ML20082R850: Difference between revisions
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| number = ML20082R850 | | number = ML20082R850 | ||
| issue date = 12/31/1994 | | issue date = 12/31/1994 | ||
| title = 1994 Radiological Environ Monitoring Rept | | title = 1994 Radiological Environ Monitoring Rept | ||
| author name = Phares R | | author name = Phares R | ||
| author affiliation = ILLINOIS POWER CO. | | author affiliation = ILLINOIS POWER CO. | ||
Revision as of 01:45, 14 May 2020
| ML20082R850 | |
| Person / Time | |
|---|---|
| Site: | Clinton  |
| Issue date: | 12/31/1994 |
| From: | Phares R ILLINOIS POWER CO. |
| To: | NRC OFFICE OF INFORMATION RESOURCES MANAGEMENT (IRM) |
| References | |
| U-602443, NUDOCS 9505020239 | |
| Download: ML20082R850 (191) | |
Text
lihnois Power Company Clinton Power Staten P.O. Box 678 Clinton,IL 61727 Tel 217 935-8881 ILLIN91S u 602u3 P6MR L30-95(04 -26 )LP 1 A.120 April 26, 1995
. Docket No. 50-461 10CFR50, App I Document Control Desk Nuclear Regulatory Commission Washington, D.C. 20555
Subject:
Clinton Power Station Annual Radiological Environmental Operating Report
Dear Sir:
Illinois Power Company is submitting the 1994 Annual Radiological Environmental Operating Report for Clinton Power Station. This submittal is provided in accordance with the requirements of Section 5.6.2 of Clinton Power Station Technical Specifications.
Sincerely yours, Richard F. Phares M[
Director, Licensing SFB/csm Attachment cc: NRC Clinton Licensing Project Manager NRC Resident Office, V-690 Regional Administrator, Region III, USNRC Illinois Department of Nuclear Safety 9505020239 941231 PDR ADOCK 05000461 R PDR P,
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pe%R Clinton Power Station
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1994 RADIOLOGICAL ENVIRONMENTAL MONITORING REPORT FOR THE CLINTON POWER STATION Prepared by Radiological Environmental Group Radiation Protection Department l
May 1, 1994
TABLE OF CONTENTS ITEM PAGE LIST OF T N RR 111 LIST OF FIGURES iv I. REBCUTIVE StBOULRY l II. INTRODUCTION 3 A. Characteristics of Radiation 3 B. Sources of Radiation Exposure 5 C. Description of the Clinton Power Station 12 D. Nuclear Reactor Operations 13 E. Containment of Radioactivity 17 F. Sources of Radioactive Effluents 18 G. Radioactive Waste Processing 19 III. RADIOIAGICAL ENVIROISBNTAL MONITORING PROGRAM (REMP) 21 A. Program Description 21 B. Direct Radiation Monitoring 43 C. Atmospheric Monitoring 47 D. Aquatic Monitoring 53 Fish 53 Shoreline sediments 54 Bottom Sediments 55 Aquatic vegetation (Periphyton) 55 E. Terrestrial Monitoring 57 Milk 57 Grass 58
- Vegetables 58 Meat 61 Soil 61 F. Water Monitoring 62 Drinking Water 62 Surface Water 65 Well Water 69 G. Quality Assurance Program 73 B. Changes to the REMP During 1994 73 IV. ANNUAL LAND USE CENSUS 75 A. Annual Land Use Census 75 Summary of Changes Identified in 1994 l
Annual Land Use Census 77 V. METEOROLOGICAL CHARACTERISTICS 79 A. Description 79 i
TABLE OF CONTENTS (Cont'd)
ITEM PAGE VI. LIST OF REFERENCES 89 VII. APPENDICES A. Exceptions to the REMP During 1994 93 B. REMP Sample Collection and Analysis Methods 101 C. Glossary 119 D. CPS Radiological Environmental Monitoring Quality control Check Results 1994 123 E. CPS Radiological Environmental Monitoring Results during 1994 129 O
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LIST OF TABLES TABLE SUBJECT PAGE 1 Common Sources of Radiation 9 2 1994 Radionuclide Composition of CPS Effluents 19 3 Clinton Power Station Sample Codes 35 4 REMP Sample Locations 37 5 Average Quarterly TLD Results 47 6 Average Gross Beta Concentrations in Air Particulates 49 7 Average Monthly Gross Beta Concentrations in Air Particulates 50 8 Average Gross Beta Concentrations in Drinking, Surface and Well Water 70 9 1994 Annual Land Use Census 75
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10 Classification of Atmospheric Stability 81 11 Joint Wind Frequency Distribution By Stability class 82 R
LIST OF FIGURES FIGURE SUBJECT PAGE 1 Dose contributions to the U. S. Population from Principal Sources of Radiation Exposure 9 2 Clinton Power Station Basic Plant Schematic 15 3 Potential Exposure Pathways of Man Due to Releases of Radioactive Material to the Environment 23 f 4 REMP Sample Locations within 1 Mile 27 5 REMP Sample Locations from 1 - 2. Miles 29 6 REMP Sample Locations from 2 - 5 Miles 31 7 REMP Sample Locations Greater than 5 Miles 33 8 Direct Radiation Comparison 45 g 9 Air Particulate Gross Beta Activ'ty i Comparison 51 10 strontium-90 Activity in Milk 59 11 Drinking Water Gross Beta Activity Comparison 63 12 Surface Water Gross Beta Activity Comparison 67 13 Well Water Gross Beta Activity Comparison 71 l
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II. INTRODUCTION The Radiological Environmental Monitoring Program (REMP) at Clinton Power Station (CPS) is designed to monitor the environment surrounding the plant for any radioactive material that may be released by CPS as a result ofplant operations. The primary concern is what impact, if any, the radioactive materials released from CPS have on the generalpublic. This report isprepared in a way that is useful to a specialized scientific community. However, this introduction, the explanations in later sections, and minimal use of technical terms are all designed to make this report understandable and useful to those with no background in environmental monitoring. A. CHARACTERISTICS OF RADIATION Atoms whose nuclei contain an excess of energy are called radioactive atoms. They release this excess energy by expelling electromagnetic or particulate radiation from their atomic centers to become stable (non-radioactive). This process is called " radioactive decay". X-rays and gamma rays are examples of electromagnetic radiation and are similar in many ways to visible light, microwaves and radio-waves. Particulate radiation may be either electrically charged such as alpha and beta particles, or has no charge, like neutrons. The term " half-life" refers to the time required for half of a given amount of a radionuclide to decay. Some radionuclides have a half-life as short as a fraction of a second, while others have a half-life as long as a million years. Radionuclides may decay directly into stable elements or may undergo a series of decays which ultimately end up reaching a stable element. Radionuclides are found in nature (e.g., radioactive uranium, thorium, carbon and potassium), and may also be produced artificially in accelerators and nuclear reactors (e.g., radioactive iodine, cesium and cobalt). 3
NATURALLY OCCURRING MAN-MADE RADIONUCLIDES RADIONUCLIDES Uranium Iodine Thorium Cesium. Carbon Cobalt Potassium Strontium Lead Barium The activity of a radioactive source is the average number of nuclear disintegrations (decay) of the source per unit of time. The unit of activity is called the curie. A one curie radioactive source undergoes 2.2 trillion disintegrations per minute, but in the realm of nuclear power plant effluents and environmental radioactivity, this is a large unit. Therefore, two fractional units, the microcurio and the picocurie, are more commonly used. I curie (Ci) ' = 2,220,000,000,000 disintegrations / minute 1 millieurie (mci) = 2,220,000,000 disintegrations /minuto 1 microcurie (pCD = 2,220,000 disintegrations / minute 1 nanocurie (nCi) = 2,220 disintegrations /minuto 1 picoeurie (pCi) = 2.22 disintegrations / minute The microcurie (uci) is one millionth of a curie (Ci) and represents 2.2 million decays per minute. The picocurie (pci) is one millionth of a microcurie and represents 2.2 decays per minute. Another way of comparing the pCi and the Ci is by analogy with distances. A picocurie would be the width of a pencil mark while a curie would be 100 trips around the earth. Radioactivity is related to the half-life and the atomic mass of a radionuclide. For example, Uranium-235 (U-235) with a half-life of 704 million years requires about 462,400 grams to obtain an activity of one curie. But iodine-131 (I-131) with a half-life of 8.04 days only requires about 0.000008 grams to produca an activity of one curie. Any mechanism that can supply the energy necessary to ionize an atom, break a chemical bond, or alter the chemistry of a living cell are capable of producing biological damage. Electromagnetic and particulate radiation can produce cellular damage in any of these ways. In assessing the biological effects of radiation, 4
the type, energy, and amount of radiation must be considered. External total bcdy radiation involves exposure of all organs. Most background exposures are of this form. When radioactive elements enter the body through inhalation or ingestion, their distributio.n may not be uniform. TARGET TISSUE NUCLIDE Bone Strontium-90 Kidney Uranium-235 Thyroid Iodine-131 Muscle and Liver Tissue Cesium-137 Gastrointestinal Tract Cobalt-60 For example, radiciodine selectively concentrates in the thyroid gland, whereas radiocesium collects in muscle and liver tissue, and radiostrontium collects in mineralized bone. The total dose to organs by a given radionuclide is also influenced by the quantity and the duration of time that the radionuclide remains in the body. Owing to radioactive decay and human metabolism factors, some radionuclides stay in the body for very short times while others remain for years. The amount of radiation dose that an individual remives is expressed in rem. Since human exposure ',o radiation usually involves very small exposures, the millirem (mrem) is the unit most commonly used. One millirem is one thousandth of a rem. I millirem = 0.001 Rem B. SOURCES OFRADIATION EXPOSURE Many sources of radiation exposure exist. The most common and least controllable source is natural background radiation from cosmic rays and the earth which mankind has always lived with and always will. Every second of our lives, over seven thousand atoms undergo radioactive decay in the body of the average adult. 5
~ Radioactive elementsL.have always_ been;'a part ;of our
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planet and everything that has come 'from the earth, , including our own bodies- -is, therefore, naturally radioactive.- i Natural Radionuclides In The Earth's Crust - :l t Potassium-40-(K-40).- . Radium-226-(Ra-226) Uranium-238 '(U-238) Radon-222 (Rn-222) : Thorium-232 (Th-232); LLead-204' (Pb-204) Examples ' .'of < radioactive materials found in: the Earth's .: cruct';today . consists of radionuclides such as - potassium- i' 40, uranium-238, thorium-232, radium-226 and radon-222. These radionuclides aree introduced into the water, soil and air by such natural" processes as -volcanic . activity, weathering, erosion and radioactive _ decay- _; i Some -- of the 1 naturally occurring radionuclides, such as : ; radon, are a significant ' source of : radiation exposure to ; the general public. Radioactive radon is a - chemically- : inert gas' produced naturally in the ground :as a part .of the. uranium'and' thorium decay series. Radon: continues to j undergo. radioactive decay, producing new- . naturally radioactive 1 materials called . radon "
. daughters".. These ;
new materials, which are solid particles, noti gases, .can ' stick to surfaces such as dust particles inithe air. ; Concentrations of radon in air are variable' and- are ! affected by concentrations of uranium and thorium in ! soil, as well as, altitude, soil porosity, temperature, i l pressure, soil' moisture, rainfall,. snow cover, ; atmospheric conditions, and. season. Radon 'can move through cracks and openings into basements of buildings i and become trapped in a small air volume indoors. Thus, l indoor radon concentrations are usually higher than those found outdoors. Building materials such as cinder blocks and concrete are radon sources. _ Radon can also be dissolved in well water and contribilte to airborne radon
- in houses when released.through showers or; washing.
Dust containing . radon daughter particles can be inhaled and deposited on the surface of an individual's lung. Radon daughters emit high . energy alpha radiation . dose to . the lung lining. Table 1 -' shows the average annual
- effective dose due to radon.
About three hundred . . cosmic rays originating from outer space pass through each person every second.- l l l l 6 i 9
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i l t i Cosmic-Ray-Activated Radionuclides Beryllium (Be-7) Tritium (H-3) l Beryllium-10 (Be-10) Sodium (Na-22) Carbon-14 (C-14) Phosphorus-32 (P-32) , 1 i The interaction of cosmic rays with atoms in the earth's j atmosphere produces radionuclides such as Beryllium-7,
- Beryllium-10, Carbon-14, tritium, and Sodium-22.
j Portions of these radionuclides become deposited on land - 4 or in water while the remainder stay suspended in the-atmosphere. l j consequently, there are natural radioactive materials in i the soil, water, air and building materials that contribute to radiation doses to the human body. Natural 4 drinking water contains trace amounts of uranium and i radium; milk contains measurable amounts of potassium-40. l Sources of natural radiation and their average -
- contributing radiation doses are summarized in Table 1.
] Figure 1 graphically shows the percentage ' contribution , from principal sources of radiation exposure to the ; i:
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general population of the United States. ~ Radiation 8 exposure levels from natural radiation fluctuate with ' l time and also can vary widely from location to location. I The average individual in the United States receives
- j approximately three hundred arem per year from natural -
{ sources. i ] In some areas of the country, the dose from natural
- radiation is significantly higher. Residents of -
l Colorado, five thousand feet above sea level, receive- ! additional dose due to the increase in cosmic and terrestrial radiation levels. In fact, for every one l! thousand feet in elevation above sea 1s.el, an individual i j will receive an additional one arem per year from cosmic 4 radiation. In several areas of the world, high j concentrations of mineral deposits result in _ natural
- background radiation levels of several thousand arem per j . year.
I In addition to natural background radiation, the average i individual is exposed to radiation from a number of man- ! made sources. The largest of these sources come from { - medical diagnosis: . X-rays, CAT-scans, fluoroscopic ,
- examinations and radio-pharmaceuticals. Approximately j 160 million people. in the United States are exposed to medical- or dental X-rays in any given year. The annual i dose to an individual from such irradiation averages 53 arem.
