 5602 I> c'02 U(> 0 F 0140 2140 420 J ti6 3 '667 -7 ~ 04 <<I 0 4 301 06 2 '529 ~ O 4 30$ ? U6 2 '529 ~ On I I 4 503 86 2 '706 -10 49.$~ 1 hnol (56 2 '046 -7 . 12(s9 4402 86 Ia8500 ~ 4030
fil.ttt'II t<vrlit t)n rn nl.L Vnl Ut' htkL I N HILL GRAMS/CUIS I C 1 HE TEII 5 hit>i I 'i:. Ptt,,OIIYV I N l NOF.X PIIFOPHYT I N A nfio J IS fi 7 ~ 05?.6 5 ~ $ 667 4501 Qb 2 ~ 2857 -6 '602 fi 'ioa 1< fi 5 305i -8 7309 ~
<<"'3 fib I ~ 0571 I ~ 762?
4 I I I ub .3 ~ 0 000 <<i' I 65?
4112 06 7. ~ 7500 -3.:36n 2
<< I I J f36 3+7500 -ba5682
<<21 I Ab 6 ODO() -ba BQt?6
<<212 .3 ~ 0000 .I I? 39
~
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<<.31 I HG 3 '714 -15 ~ .$ 7')2 fi J I HG 2 ~ 4110 -0 ~ I') 921 J lib 2 ~ 3f'39 c.ll 9 ~<)3?<<
nn I I vh 2 ~ 4 f)97 -4 0 ~ 690fs Ii << I 2 ISfi 2 '571 -7 ~ 36')2 4<<I S 06 F 0000 -I ~ f34<<l'6
<<511 06 2 ~ 4545 ~ Cin l$ 3 ~
4512 2 '545 -6 o 64 tl.'3 Ufi 3 ~ 5714 -10 '0:31 fi I 31 it I> I 1 ~ DODO 7 ~ <<<<c) 3 0 fi 0 '050 -n. n A.io
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4:I:I;> t$ 6 2 '750 -)$ . ci5o0 4 .33.$ Ob 19 5000 -2i$ ~ 5 1 ie
<<4,$ 1 li6 2 F 0000 -3 ~ 0440 n<<i32 0G 2 5000 -low?520
'i <<:33 06 2a6250 I 1 ~ f35<<0 fi 531 Qb F 0000 -3 36<<2~
4 53? t$ 6 I ~ 0667 -2aoo?~i 4 j35 06 I+6667 0 i607 4151 t36 0 '060 -<< F 0060 4 152 0f) 0~0070 -5~6070 06 13 ~ 0000 -9 0513
<<251 Ub <<+oooo -9 ~ ?ll'i n2 32 I'I fi 0.OOOO -10 0')Pb, 4 '5.$ t36 2~5000 6 ~ << t)00 4 <<'i I 06 2.oooo <<37 nn52 Ab 2 '000 4 I I)'i 4n5.$ 06 2 '500 7 ~ 0<< tt I) ns51 06, I.e667 0 a41$ 06 4 I 5 06 F 0909 -3 ~ <<443
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?>>01 86 2 '000 -2 002r>i c'>>02 <<i 6 2 '3000 4055 r'c< 0.$ 96 6 ~ 5000 -7 ~ f<<R<)f) 2501 <) fr 0000 - I 0 r' a c<
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<<' 12 <)6 0 ~ 0020 - I f<<o?0 I I ri 6 ~
o.oo5o Oor>0 c!
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?212 96 3 '000 -!3 ~ 7t> 72 r'.213 96 3 ~ t3000 -t3 i 4 105
? ll I <It> 0.0070 60 70
?:512 c) () 0 F 0000 -'i ~ 04t) 5 2313 <)6 F 0001 <
~ ct c< c<,3 2c< 11 <)6 10 ~ 0000 -6 ~ bc< 0 3 pci I'2 ')6 0 '070 -5.(>07n 2cl I 3 ')6 0 '070 -'5 t.>0
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~ c) 21 <)6 >>ioooo -I Ilc<? 3 Sr?.3 I 96 ~
3%0000 -'> ~ 2 065 2a7500 >> '3 ~ .364 2
?2 J2 96 2d 3.3 <) 6 I ~ 0000 5.04() 3
<<!;S 5 I ')6 0 '060 -.>> 'OOoO 2.$ 5c' 06 F 0000 -? ~ t>>>.$ ~
)
'<3:3 <)6 000070 -!) ~ t) I) 7 0 r'>> 31 <<) (i 6.0000 -3 2<<3c c)6 7 F 0000 c< r < >3
>c< S.'3 <<) () >>inono -I ~ t)c) i~ 3 r'! <<i 51 ~
)f) 2 '000 -I ~ ?II I f<<
r") 32 96 I ~ 6(>6 7 0 ~ OPOI r! 53.'3 ')6 Sioonn -<<. ~ bc< 33 r' vb 0 ~ 00<) 0 -7 ?090 21 <<)2 ')6 0 '090 7 ~ 20'.)0
-<) ~ 05) 1.3 r'15J <) f> I3 ~ 0000
t>t'll()f)l<Y T I lt OATh
.hLL VALI)f:5 AICL< I I'I MI LL I <" f(AMS/CI)f)I C MF TI=II
!') A(4PL I T))II)OT)IIYTI N I Nl)f X I'>HF()PI IY T I N A r'r ~'<
I <7 f) 3 '667 -n ~ 7? l)<)
22<) <)6 0 ~ 0110 -(S ~ H I 10
<! <"..) 3 <)6 0 ~ 0100 -f) 0 100 P! .(5 I 96 0 ~ 00 30 2.hn3o I)2 96 0 ~ 0040 - 3e 20/<0 96 o.oooo 0 ~ 0000 551 96 F 0000 I oonl 3 5<~ 96 4'0000 -I.On2 J 2'i5.5 ')b 0 ~()66 7 n <)C:t32 h lnl 9 j) 0 0150 -I r? ~ 0150 4102 ')6 F 5000 -I )th4H 4103 <)6 2 e 1667 -r2 ~ r'hr! f)
<<201 <)6 I ~ 0909 5~ 3667
<<202 I ~ Qoon - -0 5010~
hZOJ <l6 2 '333 --5. Oh.)<3 4.501 <76 F 0000 -2 '/<33 4 502 <) 6 0 ~ 0040 -:3 '040 4 303 96 Oooo()0 -4 a Pot)o n<<01<)00 ~QQQ9 -I ~ '361 '/
4402 '76 2 '500 -I 3 ~
~
I 27< lt hno s 9f) F 0000 44 I II 4601 <)6 0 ~ 0100 -r) ~ 0 I 00 4' 02 <) tr 0<00<)0 -7 ~ r.'0') 0 4 ')0:I rl<) 0 ~ 00(I () -f< ~ 4 (lll()
') lr ~ tr/ 6/, <rh'<ll
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.I 0 ~ Or! Jo -It) ~ 4? Sr)
<<211 9() 2 ~ 3 J.33 3 + 04;Sll 4 r.' ')6 2 '000 -3 ~ Iln 4t) c.'?13 96 2 '333 '>657 n 511 96 0+0070 -5 (') 0 70 4 '312 96 0 ~ 0020 -I 60?0 n.s 1.5 l f> 0~0030 -P ~ ho SP nnll 'l () 2 '222 .I~ 7()h 7 96 9 'J33 5429
'000
<<41<.'4 I 3 96 9 -12 4')56 n 511 96 0 ~ OOQO -C . 4 Of)0 4512 96 0 ~ 0100 -<5 ~ 0 100
<<51 J c) 6 n.olon -Q.nloo 4 131 ')6 2af3000 4 F 4055 h I 32 '76 2~0000 I .? n I s hl I;5 <) 6 3 o?'inn <l 662 lt? .5 I 9() 2 333 -.'I ~ 04 3()
42 96 3~')000 2 ~ f< Q '3 f)
J<'<2 SJ <) 6 3 '5)00 -h ~ 96f)2
III ) f)) ~
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I'I'I()l)IIVI IN l)A I A A LL V AL I)I" 5 AS'(C . I N M I I L I G((AMS/CU8 I C METFA Ii I )L A M PISF OPHYTIN INDE X l)HFOPHYT IN A 4 J31 96 0 ~ 0000 0 ~ nnno 0 ~ 0000 0 ~ nnoo 4 J:$ 2 96 4 .'I;I 'I ')6 0 ~ Onln -0 ')OIO 44 SI 4 ~ 4000 -I I,(! I
~ Sh
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-7 ? 0') 0 4 '3,$ 3 ') () 0.0090 ~
41') I ')6 2 '500
- 3 ~ l()42 4 I')2 Ot) 0 ~ 0000 -6 ~ 4080 415 3 t)6 2 ~ 6f>67 -? ~ J?. 2 9 4251 96 2 ~ 3333 -I ~ )? 'II) 4 ".)2 <)6 3~5000 -2 (!8 36 4?5.$ ')6 0 ~ 0060 -4 ~ f!06)n 4 5 )I ') I') 0 ~ Ooln -0 ~ I! 0'I 0 Ob 0 ~ 0000 0 0000 4 J5,3 ')b 0 0000 o.nnno 4451 96 F 0000 - 15 I:3(19
~
r, ~" 4452 I)b 4 '000 -12 4 I l)5
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~ ~
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~
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9() 0 '080 -6 ~ 4 080 4 )Ja 96 0 '070 -'.i ~ (')070 o'.oo4o 3 ~ 2040 455J <)6 005 1101 57 I ~ 6000 (I ~ 4 1102 57 I ~ 0750 -3 '642
'I 103 5 7 I ~ 7500 -0 '$ 010 1201 5)7 F 0000 -3 ~ I 23')
F 0000 I 4 44,$
1202 5 /
~
120J 57 3 F 0000 -2 0(l2(.