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i. 3 i ! TABLE 1 i j COMMON SOURCES OF RADIATION ; A. Average Annual Effective Dose Equivalent to the U.S. Population ! 1. NaturalSources rnrem 4 j a. Radon 200
- b. Cosmic, Terrestrial,Intemal 100 4 2. Man-Made Sources mrem
; a. Medical
- X-ray Diagnosis 39
- Nuclear Medicine 14
, b. ConsumerProducts 10
- c. Occupational 1
- d. Miscellaneous Environmental <1 i
- e. Nuclear Fuel Cycle <1 l
Approximate Total 360 l NCRP87a l
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t i 1 l 4 1 i i 1 PERCENTAGE OF CONTRIBUTION l i i . i CanSisner Products (3%) l s uclear Medcine(4%) ! m (s6%) j NATURAL . , MAN MADEs.# i qx xo.r;,.=.g.] ",. X-ray Diagnosis (11%)
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- Nuclear Fuel Cycle
+ owewa j Cosmc.Terrestnal l
- internal (27%)
. I FIGURE 1: DOSE CONTRIBUTIONS TO THE U.S. POPULA TION FROM l PRINCIPAL SOURCES OF RADIA TION EXPOSURE i I i 2 I i i 4 i'
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Smaller doses from man-made sources come from consumer products (e.g., television, smoke detectors, l fertilizers), fallout from prior nuclear weapons tests, j and production of nuclear power and its associated fuel cycle.
" Fallout" commonly refers to the radioactive debris that settles to the surface of the earth following the detonation of nuclear weapons. Fallout is dispersed throughout the environment but can be-washed down to the Earth's surface by rain or snow.
Radionuclides Found in Fallout ' Iodine-131 (I-131) Strontium-90 (Sr-90) Strontium-89 (Sr-89) Cesium-137 (Cs-137 There are approximately two hundred radionuclides produced in the nuclear weapon detonation process; a number of these are detected in fallout. The radionuclides found in fallout that produce most .of the
, fallout radiation exposures to man are iodine-131, l strontium-89, strontium-90, and. cesium-137.
i l l l 11
s j } C. DESCRIPTION OF THE CLINTON POWER STATION j The Clinton Power Station is located in Harp Township, 1 DeWitt County, Illinois. It is approximately six miles east of Clinton, Illinois. The station, its V-shaped cooling lake, and the i surrounding Illinois Power Company-owned land encloses ! a 14,182 acres. This includes the 4,895-acre, man-made l 1 cooling lake and about 90 acres of. privately owned , i property. ' The plant is sited on approximately - 150 acres j , on the northern arm of the lake. The cooling water
- discharge flume, which discharges to the eastern arm of
- the lake, occupies an additional 130 acres. Although the
,' nuclear reactor, supporting equipment, and associated 3 electrical. generation and distribution equipment lie in i Harp Township, portions of the 14,182 acres lie in ] Wilson, Rutledge, DeWitt, Creek, Nixon and Santa - Anna ' ] Townships. 2
- The cooling lake was formed by constructing an earthen i dam near.the confluence of Salt Creek and the North Fork !
of. Salt' Creek. The resulting . lake has an average depth l 8 of 15.6 feet, and includes an ultimate heat sink of about l } 590 acre feet. The ultimate heat- sink provides I j sufficient water volume and cooling capacity for
- approximately thirty days of orlera. tion without -makeup
! water. l Through arrangements with the Illinois Department of Conservation, Clinton Lake and much of the area immediately adjacent to the lake are used for public j recreation activities, including swimming, boating, j water-skiing, hunting and fishing. Recreational i facilities exist at Clinton Lake and accommodate up to j 11,460 people per day during peak ' usage periods. The i outflow from Clinton Lake falls into Salt Creek and flows i . in a westerly direction for about 56 miles before joining ! the Sangamon River. The Sangamon River drains into the ! Illinois River . which enters the- Mississippi River near i Grafton, Illinois. The nearest use of . downstream water ! for drinking purposes is 242 river miles downstream of i ! Clinton Lake at Alton, Illinois, as verified from the t j~ Illinois Environmental Protection Agency Public Water 1 Service. Although sces farms in the Salt Creek drainage j area downstream of Clinton Lake use irrigation, the
- irrigation water.is drawn from wells, not from the waters j of Salt Creek.
l Approximately 810,000 individuals live within 50 miles of i the Clinton Power. Station. 'Over half are located in the
- major metropolitan centers of 'Bloomington-Normal (located about 23 miles north northwest),
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Champaign-Urbana 4 (located about 31. miles east), Decatur (located about 22 i ( 12 e F
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' miles south southwest) and Springfield (located about 48 H l miles west southwest). The nearest city _is Clinton, the
- county seat of DeWitt County. The estimated. population of i
Clinton is about 8,000 people. Outside of. the urban areas, most. of the land within 50 - miles of the Clinton l Power Station is used for farming. The principal' crops grown are corn and soybeans. , i . i D. NUCLEAR REACTOR OPERATIONS ! The fuel of 'a nuclear reactor is made of thel element ! uranium in the form of uranium. oxide. The - fuel produces i power by the process called " fission". In fiss;.on, . the ,
- uranium atom absorbs a neutron and splits _ to produce fission products, heat, radiation and free neutrons. The -,
free neutrons travel in the reactor . core and further ; i absorption of neutrons by uranium permits the fission i
- process to continue. As the fission . process . continues, more fission products, radiation, heat and neutrons are produced and a sustained reaction occurs. _ The heat ;
produced is extracted from the fuel to produce steam that ; drives a turbine _ generator to produce electricity. ; l l , The fission products are predominantly radioactive. They ! l are unstable elements that emit radiation as they change ! i from unstable to stable elements. Neutrons that are not i absorbed by the uranium fuel may be absorbed by stable atoms in the materials that make up the components and i, structures of the reactor. In such cases, stable atoms ! often become radioactive. This process 'is called l " activation" and the radioactive atoms . which result are '
- called " activation products".
! l Fission Products Activation Products i Cesium-134 (Cs-134) Cobalt-60 (Co-60) < i ' Cesium-137 (Cs-137) Manganese-54 (Mn-54) i Ruthenium-106 (Ru-106) Iron-55 ( Fe- 55 ) + Barium-140 (Baalto) Iron-59 (Fe-59) h Cerium-144- (Ce-144) Zinc-65 (Zn-65) l l Strontium-89 (Sr-90) Tritium (H-3) i l The reactor at the Clinton Power Station is a boiling
- water reactor (BWR). Figure 2 provides :a basic plant schematic for the Clinton Power Station and shows the I separation of the cooling water from plant systems. In j', this type of reactor the fuel -is formed into small ceramic pellets that are loaded into sealed ' fuel rods.
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i l i CONTAINMENT , BUILDING i ; 2+ Steam *
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' Control i Cooling Reds-System Condenser -
s l FIGURE 2: CLINTON POWER PLANT BASIC PLANT SCHEMATIC
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i I i The ' fuel rods are arranged in arrays called bundles that are supported within a massive steel reactor vessel. The spaces between the fuel rods are filled with water. The heat released during the fission of fuel atoms is transferred to the water surrounding the fuel rods. A type of pump that contains no moving parts.(a jet pump), and recirculation pumps are used to force the water to circulate through the fuel bundles to assure even cooling of the fuel rods. As the water absorbs heat from the fuel rods some of it is changed to steam. The steam is l used to drive a turbine which is coupled to a generator, thereby completing the conversion of -- the energy released ! during fission to electricity. l After the steam passes- through' the turbine it is ! condensed back to water and returned to the reactor ! vessel to repeat the process. As the water circulates through the' reactor pressure. vessel, corrosion allows s trace . quantities of the component and structure surfaces ' to get into the water. The corroded material also contains radioactive substances known as activated corrosion products. Radioactive fission and activation products are normally confined to the primary. system although small leaks from the primary system may occur. 1 E. CONTAINMENT OFRADIOACTIVITY During operating conditions, essentially all radioactivity is contained within the first of several - barriers that collectively prevent escape of i i radioactivity to the environment. l The fuel cladding (metal tubes) provides the first ! barrier. The ceramic fuel pellets are sealed within , zircaloy metal tubes. There is a small gap between the l fuel and the cladding where the noble gases and . volatile nuclides collect. The reactor pressure vessel and the steel piping of the primary coolant system provide the second barrier. The reactor - pressure vessel is a seventy-foot = high vessel with steel walls ranging from four to seven inches thick which encase the reactor . core. The reactor pressure vessel and the steel piping provide containment ~ for all radionuclides in the primary coolant. The containment Building.provides the third barrier. Tne Containment Building has steel-lined, four-foot-thick reinforced concrete walls which completely enclose the reactor pressure vessel and vital auxiliary equipment. l This structure provides a third line of defense against 17 j i
- _ - _ _ _ _ _ _ _ _ _ _ _ . _ - - - . - . l
i 1 tihe uncontrolled release of radioactive materials to the ~ ! environment. The massive concrete walls also serve to
- absorb auch of .the; radiation emitted during reactor ;
j operation or from radioactive materials created during !
- reactor operations.
) 1 F. SOURCES OF RADIOACTIVE EFFLUENTS , l In an operating nuclear power plant, most of . the . fission ;
- products are retained within the fuel and fuel cladding. ,
i However,- the fuel . manufacturing process leaves traces of t l uranium on the exterior of the fuel tubes. Fission : 4 products from the eventual fission.of these traces may be ; Other small' amounts of 1 released to the primary coolant. ; 4 radioactive fission products are able to diffuse .or migrate through the fuel cladding and into the primary- [ coolant. ~ Trace quantities of the corrosion products from j component. and structural surfaces. that have been j activated, also get into the primary coolant. I i l Many soluble. fission and. activation products' such ~ as
. radioactive iodines, strontiums, cobalts and cesiums are l removed by domineralizers in the' water. purification
! systems. The noble gas fission ~ products, activated , j . atmospheric gases introduced. with reactor feedwater, and i some of the volatila fiesion products such as iodine and j bromine, are carried from the reactor pressure vessel to :
- the condenser with the steam. i i
l The steam jet air ejectors or the condenser. vacuum pump i remove the gases from the condenser and transfer them to the off-gas treatment system. In the. off-gas treatment system, the gases are held up by adsorption on specially.
- treated charcoal' beds to allow the radioactive gases to l decay before they are released through~ the main l ventilation exhaust stack.
! small releases of radioactive liquids from valves, j piping, or equipment associated with the primary coolant i system may occur in the containment, Auxiliary, Turbine, i RadWaste and Fuel Buildings. The. noble gases become part i of the gaseous wastes while the remaining radioactive 1 liquids are collected in sumps and processed for reuse. j Processed primary coolant water that does- not .seet
- chemical specifications for reuse may also become waste ;
[ water. These represent the principal sources of liquid ; i effluents. l ! Table 2 snamarizes the composition of radioactive effluents (gaseous and liquid)^ released from the Clinton Power Station during 1994. The highest calculated total i body dose received by a member of the public due to the l. release of these radioactive materials was 0.00256 mrem. < 18
. l i i i This is compared to the 93 mrem per year received in
- Central Illinois due to natural background radiation.
TABLE 2 3 i i 1994 RADIONUCLIDE COMPOSITION OF CPS EFFLUENTS ! i - 1 i l } Gaseous. Liquid ! ! Effluents Effluents
- Radionuclide HaN INe (Cl) (Cij, Gross Alpha NA 0.0000247
! Tritium (H-3) 12.3 years 31.3
- tron-59 2.'7 years 0.0000331
- Chromium-51 27.7 days 0.0441 2
l Manganese-54 312.7 ' days 0.000503 Cobalt-58 70.8 days 0.000656 CobeE-60 5.3 years 0.000624 0.00000942 4 Zine-65 244.4 days 0.0000139 i Molybdenum-99 66.0 hours 0.0000285 f Technetium-99m 6.0 hours 0.0987 I i Sodium-24 15.0 hours 0.00371 .f Strontium-89 50.6 days 0.0000349 4 Arsenio-76 26.3 hours 0.00183 Xenon-135 9.11 hours 1.17 4 lodine-131 8.0 days 0.0000596 ) lodine-133 20.8 hours 0.000304 1 i Total 32.6 0.00000942 i I 3 i G. RADIOACTIVE WASTE PROCESSING
. i In a normal operating nuclear power plant, radioactive !
liquid and gaseous wastes are collected, stored- and l
- processed through treatment systems to remove or reduce most of the- radioactivity (excluding tritium) prior to l reuse within the plant or discharge to the environment.
These processing systems are required by the Clinton l Power Station Offsite Dose Calculation Manual to be installed and operable to help ensure all releases of radioactive liquid and gaseous effluents are As Low As . Beasonably Achievable (ALARA). j 4 The liquid waste treatment systems consist of filters,
- demineralizers and evaporators. Liquid wastes are routed l 4
19
i 1 l through the waste. evaporators to .be degassed and
- distilled thereby reducing their volume and concentrating l; their radioactivity. The distillates are further treated through domineralizers and filters and transferred to the
- waste evaporator condensate storage tanks. Liquid wastes
- are processed' through the appropriate portions of the-L liquid waste treatment system to . provide assurance . that -
t the releases of radioactive materials in liquid offluents will be kept ALARA. I j . Liquid wastes are discharged into the plant cooling water ! i stream which varies from approximately ;5,000. gallons per j minute, when the plant is in shutdown, to 567,000 gallons
- per minute, when the plant is at full. power. The liquid
- effluents are thoroughly . mixed with and diluted by the
- plant cooling water as it travels the 3.4 miles of the . ,
l: discharge canal' before it enters Clinton Lake east of l i DeWitt County Road 14. ! The Clinton~ Power Station Offsite' Dose Calculation Manual !. requires that -liquid offluents not _contain a higher
- concentration of any. radioisotope than that which is set
- for continuous ' exposure to the general public.. This
- condition is satisfied at the point the liquid offluent i
is first introduced into the cooling water flow. The
- additional dilution that occurs in - the cooling water
- canal reduces 'the concentrations of' radioisotopes to
! between 1/73 (for minimum flow) and 1/1890 (for maximum { flow) of their original value before the water enters l Clinton Lake. l The concentrated radioactive solids captured in the { liquid waste treatment system r.re ' solidified and shipped
- off-site for- disposal at licensed low-level waste disposal facilities.
\ , l The gaseous effluents from the main condenser are held up ' i in the off-gas charcoal beds for at least 46 hours. This provides time for the decay of most of the radionuclides present since most have a: half-life of less than 8 hours, j.~ If gaseous effluents in the ventilation exhaust system
- for the containment Building and for the secondary i containment structure exceed conservatively set levels,
! they are processed through charcoal beds and ,high i efficiency particulate air filters in the Standby Gas i Treatment System before being discharged to the j environment. i i This combination of filters and charcoal beds is rated to be 95% efficient for removing lodines and greater than , 79% efficient for removing particulate material larger
- j. than one micron (one millionth of an inch) in diameter.
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l RADIOLOGICAL ENV RONMENTAL MONITORING PROGRAM
P e i III. RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM l A. PROGRAM DESCRIPTION The Clinton ' Power Station is required to. maintain a i radiological environmental monitoring program in l accordance with the Code of Federal' Regulations (CFR) Title 10, Section 20.1501 and . Criterion 64 of - CFR Title j .10, Part 50, Appendix A. The program.was developed using
- .the following guidance published by the United States ;
! Nuclear Regulatory Commission (USNRC)s l l
=> Regulatory Guide 4.1, " Programs for. Monitoring l Radioactivity in the Environs of Nuclear. Power Plants" l l '
=> USNRC Radiological Assessment Branch Technical :
j Position on. Radiological Environmental Monitoring j (1979) 1
- The Radiological Environmental Monitoring Program -is an I extensive program of sampling, measuring and analyzing d
that was instituted to monitor the radiological impact of 1 reactor operation on the . environment. . objectives of the program include: ! O ~ identification, measurement and evaluation of . existing radionuclides in the. environs -of the Clinton Power Station and fluctuations in radioactivity levels which may occur , O evaluation of the measurements to determine the impact l of Clinton Power Station operations on the local l radiation environment ! O collection of data needed to refine environmental 1 radiation transport models used in offsite dose l calculations
. O verification that radioactive material containment l j systems are functioning to minimize environmental !
j releases to levels that are ALARA 4 0 demonstration of compliance with regulations and : the ' l Clinton Power Station Offsite Dose Calculation Manual. < Implicit in these objectives are the requirements to trend and assess radiation exposure rates and ' radioactivity concentrations in the environment that may contribute to radiation exposure to the public. The program consists of two phases, preoperational (preop) and operational. L 21 _ _ _ _ _ _ _ _ _ _ _ . _ _ _ . _ _ . - - . - , _ . . _ , , . . _.,y,_ ,,__.,,.y , . . , _ .
i ; 1 l i The preoperational portion of the program was initiated in i May, 1980 and was completed on February 27,. 1987 to establish the baseline for the local . radiation l environment. Assessment of the operational impact of the. t Clinton Power Station on the radiation env.tronment is j based on data ~ collected since the . beginning of reactor , 4 operation. The operational phase implements confirmatory l measurements to verify that the in-station controls for , t the release of radioactive material are functioning as i designed. ! 1 a j Illinois Power Company maintains a contract with Teledyne - i Brown Engineering Environmental Services Midwest { i Laboratory -(TBEESE), formerly. Teledyne, Isotopes Midwest . Laboratory (TIE) , for analysis .of all radiological ! environmental samples. TBEESE is located in Northbrook,
- Illinois. Samples are collected by Illinois Power Company t personnel and shipped to TBEESE for analysis. After analysis, environmental samples are saved at TBEESE 'for a specified period of time in case additional analysis is required. Analytical results are reported monthly to company radiation protection personnel. .
Currsr.t regulatory guidance recommends evaluating direct - pathways, or the highest- trophic- level in a dietary 7 pathway, that contribute to an individual's dose. Figure i 3 - shows the basic pathways of gaseous and liquid ' radioactive offluents to man. The "important pathways" ' selected are based primarily on how radionuclides move through the environment and eventually expose individuals, as well as man's use of the environment. The scope of the program includes the monitoring of five environmental compartments: direct radiation atmospheric ' aquatic terrestrial environments ground and surface water. ; 1 Each pathway is . monitored at " indicator" and " control" locations. Indicator locations are generally within the 10-mile radius of the station. Control locations are located at least ten miles from the plant, far enough to be unaffected by plant operations. An increase in dose - rate or radioactive material concentration at an ir.dicator ; location may be due to plant operations. l
. t i
+.
i
l RELEASES DILUTED BY ATMOSPHERE -
=3 AIRBORNE ANIMALS a 5 RELEASES CLINTON POWER
; (MILK. MEAT) PLUME EXPOSURE STATION AND INHALATION
+
1
- \
CONSUMED BY PEOPLE \ ; } LIQUID RELEASES . RELEASES CONSUMED DILUTED - CONSUMED BY PEOPLE BY LAKE ! BY ANIMALS k
"" ^
l $ "EO LE h FISH [ SHORELINE EXPOSURE l . FIGUilE & POTENTIAL EXPOSwiE PATHWAYS W MAN DblE TO RELEASE W i RADI0 ACTIVE MATERIAL TO TM ENVIA0 Min lENT l
Locations of sampling ' stations are shown 'on maps in Figures 4 through 7. Table 3 provides a list of the sample codes for each sample medium and Table 4 provides information on sample location, media sampled at each location, and a brief description of each location where samples are taken. The location is listed according to distance (in miles) and the compass sector relative to the Station Heating, Ventilation and Air Conditioning (HVAC) stack. An on-site meteorological tower collects information such as wind speed, wind direction and air temperature at various levels. Meteorological monitoring is further discussed in section V of this' report. 25 __ _ _ - =_ ,
I 1 1 2 1 1 1 I e r 1 I I I l; 4 4 I i i 1 l l j i
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83 j i11 34 23 l 1 1 CLINTON
'Q 24 84 92 j {
LAKE ]p 94 i 16 9 25 85 2 j i ; l09 26 i
- 6 "31 66 I
ll30 110 29 .. 28 ,h b7
, \
1 I I I w A l FIGURE 4: REMP SAMPLE LOCATIONS WITHIN 1 MILE i 27 1 M,02345 3-8-! l
l I i i l N s 106 l l 62 f l 63 ! I
- \
I- ILL RT 54
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t l CLINTON j i 74 LAgg
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i k l N l li2 76 68 39
- 77 52 .
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1 l 2 7 1 [ O 42 ' 88 ! 61 Q $ 6 43 44 4) j i 4- %_? 00 ) l 60 sat.y $ELANE l3A 58 56 57 (5) ! _ / i 1 i i f FIGUM 6: REW SAWLE LOCATIONS FROM 2 - 5 MILES j 1 38 1
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i l I .1 ! TABLE 3 4
- CLINTON POWER STATION SAMPLE CODES 1 CODE S_AMPLEMEDIUM i'
AP Airborne Particulate l AI Airborne Iodine i l TLD Direct Radiation i . j M Milk l DW Drinking Water , ! I ! SW Surface Water l ' l J ! j WW Well Water l VE Green Leafy Vegetables i l j F Fish ! l j SL Slime or Aquatic Vegetation BS Bottom Sediments i < SS Shoreline Sediments i l SO Soil I i ME Meat i. l G Grass i ) i J l I J b 4 l i j 35 a i
i l i 8 . M
l j TABLE 4 REMP SAMPLE LOCATIONS *
- Station Sample Code Medium Location Description l
1 l CL-1 AP,Al,TLD SO,G 1.8 miles W Nearthe gate to Camp Quest,8 of Birkbeck i l CL-2 AP,Al,TLD SO,G 0.7 miles NNE Located on site's main access road.
, CoNocated with CL-70 and CL-71.
E CL-3 AP,Al,TLD,GO , 0.7 miles NE Located on site's secondary access road.
- CoNocated with CL-80.
CL-4 AP,Al TLD,80 0.8 miles SW Located on form GE oflilinois Power Recreation Area. Collocated with CL-67. i
- CL4 TLD 0.7 miles NNE . Located on sRe's main access road j CL4 AP,Al,TLD,SO 0.8 miles WSW Located near the INinois Power Recreation j Area softben fleid. CoNocated with CL46.
) CL-7 AP,Al TLD,SO 2.3 miles SE Located in the Moscoutin State Recreation Area a f CL-7B SS,8L 2.1 miles SE SE of site on Clinton Lake ! CL-7C BS,SL,SS 1.3 miles SE SE of sRe on Clinton Lake 1 i CL-70 WW 2.3 miles ESE Located in lilinois Power Department of j Conservation office et the Moscoutin i State Recreation Area i ] CL-8 AP,Al,TLD,80,G 2.2 miles E Located e DeWit Cemetery ? j CL-G SW,SL 2.7 miles ESE Located on NE side of DeWitt County Route 14 ', bndge , 1 ! CL-10c SW(1),BS,SS,SL 5.0 mues ENE Located on SE side of lilinois Route 48 bridge . I j- CL-11c AP,Al,TLD,80,G 16 miles S Lomted SW of Argente et the INinois Power j_ CL-12 WW 1.6 miles E Lomted atthe DeWitt pumphouse i 1 . CL-13 SW 3.6 miles SW Located near the Set Creek b ridge on Illinois l Route 10 4 CL-13A BS 5.0 miles SW Located on Set Creek at the Route 1300E ! bridge 4 i i CL 14 DW Plant Sennoe Located in the Plant Service Building Budding 1 N i 37~ 4 9n
TABLE 4 (Cont'd) Station Sample Code Medium Location Description CL-15 AP,Al,TLD 0.9 miles N Located north of CPS on Route 900N CL-16 SO 0.6 miles ESE Located ESE of CPS just north of dis $arge fiume CL-17 BS 3.5 miles SW Located on the lake side of Clinton Lake dem CL-19 F BS,SS,SL 3.4 miles E Located E of sRe at the end of the discharge fiume CL-20 TLD 9.1 miles ENE Located at the Campground Cemetery W of Farmer City CL-21 TLD 0.9 miles NNE Located at the intersection of IHinois Route 54 and the site's secondary access road CL-22 TLD 0.6 miles NE Located on the site's secondary access road CL-23 TLD 0.5 miles ENE Located on the site's secondary access road CL-24 TLD 0.5 miles E Located on the site's secondary access road CL-25 TLD 0.4 rniles ESE Located on the Owner Controlled Area fence CL-26 TLD 0.3 miles SE Located on the Owner Controlled Area fence CL-27 TLD 0.6 miles SSE Located on thi Owner Controlled Area fence near the Meteor, logical Tower CL-28 TLD 0.5 miles S Located on the Owner Controlled Area fence CL-29 TLD 0.6 miles SSW Located on the Owner Controlled Area fence CL-30 TLD 0.7 miles SW - Located on the Owner Controlled Aree fence at the entrance to lilinois Power Recreation Area CL 31 TLD 0.8 miles WSW Located on the Owner Controlled Aree fence near the lilinois Power Recreation Area softball fleid CL-32 TLD 0.7 milesWSW Located on the Owner Controlled Area fence neer Clinton Lake CL-33c TLD 11.7 miles SW Loosted in tieros at family residence 38
l l l TABLE 4 (Cont'd) Station Sample l Code Medium Location Description CL-34 TLD 0.8 miles WNW Located r} ear CPS Visitors Center .I CL-35 TLD 0.7 miles NW ' Located near CPS Visitors Center near lilinois Route 54 bridge CL-38 TLD' O.6 miles N Located on Illinois Route 54 near intersection with site's mein access road CL-37 TLD 3.4 miles N Located N of site CL-38 TLD 3.6 miles NNE Located near microwave tour N of site CL-39 TLD 3.8 miles NE Located 2 miles N of DeWitt CL-40 TLD 3.5 miles NE Located 0.6 miles N of dew!tt CL-41 TLD 2.4 miles E Located at S DeWitt city limit - l CL-42 TLD 2.8 miles ESE Located S of DeWitt County Route 14 bridge CL-43 TLD 2.8 miles SE Located on Clinton Marina access road J CL-44 TLD 2.3 miles SSE Located near Clinton Marine Boat Sales CL-45 TLD 2.8 miles S Located at Lane Day Use Area CL-46 TLD 2.8 miles SSW Located at Peninsula Day Use Area CL-47 TLD . 3.3 rnies SW Located near Clinton Lake Dem Access Rood CL-48 TLD 2.3 miles WSW Located at residence on West Side Access Road CL-49 TLD 3.5 miles W Located W of site along Illinois Route 54 1 CL-50 TLD 3.2 miles WNW Located WNWof site CL-51 TLO 4.4 miles NW Located NWof site CL-52 TLD 4.3 miles NNW Located NNWof site CL-53 TLD 4.3 miles E Located E of site CL-64 TLD 4.6 miles ESE Located 2 miles N of Weldon CL-56 TLD 4.1 miles SE Located 1.5 miles W of Weldon CL-66 TLD 4.1 miles SSE Located SSE of site 39
l TABLE 4 '(Cont'd) !
.)