~
2 '286 -4 08') I
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I IOI ) 7 1302 57 .3 5000 -5 '672
-Ines I .I 0 :I 57 .$ 2 000 -6 0075) 1401 57 4
~
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F 0000 - I )224~
1402 57 -3 2041 1405 57 2 '857 ~
I 7742 -I ~ I!42 J I I I 1112 I 5 lg 7 I ~ 7770
-I ~ C 021 1113 )) I Ii7057 -I 9?24
))? 4 ')
I )I I 57 3 ~ 333 3 I ~
J ~ 5000 -c' 88.36
'1 I 57 -3 ~ 4443 121.3 J7 6 F 0000 1.$ I 57 2 '000 ('0()O 1
I:$ 12 57 3 '333 -:S 25?0 2~0000 I 2:59 131J 57
I 't. H() I) lc Y r lw unrn ALL VALUf: 5 ARE I N h1 ILLIGRAMS/CUOI C ML TER 5 A h1r) LL PHC 0 P I I Y I' N I N f) F x IIIFOPHYIIN A I << I I J7 I ~ 916'/ -2 0))2)j~
I:i I 2 5>7 2 0909 e4ii I I:I I .I <j 7 2 3333 -n.!>):r 7 I I 3 I ') / 0 9231 IS ~ 0<) 0 I I 132 i7 2 ~ c! B5/ -.3 ~ 204 I I I S3 5/ 2~6000 -3 ~ on!i c>
1231 5) 7 0 '070 -5 fi070 I 2.5 0 ~ Oof) 0 0060
'j7 '040 c.'?
1.1 0 -.1 ~ 20<< 0 I .'531 !) 7 F 1667 -/.Ono(.
I 33c 57 3 '500 -6 ~ 5C)H2 I '5 SJ 2 ~ <<2)36 -4 'r)51
.1<<51 / 2 6001) -3c604'.j In 52 7 li7770 -0 '607 I <<.5:I !>7 4000 -2 >I 0 I 5.
e I I '> I '>7 ~ 0~ 00 SO -2 <<O'SO 113? 7 .I ~ 0000 ;>.Oe?6
, I I c>3 57 ? ~ ?500 -I Vf>? c' I '51 !i7 0 '020 I ~6020 I <! <3>2 57 0 0030 -c? 0 "So I '>,) j !i7 F
0 '020 - I a ni
~ 60<! 0
? lol ~
>7 I ~ 91;10 -3 ')? <<9 210~ D7 I ~ 7600 I c? 0 lr) 2 10.5 !)7 I ~ <)5Cj5 -4 ~ 72 i9
?201 !i 7 Ic8333 -0 e C)<<o)>.
2<! 02 r> '/
>>'() 3 2 '000 -/.nnSr r) 7 2 <<000 '-? ~ ISO '53
? 1()l 'i 7 F 0000 -I ~ ')?? 4 2JO2 57 2 ~ .1333 -I ~ On.'Il>
2.S 0:I 57 I ~ 8571 ~ -0 AII I I
?<<01 57 2 ~ 1250 -?a 723<<
2<<02 57 2 3 75io -4 3?'>4.
2><<0 J 57 2 F 0000 -I 9c.'2< 7 2.00on -0 ~ 72 0<)
25i0" c7 ? F 0000 0 ~. 7709
> <) 0.1 !>7 2 ~ 3:13 3 - I e'i? 19
?I I I 57 I ~ 7429 - I 2015~
2112 L)7 I ~ 7667 I t>0<! 0
~
? I I.S ">7 8<< A5 -3. )2n9
?c' I / 2 ~ 333.1 3 ~ ()4 3<>
2?12 '> 7 ? ~ 4? 0>) -n.o(5>>
<? 2 I .1 'j7 ?. ~ (3000 -<< ~ 4 0'i5 2.) I I 57 I ~ )166 / c> ~ 0 Dc. <g
?.S12 57 Ia9)()7 -? OA2C)
.'. 5 I .I 57 6429 I ~
0 fnoe
'c
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~
I 5 '> 7 F 0000 -0 4$ oc> $
r'> I 'I I rj 7 3 .333 5
~ -3 9249 r' i7 3 ~ 3 3.3 "3 -3 '249
.SrI 33 ",i 7 F 0000 -0 '6.12 r! r'..'I I 3 '333 - J<<9249 2r! J2 57 0000 -3 60')6
~
22:3 J r) 7 2<<5000 -2<<l>632
? 3J I ~>7 I ~ 6000 I ~ 2015 2'J2 67 l<<6923 0 ~ 0 f30 I
? '55 r$ 7 2 '500 -5'<<2 A66
- >4.$ I !i7 1 ~ 6() 67 0<<2403 r>4 J2 57 2 '500 J DP44 24
- I I >7 ~
?. F 0000 -2 1627~
') l j 7 5
~ ?. ~ 0000 -2 ~ 1627 2532 I5 7 2 <<1250 -?. ~ 7234) 2'i'S J rJ / 2<<0000 - I . 92? 4 r.' 5 I r} 7 J<<5000 -? IS rl:3h
~
r? 1)J~ .') 7 0 '030 -? ~ 40 50 c! 15J '>7 0 '030 -2 4 0'50
~
il lj 7 2 '000 - I <<:) H l6
- 5) !J 7<<0000 4 '45.3 225J 57 :5 F 0000 <<Of.'. <)
Sr) I ") 7 I F 0000 -{) ~ l50 I 0 2 J52 57 1 ~ OIS{$ 9 -I ~ 3f) 1 /
I 9000 I ~ 6020 2 35)3 5>7 ~
r" /I J I 5/ ?.. ~ 2!300 -J<'$21 r? '35,$ ") 7 ?. ~ 5000 - 3 ~ f344)3
- $ 101 IJ 7 2 ~ I 429 r36Ci2 J I Oc'. '.i / I ~ 933.'3 -2 'SOJ5 J10.$ ri / 54 55 -7 '493
'5?01 5> 7 2 ~ 052C> - ) ~ 3C>{) 7 J202 J7 2 ~ 12:)0 44{)O
.$ 2 0:I ".) 7 2 ~ I 075) -6 ~ r'! 4 '/ 0 3301 lJ 7 2 ~ 12 )0 -5 446{3 JJ02 57 2<<2222 - '/ 5 r~ r) 4 5303 57 I ~ 9 37'i -3 04 'Stl
G-20 I>" I il>I'IIYT I N DATA ALL VALUL>5 AAC IN MILL[GRAMS/CUHI C MI:TCR 5 AMI>LS: PI(I=..OPHY T I N I NOH X T>1$ CTIPNY T I N
.$ 401 57 2 ~ 4 000 60/0 34 04 '.> 7 2 ~ AJ:$ 3 -5~4468
- $ 40 J ? ~ 3333 -4 ~657~
.'3 l I I 57 2 '571 -10 01 3 I I ~> 57 I ~ 0000 -2 OOPS~
$ 113 > 7 1+8276 -P., ')6.$ 7 3211 JT 2 F 0000 -5 ~ 2!36ri 3>'! 12 57 I ~ 9630 -!i ~ 6137 I
.3c.'. I I 57 2 '769 7 ~ Ii4 i) II
.'3 $ 1 I 57 P. ~ 0000 -2 >38 J6
~
3 31 i? l> 7 2 '000 -n.ao60
- 3 $ 1.$ 57 2 ? 727
~ -5aon/>3 34 I I 57 2 '667
.4 '458 3>i 18 'i f 4 F 0000 -') ~ I 15P.