Stabon Sample ! Code Medium Location Description CL-57 TLD' 4.6 miles S Located S of site ! CL-58 TLD 4.3 rniles SSW Located in rural Lene '
- CL40 TLD 3.3 miles SSW Located near Lane city hmit CL40 TLD '
4.5 miles SW Located SW of Chnton Lake Dem near Set Creek CL41 TLD 4.5 miles WSW ' Located WSW of site l CL 62 TLD ' 1.9 miles NW Located NWof site CL43 TLD 1.3 miles NNW Located at North Fork Boot Access CL44 TLD 2.1 mues WNW Located 0.5 miles N of Birkbeck CL45 TLD 2.6 miles ENE Located at residence in DeWitt i CL 06 TLD 0.8 milesWSW Located near the Illinois Power Recreation l Aree softball field. Collocated wth CL4. CL47 TLD 0.8 miles SW Located on form SE oflitinois Power Recreation Area. Collocated with CL 4. CL46 TLD 4.6 miles N Located N of site. CoHocated with CL-112. i CL49 TLD 0.7 miles NE Located on site's secondary access road. Colocated with CL-3. I 1 CL-70 TLD 0.7 miles NNE Located on site's secondary access road. I Collocated wth CL-2 and CL-71. CL-71 TLD 0.7 miles NNE Located on site's secondary access road. Collocated with CL-2 and CL-70. CL-72 TLD 4.5 miles NNE Located NNE of site. Collocated with CL-77 CL-73 TLD 5.1 miles ENE Looeted nearthe MidAmerice Commodmes plant on luinois Route 48. CoHocated with CL-113. CL-74 TLD 1.9 miles W Located at Camp Quest CL-75 TLD 0.9 miles N Located N of site ! 1 CL-76 TLD 4.6 miles N Located N of site CL-77 TLD 4.5 miles NNE Located NNE o' site. Collocated with CL-72. . 1 40 l l l
TABLE 4 (Cont'd) l Station Sample Code Medium Location Description CL-78 TLD 4.8 miles NE Located NE of site l CL-79 TLD - 4.5 miles ENE Located ENE of site CL40 TLD 4.1 miles W Located Wof site 1 CL-81 TLD 4.5 miles WNW Located WNW of site l l CL-82 TLD 0.9 miles W Located at lilinois Power Recreation Area l CL-83 TLD 0.5 miles NNW Located near Illinois Route 54 E of the bridge CL44 TLD 0.6 miles E Located on Old Clinton Road between DeWItt and site. Collocated with CL-94 and CL-86. I CL-85 TLD 0.6 miles ESE Located ESE of sde CL-86 TLD 0.6 miles E Located on Old Chnton Road between DeWitt and site. Collocated wrth CL44 and CL-94. J l CL47 TLD 0.6 miles SE Located near discharge flume road l l CL-8B SS 2.4 miles SE Located SE of site CL-89 BS,SS 3.6 miles NNE Located NNE of site i CL-90 SW 0.4 miles SE Located at start of discharge f!ume l l l I CL-91 SW S.1 miles ENE Located at Pamell Boat Ac:ess l l CL-92 SW 0.1 miles NW Located at CPS Intake Screenhouse . l CL-93 SW SS 0.4 miles SW Located at CPS Settling Pond CL-94 AP,Al,SO 0.6 miles E Located on Old Clinton Road between DeWitt and site. Collocated with CL44 and CL-86. l CL-95c TLD 10.5 miles W Located at a family residence west of Clinton CL-96c TLD 10.9 miles WSW Located at a family residence SW of Clinton i CL-97c TLD 10.3 miles SSW Located on Macon County Road 1400E SE of Meroe j CL-98 M 0.7 miles SSW Located at a family residence SSW of site l CL-99 SW 3.5 miles NNE Located at the North Fork Canoe Access Are I CL-105c F,SS,BS,3L 50 miles S Located at Lake Shelbyville 41 i
.-. . . . . . . - . . . ~ , . . . . .
l l TABLE 4 (Cont'd) Staton Semple Code Medium Location Description CL-106 IME 2.0 mHes NNE ' Located'NNE of site CL-100 TLD 0.7 muss WSW Located on the Owner Controlled Aree fence near Shooting Range CL-110 TLD 0.8 miles SW Located on the Owner Controlled Aree fence CL-111 TLD 0.6 miles NE Located near site's secondary access road f CL-112 TLD 4.6 miles N Located N of site. Collocate d with CL 68. ; l CL-113 TLD 5.1 miles ENE Located near the MidAmence Commodities plant , on luinois Route 48. Collocated with CL-73. i
. CL-114c VE 12.5 miles SSE Located S of Cisco r
CL-115 VE 0.7 miles NE Located on site's secondary access road . [ CL-116c M,G 14 miles WSW Locatedin rural Kenney ) l CL-117 VE ' O.9 miles N Located N of site ' i CL-118 - VE 0.7 miles NNE Located on lilinois Rt54 neer interseebon ! with mein access road ! Sample locahon is listed by station code, location and number. Staton Code is Clinton (CL)- Number ! (site's number designetor). Location is listed by distence in miles and diredional sector from the l l Stobon HVAC stack. i c Control location; su cther locations are indicators. ' (1) Control location for surface water only. l l l 42 l
-k
i : ! B. Direct Radiation Monitoring : ! Radionuclides present in the air, and those deposited in ; i or on the ground cause human exposure by immersion in the ! atmosphere or by deposition on the ground. TLDs l (thermoluminescent dosimeters) are used to measure the . l ambient gamma radiation field at many locations around the l
- Clinton Power Station. i
! TLDs are crystalline devices that store energy -when they f j are exposed to radiation. They can be processed months i after exposure with minimal loss of information. This ! makes them well suited for quarterly environmental
- radiation measurements.
s A During processing, the stored energy is released as light ! ! and measured by a TLD reader. The light' intensity is ' j proportional to the radiation dose the TLD received. The . TLDs used in monitoring around the Clinton Power Station i l are easily capable of measuring environmental levels of j
- radiation, approximately 20 mrem per quarter. '
) Monitoring stations are placed near the site boundary and
- approximately five miles from the reactor, in locations i representing the sixteen compass sectors. Other locations
; are chosen to measure the radiation field at places of
- special interest such as nearby residences, meeting places j and population centers.
Control sites are located further than ten miles from the l site, in areas that should not be affected by plant operations. I
- TLD measurements register the gamma ray exposure in j milliroentgen (mR). For reporting purposes mR is l numerically equivalent to arem. Consequently the terms !
are used interchangeably. ! 1, 1 j A total of 342 TLD measurements were made in 1994. The average quarterly dose at indicator locations was 18.2 ; arem. These quarterly measurements ranged from 14.0 to i 23.0 arem. At control locations the average quarterly
; dose was ' 17.8 arem. These quarterly control measurements ranged from 15.7 to 20.3 area. ! Figure 8 compares the ,1994 quarterly TLD results with preoperational TLD quartorly averages.
i l Average doses (12 standard deviations), broken down by calendar quarter, are shown in Table 5 for both indicator 1 and control locations. i 43 )
i l l l l l l l l l
_.. -_._. _ ...... . _ ... ..._.. . . _ _ . _ _ . _ _ _ - - _ - - _ . _ _ . . _ . . _ . _ . _ _ _ _ _ . . _ _ . _ . . . . __m_-.. _ . . _ _ _ _ . . . . _ . . . _ . . _ . _ . _ _ . . . 30 - - - - - - - - - - - - - - - - - - - - - - - - ---
.I 28 s Preop Data a 1994 Indicator 26 01994 Control 24 E
, 22 e
E - 20 i I i a
- u. I 18 =_x ===
l
~l r
, m- '
16 - W - _ _.
=__
14 - i
=
! u=
1 w__ 12- E l M-I i M 10 i i . i
' Quarter
- FIGURE 8: DIRECT RADIATION COMPARISON 1
4 e sm_. _ _ u _. - - _ _ _ ________._.-._-_m.m. ___._- ______-m_ _ _ _ . _ _ - - - - -__ -_ -----._______m _- . _ _ . _ _ . - __.__-.__:__-____..__-.---_m_
- . - . . ~ . - - -_ .- -- . . - - -
(.
^
i 1 l j t
- j. TABLE 5 g
; AVERAGE QUARTERLY TLD RESULTS i
!' 1993 1994 PREOP i OUARTER INDICATOR INDICATOR ALL SITES i ist 17.7 *3.3 17.7 *2.9 16.4 *2.9 j 2nd- 18.7 2.8 17.7 *2.9 18.8 3.2 3rd 19.0 2.9 19.2 3.6 19.1 *4.7 i 4th 18.3 *3.2 18.3 *3.4 17.8.*2.2' , 1993 1994 PREOP ! I OUARTER CONTROL CONTROL ALL SITES r 1st 17.4 *2.3 17.6 *2.4 16.4 *2.9 , j- 2nd_ 18.2 *2.8 17.2 *3.1 18.8 *3.2 i- 3rd 19.1 3.6' 19.0 3.0 19.1 *4.7 { 4th ;17.7 *2.2 17.3 *2.6 17.8 *2.2 , i i i . j Site CL-83, located 0.5 miles NNW of; the- station, j registered the -highest annualized doses 83.5_. arem during
- 1994. I
! l From these observations, no increase in environmental i gamma radiation levels resulted -from operation -'of the ; 4 Clinton Power Station during 1994. l !
- C. Atmospheric Monitorino l i The inhalation and ingestion of ' radionuclides in the air is a direct exposure pathway to man. A , network of ten F jl active air samplers around the Clinton Power Station )
- monitors this. pathway. 'There are nine indicator air '
i sampling stations strategically located in areas which-are 4 l most likely to indicate offacts due to the release of ? j radioactive ef.fluents from the Clinton Power Station. The ! ! control location is located approxisately 16 _ miles south _ )
- ' of the plant in an area which is likely to be independent-l ~ of the r,ffacts of station operations. Historical i meteorological data indicates this control location is 3
normally upwind from the plant. ! No contribution _ to the general level of airborne i particulate radioactivity could be identified as a . result 4-of station operations during 1994. The radioactivity that was detected is normally found in the environment 'and is
- consistent with expected. concentrations' of natural
! radioactivity and fallout from prior atuosptcric nuclear j weapons testing. 47
( - . . - . . . - - - - . - . - - . _ - .- .. Mechanical air samplers are used to draw..a continuous ,
- volume of air through a filter and charcoal cartridge to collect particulates and radioiodines present in the atmosphere. The. samplers are equipped with a . pressure-
- sensing flow regulator to maintain a constant sampling !
- flow rate of.' about one cubic foot per- minute. The total i volume is calculated based on the amount-of time the air i sampler ran and its flow rate. The air sampling equipment
! is maintained and calibrated by the Clinton Power Station .
- personnel using reference standards traceable to the
- l National Institute of Standards and Technology. ,
i l Air samples are collected weekly and analyzed for ' gross ! I beta and I-131 activities. Quarterly, all air particulate {~ filters collected during that period are combined. and : a counted for gamma isotopic activity. Since the intent of ., l particulate sampling is to measure airborne radioactivity ; { released from the plant, the counting of short-lived l daughtero produced by the decay of natural radon and ~ ! thoron may mask plant contributions. Therefore, the i filters are ' not analyzed for at least . five days after their collection to allow for the decay of the short-lived. i daughters, theroby reducing their contribution to gross ; L beta. activity.. ! l . . . l Results of - the gross beta airborne particulate analyses i
- i. provided comparisons between indicator. and control !
l locations for the year, as well as comparisons - between
- j. locations'inrelationtospatialandtemporal: differences. i
- The calculated annual average was 0.020 pCi/m for all j i indicator locations and 0.020~ pCi/m3 for the control !
l location. These results are: consistent' with the i i preoperational averages for both indicator- and control l4 locations which were-0.027 pC1/m3, ; 1 ! The location with the highest calculated annual average i l was indicator station CL-3 located 0.7 miles northeast of
- the Clinton Power Station. This location had' an average
[ concentration of 0.021 pCi/m3 Individual . location
- averages for the year are presented in Table 6. ,
n l Minor fluctuations -in the gross beta concentrations were
- i. noted throughout the year. The general trend for. average i weekly gross' beta concentrations in the' indicator !
- locations correlated to the trend for control locations
~
i
- ' ' throughout the monitoring - period. This. correlation is i evidenced by the similarity of the trends in the average i monthly gross beta concentrations displayed in Figura 9.' i No significant difference was indicat*d betwsse individual l locations. Monthly averages . for indicator and ' control I locations for the year are presented in Table 7. !
i l
. I 48 I
l __r __m_m,______m_____m _ _ . _ , - -
E
- All gross beta concentrations for 1994 were within normal
- background levels and no increases were noted as a result
- of the operation of the Clinton Power Station.
I Naturally occurring Be-7 was the only gamma-emitting i ! radionuclide detected in analyses of particulate filters. I TaaLa 6 l l ! Avanana emoss aura epen 3rmaTroms i i IN AIR PARTICUM Iq1 ! ;994 1993 ' ! Avers.ge t 20 Average i 20 ' ! Station Descriotion 3i _ ,yi/m roc 1/m3) i , CL-1 Camp Quest (Birkbeck) J.019 0 0.014 0.019 i 0.012 CL-2 CPS Main Access Road 0.020 1 0.014 0.020 1 0.014-- ; ) CL-3 CPS Secondary Access 0.021 1 0.015 0.022 1 0.014 l ! Road ! 3
- CL-4 0.8 miles SW 0.021 1 0.015 0.020 1 0.014 j CL-6 IP Recreation Area 0.021 1 0.015 0.021'i 0.015 i i ;
) CL-7 Mascoutin State 0.017 i 0.014 0.019 1 0.014 : Recreation Area 4 ! CL-8 DeWitt Cemetery 0.020 1 0.014 0.021 1 0.015 f j CL-11a IP Substation 0.020 1 0.013 0.021 1 0.014 [' j (Argenta) i j CL-15 0.9 Miles N 0.020 1 0.014 0.020 1 0.015 , ! CL-94 O'Id Clinton Road 0.020 1 0.015 0.019 i 0.014 i (0.6 miles E) . s (a) Control Station i i 1 i ; 4 l 49 < 1 l
TABLE 7 i AVERAGE MONT5Y GROSS BETA GOmm-a_ ATIONS IN AIR PanTICtrr2TES f (DCi/m') , 1993 1994 1993 1994
- In&cabr Indcabr Control Control Month so- ,.a svan.a sme.a sme.a
! January 0.030 3 0.003 0.029 3 0.004 0.029 0.018 0.029
- 0.006 February 0.026 3 0.003 0.022 0.005 0.029 z0.005 0.022 a 0.002 4
. Manh 0.018 3 0.012 0.019 3 0.002 0.018 3 0.011 0.017 z0.003 1
April 0.014 z 0.001 0.014
- 0.001 0.014 3 0.007 0.015 3 0.003 May 0.015 0.002 0.011 0.003 0.016 =0.007 0.011 3 0.006
.kre 0.015 3 0.002 0.016 z0.003 0.017 z0.003 0.019 e 0.006 July 0.017 3 0.003 0.016 3 0.003 0.018 3 0.004 0.018 z0.006 August 0.018 3 0.004 0.019 z0.004 0.021 0.010 0.018 0.007 September 0.015 z0.003 0.021 z0.004 0.018
- 0.002 0.021 3 0.012 Ochber 0.021 0.003 0.019 z0.003 0.024 3 0.007 0.019 e0.004 Nowrober 0.026 3 0.003 0.020 0.002 0.025 + 0.006 0.021 3 0.003 l Deostrber 0.024 3 0.004 0.033 3 0.004 0.025 z 0.005 0.032
- 0.013 i I
1 I i 50
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. T P
T - E S W l T C G A - U A A T E B L S _ U S _ . J H T O - ~ N R G O N M E U J T A L _. U C I _ W T - . R _ A P m R I A A: 9 R E R U _ G I F 2 2 2 2 2 2 2 2 7 6 6 4 3 2 1 0 _ 0 0 0 0 0 0 0 0 - 0 0 0 0 0 0 0 0 _
=
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$ t b>=O<
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- j t
4 $ l i- D. Aquatic Monitoring ,
- i i The Clinton Power Station utilizes a man-made lake as the j source of cooling water and returns the-used cooling water ,
j to the same lake while- most nuclear power stations use once-through flow from a river, the ocean or a . body of :
- water auch larger than Clinton Lake. - When radioactive j j liquid offluents are discharged from the 'Clinton Power *
! Station into the cooling water outfall, radioisotopes with 'i l long half-lives could build up as.the same. water is reused : j on successive trips through the plant. This water' travels : e from the plant, into the eastern arm of the lake, .then !
- j. into the northern arm of the lake and back into the plant. >
j Although the only user of Clinton Lake as of !
- drinking water is the Clinton Power Station, . athe ' source lake is a ,
- major recreational facility, . used for fishing, sw1JERing, j water skiing, boating and hunting. ,
- .Clinton Lake constitutes the environmentr *
- exposure pathway for radioactive primary, materia ls in liquid i
< effluents.. Aquatic monitoring provides for.the collection i
- of fish, shoreline and bottom sediments,. and periphyton ,
. samples to detect the presence of any radioisotopes ; i related to operation of the Clinton Power Station. These " , samples are analyzed for naturally occurring and man-made
- radioactive materials. Both indicator and control ;
! locations were sampled ' during . 1994. . Indicator samples ; j were taken from various locations on Clinton Lake and the 4 control samples were taken at Lake Shelbyville which is : l approximately 50 miles south of Clinton Power. Station. 3 i Aquatic monitoring samples are collected by personnel from I i the Field Biology Laboratory of the Environmental Affairs j Department of Illinois Power. Company. l, Ziah l Samples of fish are collected from Clinton Lake and Lake i Shelbyville. In both lakes the samples include largemouth j bass, crappie, carp and bluegill.' These ' species are the i fish -most commonly harvested ~frot. the . lakes by sport
- j. fishermen. Fish ingest sediments during bottom feeding, a or prey on other organisms which ingest sediments or i j otherwise retain . radionuclides. Radiological analyses of these fish samples provide information on the potential' t '
l ingestion of radionuclides by humans' via the aquatic 1 pathway. These samples are collected semiannually and 4 j analyzed by gamma spectroscopy. l t
- The results of gassa isotopic analysis on the fish samples 1 shewed ' the presence ,of naturally occurring K-40' in all i j
1994 . samples ranging from' 2.24 to 3.41 pCi/g '(wet). Preoperational K-40 concentrations ranged from 1.71 to j - 4.61 pCi/g (wet) . All other analytical results were.less j 2 3 53
- i
1 1 i than the lower limit of' detection (LLD) for each ! radionuclide. { ! Shoreline Sediments i
! Samples of~ shoreline sediments are collected at six
- locations from Clinton Lake, at one location from the i Clinton Power Station lower settling pond and at one i j location from Lake Shelbyville. Radiological analyses 'of )
shoreline sediments provide information on the potential )
- shoreline exposure to humans and for determining long-term i j trends and accumulation.of long-lived radionuclides in.the i i environment. Samples' are collected semiannually- and i
analyzed ' for gross beta, gross alpha, Sr-90 and gamma i
- isotopic activities.
1
! Shoreline mediment samples are dried prior to analysis and
! the results are ' reported -in pCi/g dry weight. Naturally occurring radioisotopes, such as K-40, Ra-226 and Pb-212, j 1 .were present in samples taken at both indicator and { control locations. There were two fission products, Cs-137 and Sr-90, detected from both control and indicator l , locations. The activity detected was not substantially
- different from that measured during the preoperational i program.
j i w i The presence of these fission products is attributed to previous nuclear weapons testing . and atmospheric fallout. j from the accident at chernobyl.- 1 ) Preop Range 1993 Range 1994~ Range I i foci /o dryi foC1/a dry) fDCi/a dry) : , Sr-90 0.009 - 0.087 0.013 - 0.172 0.009 - 0.012 ' l Cs-137 0.016 - 0.045 0.060 - 0.62 0.016 - 0.047 ' i j Gross alpha activity in samples of shoreline sediments collected from all locations ranged from 3.48. to 9.74 pCi/g (dry) during 1994. This . activity was attributed to - i naturally occurring radioisotopes. and decay _ products i present in soil. These values compare closely with the i activity detected in the preoperational program which j ranged from 3.8 to 8.0 pci/g (dry).
?
j Gross beta activity in samples of shoreline sediments collected from all locations ranged ' . from 4.11 to 21.19
- pci/g (dry) during 1994. The majority of this activity j was attributed to naturally occurring K-40.. These values
' are comparable with the gross beta activity detected in the preoperational program which ranged from 7.0 to 17.2
- i. pci/g (dry).
M
i i i i- _
- Bottom Sediments i Samples of bottom sedhnents are collected from Clinton
! Lake at six ' locations .and Lake Shelbyville at one ' location. Radiological analyses of bottom sediments i primarily provide information about; the- amount of j radionuclides _available to predators .who feed on the organisms found in bottom sediments. Samples- are collected semiannually and analyzed for gross beta, gross
- alpha, Sr-90 and gamma isotopic activities.-
i ! Bottom sediment samples are dried prior to analysis and the results are reported. in pel/g dry weight. Naturally i occurring radioisotopes, such as K-40 and Pb-212, were .
- present in .all 1994 control and indicator sample ,
locations. ! Cs-137 was detected in samples from both indicator and ! control locations. Sr-90 ' was detected in the control l' location only. Both radioisotopes are fission products. I Preop Range 1993 Range 1994 Range j (oci/a drv) ioci/o dry) Ioci/a dry) i Sr-90 0.011 - 0.056 0.015 - 0.05 0.011 - 0.021 i j Cs-137 0.008 - 1.39 0.013 - 0.560 0.017 - 0.38 ) i - e . ! The presence of these fission products is attributed to ! i previous nuclear weapons testing' and atmospheric fallout i i from the accident at Chernobyl.
- Gross alpha activity in samples of. bottom sediments i collected from both lakes ranged from 5.31 to 13.95 pCi/g l (dry) during 1994. This activity was attributed to i naturally occurring radium isotopes and decay products 1 present in soil. The preoperational gross alpha activity j ranged from 4.4 to 14.7 pCi/g (dry).
! l
- j. Gross beta activity in samples of bottom sediments I l collected from both lakes ranged from 9.28 to 28.58 pCi/g (dry) during 1994. The majority of this activity was !
K-40. The
- attributed to . naturally occurring
- preoperational gross beta activity ranged from 8.3 to 27.7 l
. pCi/g (dry). i
) Aquatic Vegetation iPeriphyton1 ) samples of periphyton are c:ellected fron five locations in Clinton Lake and one location. in ~ Lake Shelbyville.
; Periphyton (attached algae) are collected from the 5
4 ) 55 l i
3 submerged surface of the- permanently anchored buoys or_ natural substrate. Periphyton absorb trace elements and radionuclides directly from' water, often concentrating them to levels much higher than the dilute concentrations - < that - occur .in the aquatic environment. This is because 4 most algae are coated with a carbohydrate jelly and have a large surface-to-volume ~ ratio. Cell. division usually occurs once every one or two days and, as a result, half of the cell wall is- a' new. surface' for sorption. Periphyton' represent one of'the earliest links in~the food. ' chain and provide information about- the amounts of radionuclides available to predators further up the food chain. Samples of . periphyton are collected every . two months between April and October (during the colder months growth is limited) at the indicator locations and semiannually at the control location and analyzed by gamma spectroscopy. - The results. of the gamma isotopic analyses' on periphyton j samples showed the following. concentrations of naturally-occurring radioisotopes: 4 Preop Range 1993 Range 1994 Range i fDCi/a drvi fDCi/a drv) fDCi/a dry)- ' Be-7 0.38 - 1.07 0.51 .2.71 0.10 - 1.42 K-40 0.74 - 6.82 0.81 - 6.1 0.25 - 4.76 . Cs-137 0.042 - 0.15 0.023 - 0.082 0.026-- 0.085 i one fission product, Cs-137, was detected ~in several periphyton samples. Concentrations for Cs-137 in 1994 ranged from 0.026 to 0.085 pCi/g ' (wet) . Preoperational I results for Cs-137 .showed concentrations ' ranging from 0.042 to 0.15 pCi/g (wet). The presence ~ of Cs-137 is attributed to previous nuclear weapons testing and atmospheric fallout from the accident at chernobyl. Periphyton analyses are included in the. Clinton Power station Environmental Monitoring Program because of their sensitivity to the presence of radionuclides in the aquatic environment due to bio-magnification. Using periphyton as biomonitors for radionuclides in aquatic ' systems can be a highly sensitive and qualitatively effective means of environmental monitoring around nuclear power plants that release radioactive l effluents to aquatic systems. It enables the Radiological Environmenta.1 Monitoring Program to determine the relative presence of radioactivity before it becomes a problem. 56
l E. Terrestrial Monitorina j In addition to the' direct' radiation, radionuclider present [ in the atmosphere expose individuals when deposited on
- surfaces (e.g., plants and soil) and . are subsequently
- ingested directly by man or indirectly by consumption of i animal products (e.g., meat and milk) . To monitor this l food pathway, samples of green leafy vegetables, grass, )
j- milk and meat are analyzed. I
- .i l Surface soil samples are collected and analyzed annually - ,
l at the sewage sludge application site to ensure ; radionuclides attributed to the operation.of Clinton Power _; j Station are not being land applied with the processed - 4 sewage sludge. Every three years, samples are taken at ! nine other locations to monitor the potential buildup of
- atmospherically deposited radionuclides. i i >
! Surface vegetation samples are collected from a number of , ! locations for the purpose of monitoring the potential .
- buildup of atmospherically- deposited radionucliden.
~
i Because the radionuclides of interest, with respect to the l l Clinton Power Station operations, are also present in the
- environment as a result of several decades- of worldwide j fallout or because they are haturally occurring, the i presence of these radionuclides is expected in all;of the ;
j, samples collected. ;
- t j The possible contributions of radionuclides from the i j operation of the Clinton Power Station are assessed by l l comparing the results of samples collected in prevalent
! downwind locations (north to north north-east of. the l plant) with control samples and- samples collected in j locations generally upwind of the plant. .In addition, the > 4 results of samples collected during 1994 were compared ! with the results of samples collected during the j preoperational program. In addition to naturally occurring radioisotopes, Sr-90 j and Cs-137 were found in a number of 1994 samples. l However, the concentrations of radionuclides in samples collected near the Clinton Power Station were comparable
- to the concentrations in samples collected at locations remote from the station. The presence. of these fission
- products is attributable to previous- nuclear weapons
- testing and fallout from the accident at Chernobyl. The i operation of Clinton Power Station had no measurable l contribution to the radioactive concentration of the
{ terrestrial environment. Hilk ! There is no known tsaercial production of milk for human consumption within a five-mile radius of the Clinton Power t j 57 a m, rm-
i 1 j Station. Milk samples are collected from a dairy located ) J about 14'ailes. west southwest'of the station and goat milk i j_ is collected from a family residence 3.5 miles south- ; i southwest.of the station (twice a' month during May through 1
! October and once a month during November through April).
} These samples' 'are analyzed for " I-131, Sr-90 and gamma j isotopic activities. L The results of the analyses showed positive concentrations j j of K-40 and Sr-90 in all'1994 samples with-a range of 1100 i
- to 2150 pci/1 for K-40' and 0.9 to 3.2 pCi/l for Sr-90. ;
Preoperational activity of ~ K-40 in milk ranged from 706 : a to 1375 pCi/1. Strontium-90 analysis in milk was added to-the REMP ' during the operational phase of tho' program, i ; j therefore there~ were no preoperational data for this .
- isotope. I-131_was not detected _in any milk ' sample
- obtained during- 1994. Figure 10 presents the Sr-90 t i results graphically.
5 i GEASA l In addition to - milk samples, grass samples are collected I' L ~ at three indicator locations and at two control locations.
- These samples are collected twice a month 'during May- i
- through October and once a' month during November through- i
! April. These samples are analyzed ' for gamma isotopic. , i activity including I-131.- j The results of the analyses showed only _ ' naturally 2 occurring Be-7 and K-40 in all 1994 samples. . Iodine-131 j was not detected in any grass samples obtained during ! ! 1994. ' i. ! Preop Range 1993 Range 1994 Range j fnci/a wet) foci /a wat) foci /a vet) {- Be-7 0.022 - 14.0 0.06 - 12.04 0.21 - 22.12 j K-40 0.22 - 14.5 { 0.47 - 9.37- 0.60 - 22.08 I i veaetables l-4 The Clinton - Power Station obtains broadleaf vegetable ! samples from three indicator locations and at one control ! location. The indicator locations are located in the
- j. sectors with the highest' potential for surface deposition and the control location is in a sector and at a-distance which is considered to be unaffacted by plant operations.
Samples are collected once a month during the growing season (June - through September) and analyzed for gross l beta and gamma isotopic activities including I-131. i J _ _ _ __ _ ___ _ __ _.__. __ _. ______ - _ _ _ __ _ __ ___ _~ _ _ _ _ __ _ _- J
10.0 9.0 8.0
'" * '(
- 7,n -m--1994 Control (Cow Milk) m
- Milk unavailable at indicator location 3 6.0 0
Q.
~
5.0 N 3
*C 4.0 3.0 2.0 E E ^
1.0 v % == s- - t V r 0.0 , l 1/2S* 2/23* 03/30 04/27 05/11 05/25 .06/08 06/22 07/06 07/20 08/03 08/17 08/31 09/14 09/28 10/12 10/26 11/30 12/28 DATE FIGURE 10: STRONTIUM-90 ACTIVITY IN MILK
1 1 ) 4 l 1 1 i The results of the gamma isotopic analysis showed only , naturally occurring K-40 and Be-7. 1 4 l Preop Range .1993 Range 1994. Range. j ioci/a weti foci /a'weti foci /o wet) ) Be-7 0.082 - 0.69 0.04 - 0.55' i 0.010 - 0.67 l K-40 1.45' ^7.00 1.44 - 6.34 1.99 - 8.59 i Gross 0.87 - 8.80 1.52 - 6.89 l'.86 - 14.74 i Beta 3 Iodine-131 was not detected in any vegetable samples
- during 1994.
t i 4 As an additional check on the presence of radioactive-materials in terrestrial exposure pathways, annual samples
- of beef liver, beef thyroid and edible beef portions are collected fro
- n an animal raised near the Clinton Power i Station. These samples are analyzed' for gamma isotopic activity including I-131.