'sn 1,$ !37 I ~ 7?7 $ -0.2nn3
! I.31 !>7 I ~ 9206 -2 !36 32
~
$ 1 32 7 2 F 0000 I P,3')
3 I 3.$ I) 7 2 '000 -5. r>o /0 32,31 N7 I ~ 9333 -2 ~ >30 J!>
57 I ~ 5f ln ? F 16?7 J23c.'?3 I E 7 I 7>$ 57 -0 '612 33 Sl 5/ 9!>2n -4 '45:I
,I,. $ ,$ >> '>/ 2 ~ 0') 09 -6 ~ 88116 J3JJ ',0 7 F 0000 -1 OII'3 I
'34 3 I 57 3~0000 -8~ 3:3on JIi 32 57 2 ~ 727.3 -9 ~ SI "> I3
.3'i"J 3 'i7 2 ~ 0000 '3 ~ I I> 4 I 3 I '3 I 57 ? ~ 3750 -4 ~ 3?!i 4 3152 5 2 '500 -3 '2nn
-I 7-'7 315J PE 0000 ~ ')224
'3 '> I 57 >> ~ I 'I I >I -4 '45J 325>2 57 F 0000 -2 '0'30 3?!> I >7 2 ~ 3:$ 33 On 38 4101 )7 2 '5>00 60 /0 n 102 5 7 I ~ 0750 3 ~ .Ir>4 p '
n IOJ 57 2+4167 I 3 77/P 4201 17 2 ~ 0? 3:3 -Ill ~
-8 li110 133) 4202 '> 7 I ~ 9200 ~
4?0 J :>7 2 '610 -20 ? 7'.> 3
~
4 30 I .> 7 PE 0714 /i ~ I I>52 4 Ioe >7 2 ~ 0(>67 /i ~ 40 >5 4 30 I !>7 2 ~ r>154 -'i ~ 5 J I i) 4401 57 2 '22?. -3 ~ '/s>4 7 4402 > 7 2 '33$ -n.m657 4 >i O.S 57 I ~ 9231 -PE 3?29
1st ssU Pf!Y T I <V f)A TA ALL 'I/ALUf:S Aft 1'. IN hs ILL I GRATIS/CUD I C METER S Af>IP LE PHFOPHYT I N I Nf)f'X Pcs:-nPISVT IN A i> 501 57 2+6667 -c! c 3229
. nc>n2 >>'/ 3i0000 -.3 1739 is it) J "> / I ~600$ ) n.nooi 4 I I I cg 7 c~ ~ I is 01 -9 c t>t)71 4 I I c'1
- ) 7 c ~ c 400 -10 ~ 81 35 l,s 57 I F 8846 II<<is 8 4711 5'/ 2.2432 - If>~ 1001 421 c.'>
">/
'/
2 ~ Ot) 76 -I J 05t)4 c.' 3 ci I ~ OE 05 0 2 6 c) 4 Jl I 7 0 ~ 0000 17 7021
<<J12 57 7 4545> -ti. eis Cs3
<<J I J 57 2 '667 -9 2t) 16
~
4411 !i/ F 1667 -<<.nu 36 is is I c' 57 2a5<<55 -7 '493 is 1.$ !s7 I ~ 9167 -2 ~ 0 t.$ 26 is ci I I 7 la<<000 I ~ 701'5
<<512 >i/ F 0000 -3 '239 is '31.3 '>7 I ~ 7500 -0 1602 ~
is 1.$ 1 57 3 '333 -22 t)2/5 is I J2 >5 7 2 '333 7 a f>pc)5
>"s I 33 57 I+7C$ 95 1.3617 is 2.$ 1 57 ~ 2381 -9 '5IJ 4232 5'/ I.oe36 -2 '836 is c.'33 57 2~0000 -5 7ts /2
~
's,'$.$ 1 57 2 '714 -is c I hci2
!s .'!.'3Z 57 I ~ 7')3 I -7 I C2 7 i>3$ 3 57 2 '588 is ~ 's St> I Is/s Jl 4> / 2c3636 -!i 847 3
's is.'32 .>7 2 '000 -7 '090 57 F 0000 10 ~ 's 130 is '> II ~>7 3 0000 - is ~ I 6!)~2
<<sJ2 >3 7 is F 5000 -4 ~ 4 856 is '33 J rc '/ F 0000 Q ~ >)612 4 151 57 3 '500 -is ~ 96/>2 is I!sc.'s 57 2.4286 -4 ~ 0851 I r>3 57 I ~ 8571 -0 ~ 81 I >'!
4251 57 I ~ 928f> -2 5632 is 252 57 2 ~ 6154 -9 '31>)
i>25 J c) 7 2% 7333 -12 4155 is,! ':i I 'i 7 7. 0667 ~ i>P $ 5>
4 J>32 57 I ~ 7895 - I 3617 4 .I'i.s D7 0 ~ 0000 17 7071
~
4<<51 >3 7 7c0909 - I.i>nn3
/s is >32> 57 2. 0000 .I I "c? 39 445J 57 2 ~ 4 167 -6 ~ f! Ofsb
G-22 r EH()PH Y T I N I) A r A ALL VALUES AHE. IN MILLI GAAMS/CULIIC ME I'EA SAMPLE PHEOPHYTIN INOFX PIHEOPHYT IN.
<<SSI 57 I ~ 8000 -O.noos 4552 .57 2 '500. -3a3642 455J 57 3a2000 -ee007S 1101197 naoooo -I ~ 8423 11021 a7 ..6 F 0000 -'3 ~ 4443 I LOJ197 F 0000 -I ~ 84'23 1111197 4 F 0000 -' 8423 1112197 ". ....,...3 ~ 0000 -I ~ 0413 1113197 3 F 0000 -I ~ 0413 I I:3 I I c) 7 F 0000 o<<,13 1.132197 ... 3 o'0000 I ~ 0413 1133197 F 0000 I ~ 0413 1151197 F 5000 -I ~ 2816 LI!32197 n.oooo -I ~ 8<<2:3 I I '.i.5 I 97 0%0060 -n.noeo 12>01 I ')7 I ~ 8000 -0 4005 O2197 I+7500 -0 a 160?
120:3197 3 '333 -3 9?49~
1211197 F 5000 -n.<<OSe
.. 121 c! 197 . ,2 '667 -2 '229 I?13I97 I 7500
~ -0~ 160?
12 31 I ') 7 2 'b67 -2 ~ 32? 9 1232197 I 7500
~
-0' I 60?
I23 J I '.) 7 2 '500 I ~ 7 6??
1251 197 2~2500 -I ~ 7622 12521.97 F 5000 -2 '836 I?")3197 I ~ 1667 2 a 56:5?
,1301197 F 0000 -0 '61?
1,.302 I!)7 4 F 0000 .5.<)vari r)
I;.50'5197 0 ~ 0000 0 ~ 0000 LJ11197 F 0000 -? F 0026 1312197. .0 '571 4 '259 I.'31.5'197 0 ~ 0000 0 ~ 0000 I '5.51 1 c) 7 ?. ~ 2500 7622 1332197 I ~ 3333 1+7622 I '5'5 51 97 I ~ 7500 () ~ I (> 0?.