The results of the gamma isotopic analysis showed only naturally occurring K-40 in the liver and the edible beef portions at 2.50 and 2.76 pCi/g (wet) respectively.
, Preoperational activity ranged from 1.95 to - 2. 7 8 pCi/g ,
(wet). I-131 was not detected in the meat samples during . 1994.
- Soil samples adjacent.to' air sample stations are collected triennially from nine indicator locations and one control
- location. The samples are collected to monitor the potential buildup of atmospherically deposited radionuclides.
One soil sample is collected annually from an area where j i Clinton Power Station land applies processed sewage sludge i from the Clinton Power Station Sewage Treatment Plant. l soil samples are sifted to remove any stones or debris, i then dried and analyzed. All soil samples are analyzed l for gross beta, gross alpha and gamma isotopic activities. The results of the gross beta activities ranged from 19.24 to .25.0 pci/g (dry) . Gross alpha activities ranged from 6.58 to 12.92 pci/g (dry). 61 , i
I l na-a isotopic. activity indicated several naturally occurring isotopes, such as K-40, Bi-214 ' and Pb-212, and one fission product, Cs-137. Cs-137 concentrations ranged from 0.037 to 0.44 pC1/g (dry). Preop Range 1993 Results 1994 Results ioci/a dry) foci /a drvi* foci /a drvi f Gross Beta 17.7 - 24.7 22.78 19.24 - 25.0 ) Gross Alpha 6.2 - 10.4 10.72 6.58 - 12.92 Cs-137 0.14 - 0.40 0.041 0.037 - 0.44
- Only one sample taken in 1993 ,
The presence of Cs-137 is attributed to previous -nuclear weapons testing and atmospheric fallout from the accident at Chernobyl. F. Water Monitorina water monitoring provides for the collection of drinking water, surface water and ground water (well water) samples to detect the presence of any radioisotopes related to the operation of the Clinton Power Station. The only identified user of water from Clinton Lake for domestic purposes is the Clinton Power Station; all others potentially exposed to any radioisotopes . released inte surface' or_ ground water would not be affected for .several years. Samplas taken were analyzed for naturally occurring and man-made radioactive isotopes. Average gross beta concentrations in surface, drinking and ' wall water are presented in Table 8. Drinkina Water The Clinton Power Station domestic water system is the l only known direct user of water from Clinton. Lake for human consumption. A composite water sampler located in the service Building collects a small, fixed volume sample at hourly intervals. The sampler discharges. each sample into a cosmon sample collection bottle. Therefore,' the monthly sample analyzed by the contracted. laboratory service is a composite of the individual saeples. 62 l l
5.0 4.5 --------------------------------------------------------------------------- ------------------------
---M--1994 Activity 4.0
-+---Preop Activity 3.5 - ------------------------------------------------------------------------------~~~-------------------.
e 3.0 - ---------------------------------------------------------------------------------------------------. oa. w p 2.5 - --------------------------- - -----------------------------------------~~--------------------------. i-- N O 2.0 -------- - ---- -- --------- - ------ - -- ----- ----- -- ------- -------------- -----------. cn
< W u
1.5 --------------------- -------------- -------------- - ------------- ------ --- -- -----------. 1.0 - ----------------------------------------------------------------------------------------------------. 0.5 - -------------- ------------------------------------------------------------------------------------. 0.0 , ; , , JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MONTH FIGURE 11: DRINKING WATER GROSS BETA COMPARISON
1 i t collected throughout the month. The monthly composite l f sample is analyzed for gross alpha, gross beta and gamma i
- isotopic activities. A portion of each monthly sample is !
i mixed with the other monthly samples collected during each I calendar quarter. The quarterly composite sample is j analyzed for tritium. I Gross beta activity ranged' from 1.3 to 2.3 pci/1. These
, levels are attributed to very fine particles of sediment ! containing K-40 which are not removed during the. ; chlorinating and filtration process. Monthly drinking )
water gross beta concentrations are presented in Figure .!
- 11. 1 i l J
Gamma-emitting _ radioisotopes were all below the lower ! . limits of detection. 1 4
- The results of all analyses for tritium and gross alpha activity were all less than the lower limit of detection. 1 j These results shok no measurable effects on drinking water !
j resulting from operation of the clinton Power Station j during 1994. i , j Surface Water I i
- composite water samplers are installed in four locations j to sample surface water from Clinton Lake. These-samplers j collect a small volume of water at regular' intervals and
! discharge it to a large sample collection bottle. These j bottles are collected monthly. i Two of the _ composite samplers are located upstream from ! Clinton Power Station and are unaffected by plant liquid i releases downstream. The two other composite samplers are 1 l positioned at the locations most likely to be affected by i plant operations (one samples the intake water to the j circulating water Intake Structure and the other samples ! the water at the start of the plant discharge flume).' i l Monthly grab samples are collected from two indicator i- locations and one control location on Clinton Lake. One i additional- indicator sample is obtained from the clinton , Power Station lower settling pond. I k surface water samples are analyzed for gross beta, gamma
- isotopic and tritium activities. Additional analyses for gross alpha activity are performed on the upstream water samples. Additional analyses for gross alpha activity and i I-131 activity are performed on water samples taken from.
the discharge flume. Tritium ' analyses are performed l monthly on samples from the lower settling pond, the
- intake . structure water samples and the upstream composite j i
i
- i. i
water samples, and quarterly from composites of monthly samples at the other locations. The 1994 results of the gross beta analyses ranged from 'I 0.8 to 8.6-pCi/1 at the indicator locations and 1.6 to 4.3 l pC1/1 at.the control location.- Preoperational gross beta- l activity. ranged from 1.1 to 7.6.pCi/1. These results are attributed to ' naturally occurring , K-40 suspended as fine sediment particles in. water. Other types of._ samples have- . confirmed the presence of K-40.'in Clinton - Lake shoreline and - bottom sediments. Monthly surface water gross beta ' activity for the~ control and indicator locations are presented. graphically in Figure 12. ;
' Tritium analyses. performed on samples ranged from 186 to !
653 pCi/1. The preoperational' tritium concentrations ! ranged from 220 -to 330 pCi/1. As noted in reference , (EI87), previous nuclear weapons testing increased the. ; pre-1960 levels of . tritium (6-24 pCi/1) by a factor of : approximately fifty (300-1200). Since the - levels of tritium reported . fell within this range of the ' existing, l non-rcactor-related, natural inventory of tritium, it is : considered that these positive results were not associated ; with operation of the Clinton Power Station. i namma-emitting ~ radioisotopes were all -below the lower l limits of - detection, and there was no - iodine-131 detected ! in any surface water sample during 1994. Gross alpha. activity was detected in several- of the surface water samples analyzed. These results ranged from 0.5 to 5.4 pCi/1. Preoperational gross alpha activity ; ranged from 1.3 to 1.9 pCi/1. These results' were ' t attributed to naturally occurring radioisotopes, such as . U-238 and Ra-226, suspended as fine sediment particles in ; water. These results show no measurable change l'n radioactive material concentration in surface water due to operation l of the Clinton Power Station during 1994. ' 66
., ,- .,. -r
t 10.0 , 9.0 - ----------------------------------------------------------- -+- 19941NDICATOR ---- 8.0 - ----------------------------------------------------------
-N-1994 CONTROL ____
---e-- PREOP INDICATOR 7.0 - ------------------------------------------------------------------------------------- ----
5 U 6.0 - ----------------------------------------------------------------------------------------- v a g 5.0 - ---------------------------------------- ------------- ---------------------------------- a G 4.0 - ---------------------------------------- ------------ ;-- ----------------- ------- ---- m N y 3.0 b ----- -----------------------------
-- g ----- +------- -------- ----- --------
; NN. . -
n 2.0 - ------ ------------- -- --
------------------------------------------ F------ lL 1.0 - ------- ---------------------------------------------------------------------------------
0.0 ' ' JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MONTH FIGURE 12: SURFACE WATER GROSS BETA ACTIVITY COMPARISON
I l
; 1 i.
]
f Well Water I Every two' weeks ' samples are collected .from' the well j j serving the village of DeWitt (both treated and untreated , l samples are obtained) and from a well serving the Illinois !
- -Department of- Conservation at the Mascoutin State ;
] Recreational Area. Each sample is analyzed for I-131. ; All samples - drawn from the same well .during a particular - , i month are combined and analyzed . for gross alpha, gross ! . beta and gamma isotopic activities. In addition, a , j portion of each monthly -composite is added to the : quarterly-composite sample and is analyzed for tritium. ! The 1994 results of the gross beta analyses ranged from- ; j 1.0 to 3.0 pCi/1. Preoperational gross beta activity } ranged from 1.1~to'5.1 pCi/1. The gross beta activity was !
; attributed to naturally occurring K-40 suspended as fine : ! sediment particles in water. Monthly well water gross l l beta activity is presented graphically in Figure 13. j t
1 Gross alpha activities in well water samples ranged from j 0.8 to 1.2 pCi/1. Preoperational gross alpha activity ' i ranged from 0.9 to 1.8 pCi/1. Gross alpha activity can be j attributed to naturally occurring radioisotopes, such as, j U-238 and Ra-226, suspended as fine sediment particles in r
- water.
! l
, Gamma-emitting radioisotopes were all below the lower j j limits of detection. Tritium and I-131 were not detected !
j in any well water samples taken during 1994. j These results show no measurable change in radioactive ! material concentration in. well water resulting from j operation of the Clinton Power Station during 1994. 4 3 0 i i i i f' L I l _ _ _ _ _ _ . _ _ _ _ . _ _ . _ _ _ _ _ _ . . . - .- - . _ - . - - I
i l l TABLE 8 4 AVERAGE GROSS BET 4 CONCENTRATIONS l IN. DRINKING, SURFACE AND WELL MATER l 1994 1993 Average *2a Average *20 l Station ' Description (DCi/1) foci /1) IMnfina Watg CL-14 CPS (Service Building) 2.0 0.5 2.0 1.2 Surface Water CL-9 DeWitt Road Bridge 2.9 1.9 2.4 1.7 CL-10 (c) Ill. 48 Bridge 2.7
- 1.5 2.6 2.3 -
CL-13 Salt Creek (below dam) 2.8 0.9 2.7 2.1 CL-90 CPS Discharge Flume 2.6 0.7 2.5
- 1.3 CL-91 Parnell Boat Access 2.1 e 1.0 1.9 2 0.7 CL-92 CPS Intake Screenhouse 2.7 1.3 2.4 1.3 CL-93 CPS Settling Ponds ,
3.1 2 3.0 2.5 z 2.3 t l CL-99* North Fork Canoe 3.1 4.2 N/A Access i We([ Water CL-7D Mascoutin State 1.4 2 0.6 1.3 0.6 Recreation Area CL-12 DeWitt Pump Station 2.2 2 1.0 2.0 2 1.3 Treated CL-12 DeWitt Pump Station 1.9 m 1.3 2.5 2 1.1 l Untreated l' I
- Added to the program in 1994 (c) Control location; all others are indicators i
70
_ C _ E D _ y y t V . t i v O _ i N - v i t i t c c A A p _ 4 o _ 9 9 e r T 1 P C O 0 : N O P E S I S R A P M G O U C _ A A T - E B _ L U S . S J _ H O _ T R _ N G . O NM R U E J T _ N A _ W _ Y L _ A L _ M E _ W _ 3 1 R P A E R U G I F R A M B
- E F
N
- A J
0 0 - 0 0 0 0 0 o 0 0 0 8 7 6 5 4 3 ,' 1 0 1 hoONhSty4 j
i I i 1 i G. Quality Assurance Procram I. To establish confidence that data developed and reported i are accurate and precise, all REMP activities are incorporated- into the Illinois Power. Company Quality 3 Assurance (QA) program of audits and surveillances. The
- Quality Assurance program requires
i l Participation in intercomparison programs, such as
- the EPA cross-check program.
An annual audit of the analysis laboratory functions , 3 and facilities. t l l i Periodic review of the Clinton Power Stat. ion . i procedures specifying sampling techniques. I 1 l i Duplicate analysis of every tenth sample assayed (not I This requirement is to check-including TLDs). [ laboratory precision. I. The routine counting of quality control samples. l Approximately ten percent of the total number of l counts performed are to be quality control counts. c . ! The analytical results provided by' the laboratory were i routinely reviewed by the Radiological Environmental. Group l of the Radiation Protection Department to ensure .the ! required minimum sensitivities have been achieved and the i' proper analyses have been performed. ! Teledyne Brown Engineering Environmental . Services Midwest i Laboratory (TBEESML) participates in the Environmental Protection Agency cross-check program. 'The_ TBEESML participant code in the cross-check program is CA. l Participation in this program provides assurance that the laboratory is capable of meeting widely-accepted criteria for radioactivity analysis. i j Results of the 1994 cross-check program are shown in- )
- j. Appendix D.
i i j H. Chanaes to the REMP Durina 1994 Occasionally changes to the Radiological Environmental
- Monitoring Program are necessary to improve the monitoring of the environmental exposure pathways. These changes may result from items identified during the performance of the Annual Land Use Census, revised or new regulatory
- requirements, Quality Assurance audits or supplemental r periodic and long-term sampling and analyses.
? . l 4 j- 73-i- J
i During ~ 1994, an additional water sample location (CL-99) was added to the program to provide additional information i for assessing the radiation dose to man from surface ,' water. Also, 2 additional types of broadleaf vegetation (spinach and kale greens) were grown to supplement the current types of vegetation grown (cabbage, lettuce, Swiss f chard). r t i 6 9 6 4 4 4 74
I 5)Tf m d S S * * [ , .;
-- e, :e J
. $,' ' h.@
B* M,~ . .T sp +- . . . e' ANNUAL LAND USE CENSUS
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IV. ANNUAL LAND USE CENSUS A land use census is performed to ensure that changes in the use of areas at and beyond the site boundary are identified and that any necessary modifications to the REMP are made. The land use census is performed to identify within a distance of 5 miles (8 km), the locations in each of the 16 meteorological sectors of the nearest milk animals, the nearest residence and the nearest garden of greater than 500 square feet producing broadleaf vegetation. Also, the census shall identify within a distance of 3 miles (5 km), the
; location in pach of the 16 meteorological sectors of all milk animals and all gardens of greater than 500 square feet producing broadleaf vegetation.