'5') ') 7 '.j(5) f(
I I I >I ~
t J~;.l 3t ~
I '66f) 7 O. I ed'?
1.5531 ') 7 0000 -3 ~ bf.'<<h I<<0 I I 97 I ~ 9167 -2 '826 140? I 97 2 ~ ? 727 -5 0<< b.5 InoJI 97 I ~ 7692 0 ~
7209'o0801 141 I I 97 I ~ 6923
.....14 121 97 .10.7857 -0 9612
~
I 4 1.31 97 I ~ 7500 -0 ~ 6408
G-23 P! tlOI)HY T IN I)ATA ALL VALUCS AH!= I N MILL,IC>AAMS/CUU I C MI'. TCII SAhlPLT= PHE OP!.I Y T I N I h!DE X PHFOPHYTIN 14 311<)7 I 7500 -o f)non I 4.521 9 7 1%0000 0%4105 I ') S.S I <)7 2 '909 -a.nnn 5 I 0 1 l<)7 5 F 0000 -2 f>n '3:I
~
? 10" I')7 3 5000 I> tl 36
? 103197 F 0000 -0 ~ <) f) I?.
c! 111197 0 ~ 0000 I ~ 361 7 2 I 121') 7 2 ~ 3 333 I ~ ')21 <)
2 I I '3 I ') 7 :3 ~ 5000 -? % tlQ,36
- c. 1311<)7 8F 0000 -5%046.3 2 I Jc) 7 I'%500 -0 ~ 1602 2 1331') 7 6 ~ 0000 -3 ~ nnn 3 151 I <) 7 F 0000 -0 ')bl?
? I")2197 2 '000 I ~ ?8 I f)
? 1531')7 F 0000 2n5:I 2c.'0 I I ') 7 6.OOOO -3 444~ 3 22021')7 F 0000 -2 ~ 643 3 220.5197 2 '000 I ~ ? f516 2c! I 1197 F 0000' -2 ~ Ofl'c?f) 2 2 I c? I >J 7 F 0000 -2 64 33
~
c.'21 3 I ') 7 7 F 0000 -7) ~ 24 33 c'? l l I c) 7 F 0000 I% I> >'I)> f>
321'.) 7 3 '000 -c! ~ Iltl 36 2'3 J I ') 7 ? F 0000 -0 ')!09 c', c!, J I I97 2 ~ 3333 -I ~ 5219
?'5 ' 'l l ') 7 ?. ~ 0000 -0 '20<)
')! 50 I I ) 7 6 ~ 0000 - f) 8 f3 ti
% <3 2.'0219 7 F 0000 -I ~ 2015 2 'I 0 J I ') 7 4%5000 -7> ~ 4 85fi 2.31 I I <)7 2%2000 -2 ~ 00? 5 c'.J I 21 <)7 2 '000 -2 '632 2 J I 'l l <)7 4%0000 -3% f)f34 6 c! 3 3 I I ') 7 ?%2000 -2%0025 23 321 <) 7 2.'3333 -I ~ 5?.1')
?.33 J I <) 7 F 0000 0 ~ 9() I?
2 3 'i I I <) 7 2%2500 -I % 76?2 2 3521')7 I ~ 7500 -0% 1602
- ? 35:I I ')7 2.OOOO -0 ~ 96 I?.
c'4 0 I 197 ?%0000 -2 '627 2402197 I ~ 0333 -0 '400 24 0:3 I c)7 ? ~ 2000 -2 '025
'2411197 2 33 J3,. I ~ 5219 241?107 2.6667 -2 3229 2<)131<) 7 ?%5000 -I ~ 2016-
G-24 I ': IUh)
I I IY I I hl I)A fA ALI. MALUf: 5 AAI IN V>I LL I GIIAh15/CI)01 0 N.F TEA rr A h) I) I F PHI=. 0 PHYT IN I NDFX PI~COPISYT IN A 2431 197 F 0000 -3 1239
?4 32197 2<<3333 -3<<043f!
P<<.S 3!r)7 e ~ 0000 -'.).O4f a 2451 I ') 7 I << I!4f)2 - I 521')~
"4521') 7 F 0000 I ~ C) )52 I 4g,SI>) f 2 '250 r' 7 r'34 i".) <) I I ') 7, I ~ f) 750 - I I? 14~
h
- ? 5 0 <<! I ') 7 r'. <<333;5 -J ~ 043)5 250 51') 7 2 ~ 142') ~ 4)l 3 I
?'> I I I ')7 I ~ H750 -I ~ I r~ I4 2 . I c'19 7 I ~ (5571 -0 ~ >SII I I 251 J I <)7 I ~ 5000 I ~ 2AI 6
;"i.l I I 9 7 I ~ 66K) 7 O. I I)02
? rJ S? 197 I 0335 -o. f>no)!
- -..IJI )r ? ~ ?000 -? 002 ~ )
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G-34 I>I I I(IPIIYT I t( OA TA ALL VALUI S A.'I IN N ILL I GRAYS/'CUB I C l4F T EII SA(1PLC P I II'. ()PHY T I N,'I Nf)EX PHI=GPI'YT IN A 515J? 17 I ~ 4000 I ?015 5251217 I ~ 7143 -0 0001 F
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APPENDIX H OVERBANK VS. CHANNEL STUDIES: SUSPENDED SOLIDS AND ORGANIC CONTENT DATA
- Explanation of sample code used in Appendix H:
Example: sample 8 6C0156 6 C 0 1 5 6 a b c d e f a the first number refers to the sampling location; number 6 is at TRM 296.9, number 7 is at TRM 298 .4, and number 9 is at TRM 295.4.
b - the second letter refers to the boat location (0 overbank, C ~ channel) (See Figure 2).
c - the third number refers to the depth (in meters} sampled.
d - the fourth number refers to the replicate.
e .- the fifth (or fifth and sixth) number refers to the day of the month sampling took place.
f- the last number refers to the month of sample collection.
Sample 6C0156 was'collected (a) at, TRM 296.9 in (b) the channel from a (c) depth of 0 m, (d) first replicate, on the (e) 5th day of (f) June.
OVERBANK VS. CllANNLL SUSPENDED SOLIDS AND ORGANIC CONTENT JUNE 5, 1977 ALL VALUES ARE IN GRAMS/LITER Sample Number Total Suspended Solids Organic Content 610156 . 0056 .0046 600256 .0050 .0046 600356 .0054 .0048 601156 .0092 .0050 601256 .0082 .0054 601356 .0090 .0048 603156 .0156 .0058 603256 .0146 .0054 603356 .0158 . 0056 6C0156 ,0064 .0032 6C0256 .0064 ~ 0036 6C0356 .0062 .0024 6C1156 .0072 .
0046'0042 6C1256 .0074 6C1356 .0070 .0042 6C3156 .0066 .0034 6C3256 .0076 .0028 6C3356 .0070 . 0040 6C5156 . 0086 .0054 6C5256 .0076 .0050 6C5356 .0078 .0048 700156 .0102 .0028 700256 .0102 .0032 700356 .0120 .0038 701156 .0136 .0044 701256 .0134 .0050 701356 .0140 .0064 703156 .0144 .0054 703256 .0150 .0062 703356 .0154 .0032-7C0156 .0054 .0014 7C0256 .0058 .0020 7C0356 .0060 .0048 7C1156 .0066 .0040 7C1256 .0060 .0042 7C1356 .0058 . 0040 7C3156 .0080 .0050 7C3256 .0066 .0046 7C3356 .0076 .0054 7C5156 . 0100, .0046 7C5256 . 0086 .0054 7C5356 ,0090 .0040
Sample Number Total Suspended Solids Organic Content 900156 .0092 . 0046 900256 .0068 .0038 900356 .0062 .0042 901156 .0086 .0030 901256 .0120 .0060 901356 .0108 .0050 903156 .0114 .0040 903256 .0126 .0044 903356 .0140 .0038 9C0156 .0052 .0046 9C0256 .0092 .0054 9C0356 .0060 .0040 9C1156 .0068 .0048 9C1256 .0066 .0042 9C1356 .0062 .0026 9C3156 .0066 .0024 9C3256 .0062 .0024 9C3356 ~ 0062 .0026 9C5156 .0082 .0028 9C5256 .0078 .0022 9C5356 .0082 .0030
OVERBANK VS. ('UANNEL SUSPENDED SOLIDS AND ORGANIC CONTENT JULY 5, 1977 ALL VALUES ARE IN GRAMS/LITER Sample Numbers Total Suspended Solids Organic Content, 6001057 ,.0030 .0034 6002057 .0024 .0030
~ 6003057 .0026 .0028 6011057 . 0026. .0032 6012057. .0132 .0078 6013057 .0100 .0060 6031057 .0384 .0068 6032057 .0330 .0058 6033057 .0016 .0064 6C01057 .0048 . 0030 6C02057 . 0044 .0030 6C03057 . 0048 .0036 6C11057 .0054 .0034 6C12057 .0052 .0044 6C13057 .0046 .0034 6C31057 .0036 .0024 6C32057 .0034 .0024 6C33057 .0036 .0024 6C51057 .0046 .0038 6C52057 .0052 .0038 6C53057 .0058 .0034 7001057 .0036 .0036 7002057 .0042 .0034 7003057 .0042 .0036 7011057 .0066 .0046 7012057 .0056 .0040 7013057 .0052 .0038 7031057 .0074 .0056 .,
7032057 . 008,6 .0044 7033057 . 0068 .0042 7C01057 .0030 .0044 7C02057 .0040 .0038 7C03057 .0028 .0042 7C11057 .0058 . 0046 7C12057 .0058 .0044 7C13057 .0064 .0050 7C31057 .0052 .0038 7C32057 .0038 .0032 7C33057 . 0044 .0036 7C51057 .0080 .0056 7C52057 '.0060 .0034 7C53097 .0072 .0036
Sample Number Total Suspended Solids Organic Content 9001057 . 0048 .0020 9002057 . 0058 .0030 9003057 .0042 .0022 9011057 . 0148 .0058 9012057 .0102 .0036 9013057 .0124 .0042 9031057. .0200 .0034 9032057 .0196 .0038 9033057 .0220 .0040 9C01057 . 0044. .0046 9C02057 . 0048 .0048 9C03057 . 0034 .0046 9C11057 . 0040 .0032 9C12057 . 0034 .0024 9C13057 .0006 .0018 9C31057 .0062 .0018 9C32057 .0080 .0014 9C33057 .0078 .0014 9C51057 .0054 .0016 9C52057 .0048 .0024 9C53057 .0070 .0022
OVERBANK VS ~ CHANNEL SUSPENDED SOLIDS AND ORGANIC CONTENT JULY 28, 1977 ALL VALUES ARE. IN GRAMS/LITER Sample Number Total Suspended Solids Organic Content 6001287 . 0108 .0032 6002287 .0102 .0038 6003287 .0120 .0028 6011287 .0132 .0056 6012287 ',. 0216 .0030 6013287 . 0122 .0032 6031287 . 0124 .0044 6032287 .0124 .0034 6033287 .0144 .0032 6C01287 .0064 .0028 6C02287, .0056 .0030 6C03287 ..0062 .0024 6C11287 .0044 .0032 6C12287 .0058 .0036 6C13287 Lost Lost 6C31287 .0078 .0038 6C32287 .0072 .0038 6C33287 .0146 .0052 6C51287 .0114 .0048 6C52287 .0062 .0034 6C53287 .0076 .0042 7001287 .0092 .0038 7002287 .0086 .0040 7003287 .0088 .0036 7011287 .0116 .0044 7012287 .0092 .0034 7013287 .0092 .0038 7031287 .0136 .0042 7032287 .0282 .0052 7033287 .0124 .0040 7C01287 .0066 .0032 7C02287 .0076 .0028 7C03287 .0056 .0030 7C11287 .0060 .0034 7C12287 .0072 .0034 7C13287 .0060 .0038 7C31287 .0068 .0018 7C32287 .0070 .0016 7C33287 .0070 .0018 7C51287 .0254 .0044 7C52287 .0090 .0030 7C53287 .0086 .0024
Sample Number Total Suspended Solids Organic Content 9001287 . 0176 .0036 9002287 . 0170 .0036 9003287 . 0184 .0034 9011287 . 0206 .. 0040 9012287 .0188 . 0032
'013287
.0192 . 0032 9031287 .0200 .0038 9032287 .. 0192 .0036 9033287 .0212 .
0034'0024 9C01287 .0064 9C02287 . 0052" ,. 0028 9C03287 .0062 .0026 9C11287 .0068 .0028 9C12287 .0064 .0026 9C13287 .0062 .0028 9C31287 .0074 .0022 9C32287 ..0062 '0026 9C33287 .0064 ~
.0024 9C51287 .0076 .0020 9C52287 .0078 .0022 9C53287 .0070 .0030 gP
APPENDIX I OVERBANK VS. CHANNEL STUDIES: ZOOPLANKTON BIOMASS DATA
- Explanation nf sample cnde used in Appendix I:
Example: sample II 6C0156 6 C 0 1 5 6 a b c d e f a - the first number refers to the sampling location; number,6 is at TRM 296.9, number 7 is at TRM 2/8.4, and number 9 is at TRM 295.4.
b the second letter refers to the boat location (0 = overbank, C ~ channel) (See Figure 2)'.
c - the third number refers to the'depth (in meters) sampled.
d the fourth number refers to the replicate.
e - the fifth (or fifth and sixth) number refers to the day of the month sampling took place.
f the last number refers to the month of sample collection.
Sample 6C0156 was collected (a) at TRM 296.9 in (b) the channel from a (c) depth of 0 m, (d) first replicate, on the (e) 5th day of (f) June.
ZOOPLANKTON BI ONASS OVERBANK VS. OlANNEL STUDY
.IUNE 5, 1977 Sample Number N Hean Variance Coefficient of Variatibn.
6 5 26. 16 141.43 45.45 6C015 6 10. 33 6C025 6 26. 85 6C0356 43. 11 6C0456 21. 67 6coss6 28. 84
- 6. 5 45.13 138. 73 26.10 600156 61.94 600256 43.56 600356 32.40 600456 36.64 600556 51.11 7 5 81.15 708.21 ,32. 79 700156 60.07 700256 77.83 700356 113.98 700456 51.79 7OOSS6 102.07 7 5 66. 12 149.94 18.51 7C0156 57. 99 7C0256 77. 85 7,C0356 74. 77 7C0456 71. 09 7CO556 48.90 9 5 89. 29, .711.77 29. 89 900156 99. 88 900256 62. 68 900356 130. 09 900456 71. 79 900556 81. 81 9 5 59. 20 1582. 00 67. 18 9C0156 75.13 9C0256 45.45 9C0356 45. 66 9C0456 117.98 9C0556 11.80
X-2 ZOOPLANKTON 13IOMASS OVERBANK VS. CUANNEL STUDY JUL Y 5, 1977 Sample Number Mean Variance Coefficient of Variation 6 5 21.35 29.04 25.25 6001057 18. 58 6002057 16. 37 6003057 29. 43 6004057 24.21 6005057 18.15 6 5 31.83 43. 68 20.77 6C01057 34.51 6C02057 34.53 6C03057 40.06 6C04057 24.88 6C05057 25.18 7 5 16. 46 54.99 45.08 7001057 5.47 7002057 18.82 7003057 12. 72 7004057 21 40
~
7005057 23. 89 7 5 28. 85 32.33 19.72 7C01057 27.47 7C02057 32. 11 7C0305/ 20. 10 7C04057 29.41 7C05057 35.17 9 5 84. 23 465. 65 25. 60 9001057 52. 70 9002057 72. 30 9003057 95.58 9004057 93. 89 9005057 106. 68 9 67. 99 ,.275.10 24;40 9001057 79.06 9C02057 81. 87 9003057 78. 99 9004057 53. 05 9C05057 46. 99
I',OOI>I.AHK'I'OH ll I'OI IASS OVI'.RIIANK VS. CIIANHLII. S'fUI)Y JUI.Y 28, 3977 Sa>>lp.I e Nu>nber H Hen n Variance Coeffl.clei>t of: Varintinn 6 5 33.? 0 28.23 15. 99 6001287 32 02
~
G002287 36. 02 6003287 25.34 6004287 32.95 6005287 39.66 6 23.46 103. 30 43 12
~
GC01287 7.49 6C02287. 27. 84 6C03287 34. 90 GC04287 21. 53 6C05287 25 55
~
7 3G.50 172.40 35.97 7001287 21.56 7002287 46.54 7003287 49.46 7004287 41.55 7005287 23.38 7 30.96 133.75 37.37 7C01287 14. 16 7C02287 36.09 7C03287 29.62 7C04>287 45.83 jc05287 29.08 9 34.40 181.80 39.19 9001287 30.29 9002287 50.44 9003287 40. 60 9004287 14. 15 9005287 36. 53 9 34.86 62.50 22. 69 9C01287 47.37 9C02287 39.84 9C03287 31.46 9C04287 22.70 9C05287= 37. 92
e
APPENDIX J OVERBANK VS. CHANNEL STUDIES: CHLOROPHYLL a CONCENTRATIONS DATA
- Explanation of sample code used in Appendix J:
Example: sample 8 6C0156 6 C 0 1 5 6 a b c d e f a the first number refers to the sampling location; number 6 is at TRM 296.9,, number 7 is at TRM 298.4, and number 9 is at TRM 295.4.