4 TABLE 9
; 1994 AmtUAL LkND USE CENSUS Nearest Nearest Nearest Sector Residence (km) Garden (km) Milk Animal (km) i N 1.68 1.68 1.68 NNE 1.71 3.76 2.14 :
NE 3.07 5.56 5.63 ENE 2.78 2.78 7.54 i E 1.58 3.95 a ] . ESE 5.14 5.14 a SE 4.73 4.73 a i SSE 2.74 4.19 3.72 ! S 4.78 4.78 6.49 I i SSW 4.68 4.68 5.36 l SW 1.13 6.73 5.87 l WSW 2.47 4.32 5.53 .i W 2.63 2.63 3.35 , WNW 2.66 0.80 a 3.11 a i NW 2.79 NNW 2.50 3.76 1.74 a mene identified within 8 kilcunsters of CPS in this meteorological sector. l
, The 1994 Land Use census was conducted during the growing season satisfying the CPS Offsite Dose Calculation Manual requirements. Over 160 residences were surveyed by either direct contact, mailed in questionnairo, telephone, or direct observation. Data for this report was obtained using the following means:
4 75
V i 4 i j l e Performed door-to-door solicitation of residencee/ land ,
; owners identified in the 1993 Annual Land . Use Census, . , 1994 DeWitt County plat book. If a. resident- was ;
f unavailable for.. questioning, a questionnaire was placed - ' j on their door to have them fill out and mail back. i j e Performed ' telephone solicitation'.of persons who were '
- unavailable during the door-to-door- survey and didn't- '
4 mail back their questionnaire. l
- By direct observation of land when the aforementioned-4 methods were unsuccessful. .If an. individual ~was unable l
to be contacted, data from the previous, year was used. )i
- Contacting several' state and-local agencies.
! The 1994 Land Use census results were examined to ensure that I l the REMP will provide representative measurements. of '
{ radiation and radioactive materials in those _ exposure ! t pathways and for those radionuclides that lead to the highest ! C potential radiation exposures to the general public resulting i
; fros'Clinton Power Station operations. #
On the basis of the examination of the '1994 Annual Land Use census results, no changes to the REMP were mada.
- l
+
l
. ~ ,
l 1 I i 76 !
1 4 I l Bususary of Changes Identified in j 1994 Annual Land Use Census , Nearest Residence i Five changes were identified for the nearest residence.
- These changes are shown below
} l 1 1993 Census Location 1994 Census Location : .i 1.68 km N 1.68 km N* l I 4.02 km ENE 2.78 km ENE ' I b.15 km ESE 5.14 km ESE l 3 2.41 km WNW 2.66 km WNW
- 4.02 km NNW 2.50 km NNW i
- change in ownership i
i Nearest Garden 1
- A total of 150 gardens were identified in the 16 sectors within a 5-mile (8 km) radius of Clinton Power Station of i lettuce and j which cabbage) 50 produced and werebroad leaf vegetationm2.
greater than 50 (e.g.In, most cases, j tomatoes, sweet corn and beans were grown in gardens identified. Changes in census locations for the nearest garden were ! identified in 8 of the 16 sectors and are shown belows i { 1993 Census Location 1994 Census Location j 1.45 km NNE 3.76 km NNE j 4.02 km ENE 2.78 km ENE 3.86 km E 3.95 km E i 5.15 km ESE 5.14 km ESE l 4.99 km SE 4.73 km SE f 6.12 km S 4.78 km S ! 3.38 km WSW 4.32 km WSW ! 3.70 km W 2.63 km W j 4.02 km NNW 3.76 km NNW i l 1 ~ Nearest Livestock / Dairy Milking animals within 5 miles (8 km) were located in the 16 2 sectors surrounding CPS. The cattle were used for nursing of
- - calves and meat production (both own use and meat j production). There was only one resident that milked cows i for human consumption. Goats were found at two residences, j however, only one of the residences used the milk for human consumption.
4 i' 77 i
4 Changes in the census locations for the nearest livestock / dairy were identified in 7 of the 16 sectors and are shown belows 1993 Census Location 1994 census Location
-1.45 km N. 1.68 km N '
3.22 km NNE 2.14 km NNE i 7.40 km ENE 7.54 km ENE I 4.51 km SSE 3.72 km SSE 4 4.83 km S 6.49 km S 5.15 km SW- 5.87 km SW l . 6.28 km NNW 1.74 km NNW 4 3 1 h i o 1 I i 1
?
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i METEOROLOGICAL ! MONITORING - i ) e j i 4 i 'l -- ,
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.s METEOROLOGICAL MONITORING <
i
5 , I i l Y. i METEOROLOGICAL CHARACTERISTICS i A. Description '!
- The climate of central Illinois is typical of the 1 Midwest, with cold winters, warm summers and frequent
, short-period fluctuations in temperature, humidity, 1 cloudiness and wind direction. The variability in central Illinois climate is due to its location in a 4
- confluence zone (particularly during the cooler months) ]
l between different air masses. The specific air masses ! which affect central Illinois include maritime tropical air which originates in the Gulf of Mexico; continental ! tropical air which originates in Mexico and the southern i Rockies; Pacific air which - originates in the eastern l 2 Nor*.h Pacific Ocean; and continental polar and l ! continental Arctic air which originates in Canada.
- Monthly streamline analyses of resultant surface winds
- suggest. that air reaching central. Illinois most
? frequently originates over the Gulf of Mexico from April through August, over the southeastern United States from September through November, and over both the Pacific Ocean and the Gulf of Mexico from December through March.
- The major factors controlling the frequency and
- variation of weather types are determined by the j movement of storm systems which conunonly follow paths
! along a major confluence zone between air masses. The confluence zone is usually oriented from southwest to northeast through the region and normally shifts in latitude during this period, ranging in position from I the central states to the United States - Canadian j border. The average frequency of passage of storm i systems along this zone is about once every 5 to 8 days. l These storm systems are most frequent during the winter and spring months, causing a maximum of cloudiness l during these seasons. l Winter is characterized by alternating periods of steady l' precipitation and periods of clear, crisp and cold ! weather. Springtime precipitation is primarily showery in nature. The frequent passage of storm systems,
- presence of high winds, and frequent occurrence of unstable conditions caused by the close proximity
- between warm, moist air masses and cold, dry air masses,
- j. result in this season's thunderstorms and on occasion,
! are the source of hail, damaging winds and tornadoes. } i L 79 1 l
h 1 i i Although storm systems also' occur during the fall
- months, the frequency of occurrence during these months l 4- is less than that of the winter or' spring months.
! Periods of dry weather characterize the fall season j . which ends rather abruptly with increasing storminess j' that usually begins in November.' r i >
- In contrast,. weather during the summer, months is j i characterized by weaker storm systems which tend to pass ;
to the north of Illinois. A major confluence zone- is j ! not present-in this region, and the region's weather is i characterized by much- sunshine interspersed with ! thunderstorms. Showers and thunderstorms are usually of. j the air mass type, although occasional outbreaks of. cold air bring precipitation and weather typical of that associated with the fronts and storm systems of the spring months.- ! When southeasterly and easterly winds are present in j central Illinois, they usually bring mild and wet j weather. Southerly winds are warm and showery,~ westerly 5 winds are dry with moderate temperatures, and-winds from i [ the northwest and north are cool and dry. j The prevailing wind is southerly at' the Clinton Power
, Station. The frequency of winds. from other directions is relatively well distributed. The monthly average j
wind speed is lowest during late summer and highest i during late winter and early spring. I ! The meteorological monitoring program began at Clinton
- Power Station on April 13, 1972. The _ meteorological i system consists of a tower 199-feet high with two levels
! of instrumentation, at the 10-meter and 60-meter levels. 1 Wind direction and speed at the two levels are measured ! by a combined cup and vane sensor. The temperatures at i these levels are sensed by an aspirated dual temperature
- sensor. One-half of the dual sensor at each elevation '
{ is used for ambient temperature while the other half is i used to provide a difforential temperature of the two ! levels. Dow-point is measured at the 10-meter level
- using an aspirated dow-point sensor. Precipitation is l j measured at ground level by a tipping bucket rai'n gage.- '
Meteorological monitoring instruments have been placed on the Clinton Power Station microwave tower at the 10-j meter level to act as a backup to the existing tower. l 1 1 Clinton Power Station meteorological data'is transmitted
- to the Main Control Room via a dedicated telephone line.
There the signals are received and converted to a _4 to l 20 milliamp signal and fed individually to a 1 microprocessor and chart recorders. The microprocessor . is part of the Clinton Power Station Radiation ' Y l 4- I H b . . . -- . --- - . _ .
Monitoring System. Meteorological data is available via the microprocessors in the Main Control Room, Technical Support Center and the Radiation Protection office. ) l The on-site meteorological tower obtains information ) that is valuable in determining plume dispersion by ; providing differential temperature, wind speed and i direction. Table 10 summarizes the seven stability classes, with unstable conditions dispersing a plume more than stable conditions. Table 11 compiles the total hours for different wind speeds for each stability class during 1994, at 10 meters and 60 meters. TABLE 10 CLASSIFICATION OF ATMOSPHERIC STABILITY Stability Pasquill Defining Classification Cateaories Conditions Extremely unstable A -0.900 < AT s-0.019 Moderately unstable B -0.019 < AT S-0.017 Slightly unstable C -0.017 < AT s-0.015 Neutral D -0.015 < AT s-0.005 Slightly stable E -0.005 < AT s 0.015 Moderately stable F 0.015 < AT s 0.040 Extremely stable G 0.040 < AT 5 0.900 l Invalid AT 5 -0.900 or AT > 0.900 AT = temperature difference in Celsius degrees per meter l 1 I 81
i t i i
- l 1
TABLE 11 JOINT WIND FREQUENCY DISTRIBUTION BY STABILITY CLASS { For the Period January 1,1994. December 31,1994 STABILITYCLASS A 60 METER (All tabled values are hours)
- SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL
] N 5.00E+00 1.60E+01 1.90E+01 1.80E+01 7.00E+00 0.00E+00 6.50E+01