b the second letter refers to the boat location (0 ~ overbank, C = channel) (See Pigure 2).
c the third number refers to the depth (in meters) sampled.
d the fourth number refers to the replicate.
e - the fifth (or fifth and sixth) number refers to the day of the month sampling took place.
f- the last number refers to the month of sample collection.
Sample 6C0156 was collected (a) at TRM 296.9 in (b) the channel from a (c) depth of 0 m, (d) first replicate, on the (e) 5th day of (f) June.
t\
~ >~
Chlorophyll A. Summary Overbank vs. Channel =
June 5,'977 Mean Values of Chlorophyll A are in Hilligrams/Cubic Heter Sample Mean Variance Coefficient of Variation 900056 2.2116 0.5284 32.86 901056 3.2592 1.1381 32;73
,903056 0.3492 0.1219 99.98 9C0056 3.4920 0.4878 20.00 9C1056 3.3756 0.0406 5.97 9C3056 4.5396 2.5608 35.25 9C5056 1.2804 0.5284 56.77 600056 0.3582 0.3849 173.20 601056 0.5820 0.2845 91.65 603056 0.0000 0.0000 0 000 F
6C0056 11.4804 0.7871 7.73 6C1056 7.9152 3.6989 24.30 6C3056 2. 5608 0.7723 34.32 6C5056 0.0000 0.0000 0 00 F
700056 0.3492 0.1219 99.98 701056 0.0000 0.0000 0.00 703056 0.0000 0.0000 0.00 7C0056 0.0000 0.0000 0.00 7C1056 0.0000 0.0000 0.00 7C3056 0.0000 0.0000 0.00 7C5056 0.0000 0.0000 0. 00
OVERBANK VS. CHANNEL CHLOROPHYI.I. DATA ALL VALUES ARE IN MII.LIGRANS/CUBIC METER SQBlpl 0 Chlorophyll A Chlorophyll B Chlorophyll C 9001056 1. 3968 0. 0000 0. 0000.
9002056 2.4444 0.0000 0.0000 9003056 2.7939 0.0000 0.0000 9011056 3.4920 0.0000 0.0000 9012056 2.0952 0.0000 0.0000 9013056 4.1904 0.0000 0.0000 9031056 0.6984 0.0000 0.0000 9032056 0.0000 0.0000 0.0000 9033056 0.3492 0.0000 0.0000 9C01056 2.7936 0.0000 0.0000 9C02056 3.4920 0.0000 0.0000 9C03056 4.1904 0.0000 0.0000 9C11056 3.4920 0.0000 0.0000 9C12056 3.1428 0.0000 0.0000 9C13056 3.4920 0.0000 0.0000 9C31056 5.9364 0 0000 F 0.0000 9C32056 4.8888 0.0000 0.0000 9C33056 2.7936 0.0000 0.0000 9C51056 2.0952 0.0000 0.0000 9C52056 0.6984 0.0000 0.0000 9C53056 1.0476 0 0000 F 0.0000 6001056 1. 0476 0.0000 0.0000 6002056 0.0000 0.0000 0.0000 6003056 0.0000 0.0000 0.0000 6011056 0. 0000 0.0000 0.0000 6012056 0. 6984 0.0000 0.0000 6013056 1. 0476 0.0000 0 0000 F
603105G 0 0000 F 0 0000 F 0.0000 6032056 0.0000 0.0000 0.0000 6033056 0.0000 -
0.0000 0.0000 6C01056 11 '080 0. 0000 0.0000 6C02056 12.1572 0.0000 0.0000 6C03056 10.4760 0.0000, 0.0000 6C11056 6.6348 0.0000 0.0000 6C12056 6.9840 0.0000 0.0000 6C13056 10.1268 0.0000 0.0000 6C31056 2.4444 0.0000 0.0000 6C32056 3.4920 0.0000 0.0000 6C33056 1.7460 0.0000 . 0.0000 60 >.1. 056 0.0000 0.0000 0.0000
()C52056 0.0000 0.0000 0.0000 6C53056 0.0000 0.0000 0.0000
Sample A Chlorophyll 8 Chlorophyll C J 3 7001056 0.0000 0.0000 0.0000 7002056 0.6984 0.'0000 0.0000 7003056 0.3492 0.0000 0.0000
. 7011056 0.0000 0. 0000 0.0000 7012056 0.0000 0.0000 0.0000 7013056 0.0000 0.0000 0.0000 7031056 0.0000 0.0000 0.0000 7032056 0.0000 0.0000 0.0000 0.0000 7C53056'hlorophyll 7033056 0.0000 0.0000 7C01056 0.0000 0;0000 0.0000 7C02056 0.0000 0.0000 0.0000 7C03056 0.0000 .0.0000 0.0000 7C11056 0.0000 0.0000 0.0000 7C12056 0.0000 0.0000 0.0000 7C13056 0.0000 0.0000 0.0000 7C31056 '0.0000 0.0000 0.0000 7C32056 0.0000 0.0000 0.0000 7C33056 0.0000 0.0000 0.0000, 7C51056 0.0000 0.0000 0.0000 7C52056 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000
Chlorophyll A. Summary Overbank vs. Channel July 5, 1977 Mean Values of Chlorophyll A are in Milligrams/Cubic Meter Sample Me,an Variance Coefficient of Variation 900057 0. 0000 0.0000 0.0000 901057 8.2644 10.5275 39.26 903057 3.9579 2.1128 36.73 9C0057 11.3439 0 '583 2.13 9C1057 14.3618 5.5696 16.43 9C3057 2.3280 0. 2845 22.91 9C5057 0.5820 0. 2845 91.65 600057 1.0476 0.3568 57.02 601057 8.7810 0.4269 7.44 603057 4.5396 ..1.0975 23.08 6C0057 3 ~ 1428 0:1219 11. 11 6C1057 4.8466 0.3270 11.80 6C3057 7.3230 0.5680 10.29 6C5057 1.6296 0.0406 12.36 700057 2.4444 0.0000 0.00 701057 1.6296 , 0.0406 12.36 703057 2.6772 0.2845 19.92 7C0057 3. 1428 0.1219 11.11 7C1057 4.0534 3.5634 46.57 7C3057 1.5312 0.0406 13.16 7C5057 0.0000 0.0000 0.0000
OVERBANK VS. CIIANNFL CHLOROPilYLL DATA ALL VALUES ARE IN MILLIGRAMS/CUBIC METER Sample Chlorophyll A Chlorophyll B Chlorophyll C 9001057 0.0000 ~ 0.0000 0.0000 9002057 0.0000 0.0000 0.0000 9003057 0.0000 0.0000 0.0000 9011057 4.5396 0.0000 0.0000 901205/ 9.7776 0.0000 0.0000 9013057 10.4760 0.0000 0.0000 9031057 2.7936 0.0000 0.0000 9032057 3.4920 0.0000 0.0000 9033057 5.5872 0.'0000 0.0000 9C01057 11.2086 0.0000 0.0000 9C02057 11.6226 0.0000 0.0000 9C03057 11.2116 0.0000 0.0000 9C11057 16.8978 0.0000 0.0000 9C12057 12.2004 0.0000 0.0000 9C13057 14.0052 0.0000 0.0000 9C31057 2.4444 0.0000 0.0000 9C32057 1.7460 0. 0000 0.0000 9C33057 2.7936, -
0.0000 0.0000 9C51057 1.0476 0.0000 0.0000 9C52057 0.6984 0.0000 0.0000 9C53057 0.0000 0.0000 0 0000 F
6001057 1.7460 0.0000 0.0000 6002057 O.G984 0.0000 0.0000 G003057 0.6984 0.0000 0.0000 6011057 8.3190 ~ 0.0000 0. 0000 6012057 9.2430 0.0000 0.0000 6013057 7.9080 0. 0000 0.0000 6031057 5.5872 0.0000 0.0000 6032057 3.4920 0.0000 0.0000 6033057 4.5396 0.0000 0.0000 6C01057 5. 1114 0.0000 0.0000 6002057 si. 1904 0.0000 0.0000 6C03057 5. 2380 0.0000 0.0000 6C11057 6. 8544 0.0000 0.0000 6C12057 6. 9222 0.0000 0.0000 6C13057 8. 1924 0.0000 0.0000 6C31057 1. 3968 0.0000 0.0000 GC32057 1.7460 0.0000 0.0000 6C33057 1.7460 0.0000 0.0000 6C51057 0.3492 0.0000 0.0000 6C52057 1.0476 0.0000 0.0000 6C53057 1.7460 0.0000 0.0000
Sample Chlorophyll A Chlorophyll B Chlorophyll C 7001057 2.4444 0.0000 0.0000 7002057 2.4444 0.0000 0.0000 7003057 2.4444 0.0000 0.0000
'7011057 1.3968 0.0000 0.0000 7012057 1.7460 0.0000 0.0000 7013057 1.7460 0.0000 0.0000 7031057 2.7936 0.0000 0.0000 7032057 2.0952 0.0000 0.0000 7033057 3.1428 0.0000 0.0000 7C01057 2.7936 0.0000 0.0000 7C0205/ 3.4920 0. 0000 0 0000 F
7C03057 3-1428 0.0000 0.0000 7C11057 2.7936 0.0000 0.0000 7C12057 3.1428 0.0000 0.0000 7C13057 6.2238 0.0000 0.0000 7C31057 1.3968 0.0000 '.0000 7C32057 1.7460 0.0000 0.0000 7C33057 1.3968 0.0000 0.0000 7C51057 0.0000 0.0000 0.0000 7C52057 0.0000 0.0000 0.0000
Chlorophyll 'A. Summary Overbank vs. Channel July 28; 1977 Mean Values of Chlorophyll A are in Milligrams/Cubic Meter Sample Mean Variance Coefficient of Variation 900287 5.8664 1.6119 21.58 901287 7.2334 1.4729 16.78 903287 7.7968 0.2416 6. 30 9C0281 0.8158 0.7751 107. 92 9C1287 1.0496 0.1230 33. 41 9C3287 1.1660 0.1640 34. 73 9C5287 1.6306 0. 0410 12. 42 600287 2.0776 0.3269 27.52 601287 ,2. 2156 0.2800 23.88 603287 2.4412 0.0459 8.78 6'C0287 0.5840 0.0414 34.84 6C1287 0.9332 0.0403 21-53 6C3287 1.1454 0.5994 67.59 6C5287 0.9322 0.0400 21.45 700287 0.9322 0.1619 43.16 701287 0.8158 0.0413 24. 91 703287 0.4666 0.1633 86. 61 7C0287 0.3512 0.1219 99.41 7C1287 0.1204 ,0.0414 168.99 jc3287 . 0.6582 0.1254 53. 80
'C5287 0.0000 0.0000 0.0000
OUERBANK US. CHANNEL CHLOROPHYLL DATA ALL VALUES ARE IN MILLIGRAMS/CUBIC METER Sample Chlorophyll A Chlorophyll B Chlorophyll C 9001287 4.4100 0.0000 0.0000 9002287 6.7398 0.0000 3.0378 9003287 6.4494 0.0000 0.3948 9011287. 7.0860 0.0000 1.2453 9012287 ~
- 8. 5140 1.9299 1.4475 9013287 6. 1002 0.0000 0.5607 90312b i 8.2944 0.7899 2.5020 9032287 7.3116 0.5154 3.444Q 9033287 7. 7844 0.0000 0.9135 9C01287 0.0000 0.0000 0.0000 9C02287 0.6984 0'. 0000 0.0000 9C03287 1.7490 0.0000 0.7971 9C11287 0.6984 0.0000 0.0000 9C12287 1.3998 0.0000 0.9630 9C13287 1.0506 0.0000 1.1289.
9C31287 1. 3998 0.0000 0.9630 9C32287 l. 3998 0.0000 0.9630 9C33287 0.6984 0.0000 0.0000 9C51287 1.3968 0.0000 0.0000 9C52287 1.7460 0.0000 0.0000 9C53287 1.7490 0.0000 0.7971 6001287 1.7490 0.0000 0.7971 6002287 6003287
- l. 7460 0.0000 ~
0.0000 2.7378 0.0000 3.1083 6011287 2.7936 0.0000 0.0000 6012287 1.7550 0.0000 4.0503 6013287 2.0982 0.0000 0.6312 6031287 2.3916 0.0000 4.9008 6032287 2.6760 0.0000 4.2906 6033287 2.2560 0.8403 0.7590 6C01287 0.3492 0.0000 0.0000 6C02287 0.6984 0.0000 0.0000 6C03287 0.7044 0.0000 2.9214 6C11287 0.7014 0.0000 1.2948 6C12287 1.0476 0.0000 0.0000 6C13287 1.0506 0.0000 1.1289 6C31287 0.6984 O.OOQO '0.0000 6C32287 2.0394 0.0000 3.4401 6C33287 0.6984 0.0000 0.0000 6C51287. 0.7014 0.0000 1.2948 6C52287 1.0476 0.0000 0.0000 6C53287 1.0476 0.0000 0.0000
Sample Chlorophyll A Chlorophyll B Chlorophyll C 7001287 0.7014 0. 0000 1.2948 7002287 1.3968 0.0000 0.0000 7003287 0.6984 0.0000 0.0000 7011287 1.0506 0.0000 1.1289 7012287 0.6984 0.0000 0.0000 7013287 0.6984 0.0000 0.0000 7031287 0.6984 0.0000 0;0000 7032287 0.0000 0.0000 0 0000 F
7033287 0.7014 0.0000 1. 2948 7C01.787 0.3492 0.0000 0.0000 7C02287 0.70>4 0.0000 1.2948 7C03287 .0030 0.0000 1.6266 7C01287 .0060 0.0000 3 '532 7C12287 0."0000 0.0000 0.0000 7C13287 0.3552 0.0000 3.0873 7C31287 1.0476 0.0000 0 0000 F
'7C32287 0.3552 0.0000 3.0873 7C33287 0.5718 0.9120 0.4062 7C51287 0.0000' 0.0000 0.0000 7C52287 F 0000 0.0000 0.0000 7C53287 0.0000 0.0000 0.0000
4 f
II
APPENDIX K OVERBANK VS. CHANNEL STUDIES: PHEOPHYTIN a CONCENTRATIONS DATA
- Explanation of sample code used in Appendix K:
Example: sample /I 6C0156 6 C 0 1 5 6 a b c d e f a the first number refers to the sampling location; number 6 is at TRM 296.9, number 7 is at TRM 298.4, and number 9 is at TRM 295.4.
b the second letter refers to the boat 'location (0 = overbank, C = channel) (See Figure 2) .
c the third number refers to the depth (in meters) sampled.
d the fourth number refers to the replicate.
e the fifth (or fifth and sixth). number refers to the day of the month sampling took place.
f the last number refers to the month of sample collection.
Sample 6C0156 was collected (a) at TRM 296.9 in (b) the channel from a (c) depth of 0 m, (d) first replicate, on the (e} 5th day of (f) June.)
re if'P
Pheophytin h Data Overbank vs. Channel All Values are in Milligrams/Cubic Meter Sample Pheophytin Index Pheophytin a 9001056 0.0000 0.0000 9002056 3.5000 -2.8836 9003056 0.0000 0.0000 9011056 0.0000 0.0000 9012056 0.0000 0.0000 9013056 3.0000 -4.1652 9031056 0.5000 3.8448 9032056 0.0000 0.0000 9033056 0.0000 0.0000 9C01056 0.0000 0.0000 9C02056 3.3333 -3.9249 9C03056 6.0000 -6.8886 9C11056 3.3333 -3.9249 9C12056 9.0000 -5.8473 9C13056 10.0000 -6.6483 9C31056 8.5000 -10.8936 9C32056 14.0000 -9.8523 9C33056 0.0000 0.0000, 9C51056 0.0000 0.0000 9C52056 0.0000 0.0000 9C53056 0.0000 0.0000 6001056 0.0030 -2.4030 6002056 0.0000 0.0000 6003056 0.0000 0.0000 6011056 0.0000 0.0000 6012056 0.0020 0.0000 6013056 0.0000 0.0000 6031056 0.0000 0.0000 6032056 0.0000 0.0000 C) 0'33(35) 6) 0.0000 0.0000 6(,'01056 3.7778 -14.9787 6C02056 5.8333 -19.0638 6C03056 3.7500 -13.1364 6C11056 4. 7500 -9.7722 6C12056 5.0000 -10.5732 6C13056 2.9000 -8.8110 6C31056 0.0070 -5.6070 6C32056 5 F 0000 -5.2866 6C33056 0.0050, -4.0050 6C51056 0.0000 0.0000 6C52056 0.0000 0.0000 6C53056 0.0000 0.0000 7001056 0.0000 0.0000 7002056 0.0020 -1.6020 7003056 0.0010 -0.8010 7011056 0.0000 0.0000 7012056 0. 0000 0.0000 7013056 '.0000 0.0000 7031056 0.0000 0.0000
Cg K-2 Sample Pheophytin Index Pheophytin a 7032056 0.0000 0.0000 7033056 0.0000 0.0000 7C01056 0.0000 0.0000 7C02056 0.0000 0.0000 7C03056 0.0000 0. 0000 7C11056 :,0.0000 0.0000 7C12056 0.0000 0.0000 7C13056 0.0000 0.0000 7C31056 0.0000 0.0000 7C32056 ,0.0000 0.0000 7C33056 (0.0000 0.0000 7C51056 0.0000 0.0000 7C52056 ,0.0000 0.0000 7C53056 (0,0000 0.0000
Pheophytin A Data K-3 Overbank vs. Channel All Values are in Milliprams/Cubic Meter Sample Pheophyt in index Pheophytin a 9001057 0. 0000 0.0000 9002057 0.0000 0.0000 9003057 0.0000 0.0000 9011057 0.000* -10 '130 9012057 5.6000 -15.6195 9013057 4.2857 -14.4981 9031057 0.000<< -6.4080 9032057 0.000* -8.0100 9033057 4.0000 -7.3692 9C01057 2.0625 -4.6458 9C02057 2.0000 -4.0851 9C03057 1. 941'2 -3.2841 9C11057 2.0000 -6.0075 9C12057 2.1176 -5.6781 9C13057 2.4118 -9.6921 9C31057 0.000* -5.6070 9C32057 0.000<< -4.0000 9C33057 0.000* -6.4080 9C51057 0.000<< -2.4030 9C52057 0.000* -2.4030 9C53057, 0.0000 0.0000 6001057 0.000* -4.0050 6002057 0.000<< -1.6020 6003057 0.000* -1.6020 6011057 2.1818 -4.2453 6012057 1.9286 -2.5632 6013057 1.9167 -2.0826 6031057 1.6000 0.8010 6032057 2.5000 -2 '632 6033057 2.1667 -2.2428 6C01057 2.1429 -2.4831 6C02057 1.7143 -0.0801 6C03057 '2.1429 -2.4831 6C11057 2.0000 -2.4030 6C12057 2.0000 -2.4030 6C13057 2.1818 -4.2453 6C31057 4.0000 -1.8423 6C32057 5.0000 -2.6433 6C33057 F 0000 -2.6433 6C51057 0.000<< ~
-0.8010 6C52057 3. 0000 -1.0413 6C53057 5. 0000 -2.6433 7001057 0.000* -5.6070 7002057 7.0000 -4.2453 7003057 7.0000 -4.2453 7011057 4.0000 -1.8423 7012057 2.5000 -1.2816 7013057 2.5000 -1.2816 7031057 , 8.0000 -3.4443 7032057 6.0000 -5.0463
Snmpl<< Pheophytin index pheophytin n 7033057 4.5000 -4.4856 7C01057 8. 0000 -5.0463 7C02057 3.3333 -3.9249
.7C03057 3. 0000 -3.1239 7C11057 2.6667 -2.3229 7C12057 4.5000 -4.4856 7C13057 3.6000 -7.6095 7C31057. 0.000* -3.2040 7C32057 0;000* -4.0050 7C3305/ 0.000* -3.2040 7C51057 0; 0000
- 0.0000 7C52057 0.0000 0.0000 7C53057 0.0000 0.00 JO
* ~ Infinity
Pheophytin A l)ata K-5 Overbank vs. Channel All Values're in Milligrams/Cubic Heter Sample Pheophytin Index Pheophytin a 9001287 2.6000 -3. 6045
'002287 1.6667 0.3204 9003287 2.7143 -5.6871 9011287 1.7500 -0.4806 9012287 2.1667 -4.4856 9013287 3.6000 -7.6095 9031287 2.7778 -7.7697 9032287 2.4444 -6.9687 9033287 2.0909 -3.4443 9C01287 0.0000 0.0000 9C02287 0.0020 -1.6020 9C03287 0.0050 -4.0050 9C11287 2.0000 -0.2403 9C12287 2.0000 -0.4806 9C13287 0.0030 -2 '030 9C31287 0.0040 -3.2040 9C32287 4.0000 -1 8423
~
9C33287 0. 0020 -1.6020 9C51287 0.0040 -3.2040 9C52287 1.6667 -0.0801 9C53287 5.0000 -2.6433 6001287 5.0000 -3.6846 6002287 1.6667 -2.6433
,6003287 2.0000 -0.9612 6011287 4.0000 -3.6846 6012287 5.0000 -2.6433 6013287 2.0000 -0.7209 6031287 1.7500 -0.1602 6032287 2.6667 -2.3229 6033287 7.0000 -4.2453 6C01287 1.0000 0.5607 6C02287 0.0020 -1.6020 6C03287 2~ 0000 -0.2403 6C11287 0.0020 -1.6020 6C12287 0.0030 -2.4030 6C13287 1.5000 0.3204 6C31287 0.0020 -2.4030 GC32287 6.0000 -3.4440 6C33287 0.0020 -1.6020 6C51287 0.0020 -1.6020 6C52287 0.0030 -2.4030 6C53287 0.0030 -2.4030 7001287 0.0020 -0.8010 7002287 0.0040 -1.6020 7003287 0.0020 0.0000 7011287 3.0000 0.0000 7012287 0.0020 0.0000 7013287 2.0000 -0.8010 7031287 0.0020 -2.4030
K-6 Sample Pheophytin Index Pheophytin a 7032287 0. 0000 -0.8010 7033287 0. 0020 -1.6020 7C01287 0. 0010 -1.6020 7C02287, 0.0020 -3.2040 7C03287 0.0000 -1.6020 7C11287 0 0000 F -1.0413 7C12287 ~ '.0000 -1.6020 7C13287 0.0010 -0.2403
/C31287 0.0030 .1".6020 7C32287 0.0010 1.3617 7C33287 0.0020 1.3617 7C51287 0.0000 0.0000, 7C52287 '.0000 0.0000 7C53287 0.0000 0.0000}}