- NNE 9.00E+00 2.90E+01 3.50E+01 1.50E+01 6.00E+00 0.00E+00 9.50E+01 i E 1.00E+01 1.80E+01 3.40E+01 2.90E+01 5.00E+00 0 00E+00 9.60E+01 EE 7.00E+00 1.50E+01 1.60E+01 2.40E+01 2.00E+00 0.00E+00 6.60E+01 I
E 1.10E+01 2.30E+01 6.00E+00 120E+01 3.00E+00 0.00E+00 5.50E+01 ESE 2.10E+01 270E+01 7.00E+00 0.00E+00 0.00E+00 0.00E+00 5.50E+01 SE 1.70E+01 3.80E+01 1.40E+01 3.00E+00 3.00E+00 0.00E+00 8.00E+01 SSE 1.10E+01 4.70E+01 1.60E+01 1.50E+01 9.00E+00 0.00E+00 1.06E+02 S 1.50E+01 3.20E+01 5.00E+01 4.20E+01 1.30E+01 0.00E+00 1.59E+02 SSW 9.00E+00 2.40E+01 5.50E+01 4.00E+01 1.40E+01 0.00E+00 1.61E+02 SW 7.00E+00 2.80E+01 4.80E+01 3.00E+01 1.00E+01 0.00E+00 1.35E+02 2 WSW 6.00E+00 2.90E+01 4.50E+01 4.10E+01 6.00E+00 7.00E+00 1.27E+02 W 5.00E+00 1.80E+01 5.30E+01 4.10E+01 9.00E+00 3.00E+ 00 1.31E+02 WNW 1.10E+01 2.90E+01 3.70E+01 3.90E+01 2.40E+01 3.00E+00 1.45E+02 NN 1.40E+01 3.40E+01 4.00E+01 3.60E+01 2.00E+00 2.00E+00 1.30E+02 NNW 8.00E+00 3.70E+01 5.20E+01 8.00E+00 4.00E+00 0.00E+00 1.10E+02 Total 1.66E+02 4.44E+02 5.27E+02 3.93E+02 1.17E+02 1.50E+01 1.72E+03 Penods of Calm: 4.00E+00 invalid Data : 3.00E+00 10 METER (Alltabled values are hours) SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL N 4.00E+00 2.80E*01 3.10E+01 1.90E+01 0.00E+00 0.00E+00 8.20E+01 NNE 7.00E+00 1.80E+01 1.60E+01 1.40E+01 1.00E+00 0.00E+00 5.60E+01 i E 1.10E+01 3.80E+01 4.10E+01 8.00E+00 0.00E+00 0.00E+00 9.80E+01 l EE 1.30E+01 3.00E+01 3.50E+01 1.00E+00 1.00E+00 0.00E+00 8.00E+01 1 E 1.20E+01 2.40E+01 1.90E+01 1.00E+00 0.00E+00 0.00E+00 5.60E+01 ! ESE 8.00E+00 3.40E+01 2.00E+00 0.00E+00 0.00E+00 0.00E+00 4.40E+01 1 SE 1.60E+01 4.705+01 1.80E+01 6.00E+ 00 0.00E+00 0.00E+00 8.70E+01 SSE 1.10E+01 3.40E+01 1.90E+01 1.10E+01 1.00E+00 0.00E+00 7.60E+01 S 1.70E+01 6.00E+01 5.00E+01 1.80E+01 1.00E+00 0.00E+00 1.46E+02 SSW 1.40E+01 3.60E+01 6.70E+01 3.70E+01 1.40E+01 0.00E+00 1.68E+02 SW 7.00E+00 4.20E+01 7.20E+01 2.20E+01 8.00E+00 0.00E+00 1.51E+02 WSW 1.00E+01 3.10E+01 4.10E+01 2.90E+01 2.00E+00 7.00E+00 1.20E+02 W 6.00E+00 2.30E+01 7.10E+01 4.30E+01 7.00E+00 3.00E+00 1.53E+02 WNW 1.00E+01 3.00E+01 6.20E+01 5.50E+01 5.00E+00 3.00E+00 1.65E+02 NN 1.70E+01 4.00E+01 4.30E+01 2.70E+01 2.00E+00 2.00E+00 1.31E+02 NNW 5.00E+00 4.10E+01 5.00E+01 4.00E+00 0.00E+00 0.00E+00 1.00E+02 Total 1.68E+02 5.56E+02 6.37E+02 2.95E+02 4.20E+02 1.50E+vi N.71E+03 Portods of Calm; 4.00E+00 invulid Data : 000E+00 82 l
1 TABLE 11 (cont'd)
- JOINT WIND FREQUENCY DISTRIBUTION BY STABILITY CLASS Data Period
- January 1,1994 - December 31,1994 STABILITY CLASS B J 60 METER (All tabled values are hours)
SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL l N 1.00E+00 4 00E+00 1.50E+01 9000 00 3.00E+00 0.00E+00 3 20E+01 l NNE 1.00E+00 5.00E+00 9.00E+00 8.00E+00 1.00E+00 2.00E+00 2.60E+01 l E 5.00E+00 7.00E+00 5.00E+00 8.00E+00 1.00E+00 1.00E+00 2.70E+01 ENE 1.00E+00 8.00E+00 4.00E+00 6.00E+00 3.00E+00 2.00E400 2.40E+01 E 1.10E+01 5.00E+00 4.00E+00 1.00E+00 1.00E+00 1.00E+00 2.30E+01 ESE 1.00E+01 1.00E+01 6.00E+00 0.00E+00 0.00E+00 0.00E+00 2.60E+01 SE 8.00E+00 4.00E+00 7.00E+00 3.00E+00 1.00E+01 0.00E+00 3.20E+01 SSE 8.00E+00 4.00E+00 3.00E+00 8.00E+00 5.00E+00 2.00E+00 3.00E+ 01 9.00E+00 3.00E+00 5.30E+01 S 7.00E+00 5.00E+00 1.20E+ 01 1.70E+01 SSW 4.00E+00 7.00E+ 00 1.90E+01 1.00E+01 3.00E+00 1.00E+00 4.40E+01 SW 4.00E+00 5.00E+00 1.00E+01 7.00E+00 2.00E+00 2.00E+00 3.00E+01 WSW 2.00E+00 4.00E+00 7.00E+00 1.30E+01 5.00E+00 3.00E+00 3.40E+01 W 2.00E+00 3.00E+00 6.00E+00 9.00E+00 2.00E+00 0.00E+00 2.20E+01 WNW 1.00E+00 2.00E+00 8.00E+00 7.00E+ 00 4.00E+00 2.00E+00 2.40E+01 NW 5.00E+00 9.00E+00 1.40E+01 1.00E+ 01 5.00E+00 1.00E+00 4 40E+01 NuW 1.00E+00 6.00E+00 8.00E+00 5.00E+00 0.00E+00 0.00E+00 2.00E+01 8.80E+01 1.37E+02 1.21E+02 5.40E+01 2.00E+01 4.91E+02 Total l7.'0E+01 Periods of Cairr : 2.00E+00 invalid Data : 0.00E+00 10 METER (All tabled values are hours) SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL N 0.00E+00 7.00E+00 1.30E+01 9.00E+00 0.00E+00 0.00E+00 2.90E+ 01 NNE 1.00E+00 7.00E+00 1.10E+01 5.00E+00 1.00E+00 0.00E+00 2.50E+01 E 2.00E+00 1.40E+01 9.00E+00 2.00E+00 0.00E+00 0.00E+00 2.70E+01 ENE 4.00E+00 1.00E+01 9.00E+00 3.00E+00 1.00E+00 0.00E+00 2.70E+01 E 9.00E+00 8.00E+00 2.00E+00 2.00E+00 0.00E+00 0.00E+00 2.00E+01 ESE 1.W+01 6.00E+00 3.00E+00 0.00E+00 0.00E+00 0.00E+00 2.20E+01 SE 9.00E+00 ;00E+01 7.00E+00 7.00E+00 0.00E+00 0.00E+00 3.30E+01 l SSE 9.00E+00 7.00E+00 1.60E+01 5.00E+00 0.00E+00 0.00E+00 3.70E+01 S 9.00E+00 4.00E+00 1.20E+01 5.00E+00 0.00E+00 0.00E+00 3.00E+ 01 SSW 6.00E+00 1.10E+01 2.30E+01 1.40E+01 2.00E+00 0.00E+00 5.60E+01 SW 3.00E+00 1.70E+01 1.50E+01 3.00E+00 1.00E+00 0.00E+00 3.90E+01 WSW 3.00E+00 5.00E+00 1.40E+01 9.00E+00 1.00E+00 0.00E+00 3.20E+01 W 1.00E+00 4.00E+00 1.30E+01 4.00E+00 4.00E+00 0.00E+00 2.60E+01 WNW 0.00E+00 6 00E+00 1.70E+01 6.00E+00 3.00E+00 0.00E+00 3.20E+01 NW 4.00E+00 1.20E+01 1.30E+01 7.00E+00 1.00E+00 0.00E+ 00 3.70E+01 NNW 3.00E+00 3.00E+00 1.20E+01 1.00E+00 0.00E+00 0.00E+00 1.90E+01 Total 7.50E+01 1.31E+02 1.89E+02 8.20E+01 1.40E+01 0.00E+00 4.91E+02 I Penods of Calm: 2.00E+00 ' invalid Data 0.00E+00 83
TABLE I1 (cont'd) JOLNT WIND FREQUENCY DISTRIBUTION BY STABILITY CLASS Data Period: January 1,1994 - December 31,1994 STABILITY CLASS C l 60 METER (All tabled values are hours) SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTA 8 N 4.00E+00 8.00E+00 1.80E+01 6.00E"00 4.00E+00 0.00E+00 4.00E+01 NNE 3.00E+00 1.00E+01 1.30E+01 3.00E400 200E+00 1.00E+ 00 3.20E+01 E 1.00E+00 3.00E+00 7.00E+00 7.00E+00 1.30E+01 3.00E+00 3.40E+01 EE 5.00E+00 1.00E+00 6.00E+00 5.00E+00 1.30E+01 1.20E+01 4.20E+01 E 2.00E+00 6.00E+00 4.00E+00 1.00E+00 0.00E+00 0.00E+00 1.30E+ 01 ESE 6.00E+00 5.00E+00 5.00E+00 1.00E+00 0.00E+00 0.00E+00 1.70E+01 ! SE 3.00E+00 3.00E+00 3.00E+00 5.00E+00 5.00E+00 1.00E+00 2.00E+01 I SSE 1.00E+01 6.00E+00 2.00E+00 1.20E+01 5.00E+00 3.00E+00 3.80E+01 S 5.00E+00 1.00E+00 1.70E+01 1.20E+01 1.00E+01 8.00E+00 5.30E+01 SSW 2.00E+00 3.00E+00 1.50E+01 1.00E+01 6.00E+00 3.00E+00 3.90E+01 SW 3.00E+00 1.00E+01 1.20E+01 4.00E+00 3.00E+00 6.00E+00 3.80E+01 i WSW 3.00E+00 5.00E+00 8.00E+00 6.00E+00 3.00E+00 1.00E+00 2.60E+01 l W 2.00E+00 4.00E+00 1.40E+01 6.00E+00 3.00E+00 5.00E+00 3.40E+01 ' I WNW 1.00E+00 4.00E+00 1.60E+01 5.00E+00 2.00E+00 0.00E+00 2.80E+01 NW 5.00E+00 7.00E+00 1.20E+01 1.00E+01 4.00E+00 0.00E+00 3.80E+01 NNW 0.00E+00 9.00E+00 1.00E+01 1.80E+01 0.00E+00 0.00E+00 3.70E+01 Total 5.50E+01 8.50E+01 1.62E+02 1.11E+02 7.30E+01 4.30E+01 5.29E+02 Penods of Calm : 4.00E+00 invalid Data : 0.00E+00 10 METER (All tabled values are hours) SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL N 1.00E+00 1.20E+01 1.50E+01 1.00E+01 0.00E+00 0.00E+00 3.80E+01 NNE 5.00E+00 1.80E+01 8.00E+00 4.00E+00 0.00E+00 0.00E+00 3.50E+01 E 2.00E+00 1.00E+01 1.00E+01 3.00E+00 0.00E+00 0.00E+00 2.50E+01 1 EE 3.00E+00 1.20E+01 1.30E+01 2.20E+01 2.00E+00 0.00E+00 5.20E+01 E 3.00E+00 5.00E+00 2.00E+00 3.00E+00 0.00E+00 0.00E+00 1.30E+01 ESE 5.00E+00 9.00E+00 2.00E+00 0.00E+00 0.00E+00 0.00E+00 1.60E+01 j SE 8.00E+00 6.00E+00 1.00E+C 1 8.00E+00 0.00E+00 0.00E+00 3.20E+01 SSE 5.00E+00 5.00E+00 5.00E+(0 6.00E+00 1.00E+00 0.00E+00 2.20E+01 S 7.00E+00 7.00E+00 1.70E+C1 1.20E+01 1.00E+00 0.00E+00 4.40E+01 SSW 5.00E+00 1.70E+01 1.70E+01 9.00E+00 1.00E+00 0.00E+00 4.90E+01 SW 2.00E+00 9.00E+00 1.50E+01 3.00E+00 2.00E+00 0.00E+00 3.10E+01 WSW 3.00E+00 1.20E+01 6.00E+00 5.00E+00 4.00E+00 1.00E+00 3.10E+01 W 3.00E+00 4.00E+00 1.50E+01 5.00E+00 5.00E+00 0.00E+00 3.20E+01 i WNW 1.00E+00 8.00E+00 2.20E+01 8.00E+00 1.00E+00 0.00E+00 4.00E+01 PM/ 1.00E+00 1.20E+01 1.70E+01 3.00E+00 0.00E+00 0.00E+00 3.30E+01 NNW 1.00E+00 7.00E+00 1.70E+01 4.00E+00 0 00E+00 0.00E+00 2.90E+01 Total 5.50E+01 1.53E+02 1.91E+02 1.05E+02 1.70E+01 1.00E+00 5.22E+02 l Penos of Cairm 3 00E+00 l Invalid Data : 8.00E+00 l 1 84 l
4 l TABLE 11 (cont'd) l JOINT WIND FREQUENCY DISTRIBUTION BY STABILITY CLASS , Data Per%I: January 1,1994 December 31,1994
- STABILITY CLASS D
, 60 METER (All tabled values are hours) ) SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL i N 8.00E+ 00 2.10E+01 5.10E+01 4.10E+01 7.00E+00 3.00E+00 1.31E+02 1 NNE 8.00E+00 1.40E+01 4.00E+01 5.40E+01 2.40E+01 2.00E+00 1.dr+02 E 8.00E+00 1.90E+01 6.80E+01 7.50E+01 2.40E+01 5.00E+00 1.99E+02 ENE 6.00E+00 1.50E+01 5.00E+01 5.80E+01 3.20E+01 1.20E+01 1.73E+02 ! E 1.80E+01 2.80E+01 6.50E+01 3.50E+01 1.30E+01 6 00E+00 1.65E+02 ) ESE 2.40E+01 4.90E+01 ~4.60E+01 7.00E+00 3.00E+00 1.00E+00 1.30E+02 SE 8.00E+00 2.30E+01 5.00E+01 2.90E+01 1.90E+01 5.00E+00 1.34E+02 ! SSE 7.00E+00 2.10E+01 5.40E+01 8.40E+01 2.80E+01 1.10E+01 2.05E+02 l S 1.10E+01 2.40E+01 6.00E+01 1.36E+02 6.70E+01 3.00E+01 3.28E+02 2 SSW 2.00E+00 2.00E+01 9.00E+01 8.10E+01 1.60E+01 9.00E+00 2.18E+02 i SW 5.00E+00 2.10E+01 3.40E+01 3.10E+01 1.40E+01 1.40E+01 1.19E+02 l WSW 3.00E+00 1.30E+01 3 40E+01 4.30E+01 2.00E+01 J00E+00 1.16E+02 j W 2.00E+00 1.10E+01 4.90E+01 4.00E+01 3.00E+01 1.00E+01 1.42E+02 j WNW 5.00E+00 2.30E+01 4.10E+01 4.90E+01 3.00E+01 3.00E+00 1.51E+02
- M 4.00E+00 3.60E+01 6.20E+01 3.10E+01 2.30E+01 5.00E+00 1.61E+02 i NNW 5.00E+00 2.70E+01 7.70E+01 4.20E+01 7.00E+00 6.00E+00 1.64E+02 f Total 1.24E+02 3.65E+02 8.77E+02 8.36E+02 3.57E+02 1.25E+02 2.68E+03 j Penods of Calm
- 1.00E+00 i invahd Data : 1.00E+00 3
10 METER (All tabled values are hours) SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 19-24 mph >24 mph TOTAL ] N 8 00E+00 3 60E+01 6.30E+01 1.70E+01 0.00E+00 2.00E+00 1.26E+ 02 i NNE 1.60E+01 4.80E+01 5.30E+01 1.60E+01 1.00E+00 0.00E+00 1.34E+02 ! E 1.80E+01 7.80E+01 5.70E+01 2.40E+01 1.00E+00 - 0.00E+00 1.78E+02 1 ( EE 2.60E+01 7.80E+01 8.10E+01 1.80E+01 2.00E+00 0.00E+00 2.05E+02 i E 2.70E+01 7.70E+01 3.40E+01 9.00E+00 0.00E+00 0.00E+00 1.47E+02 ! ESE 3.30E+01 6.80E+01 3.00E+01 2.00E+00 0.00E+00 0.00E+00 - 1.33E+02 l i SE 1.80E+01 6.20E+01 6.10E+01 1.70E+01 1.00E+00 0.00E+00 1.59E+02 i SSE 1.70E+01 7.40E+01 4.60E+01 7.00E+00 1.00E+00 0.00E+00 1.45E+02 l S 2.00E+01 5.60E+01 1.25E+02 4.00E+01 6.00E+00 2.00E+00 2.49E+02 l SSW 1.10E+01 8.30E+01 1.48E+02 5.10E+01 5.00E+00 0.00E+00 2.98E+02 j SW 1.50E+01 5.40E+01 6.00E+01 1.30E+01 3.00E+00 0.00E+00 1.45E+02 i WSW 5.00E+00 2.50E+01 4.40E+01 2.00E+01 9.00E+00 3.00E+00 1.06E+02 i W 6.00E+00 3.40E+01 7.40E+01 4.70E+01 1.00E+01 0.00E+00 1.71E+02 i WNW 8.00E+00 3.80E+01 5.70E+01 6.50E+01 8.00E+00 1.00E+00 1.77E+02
] M 1.00E+01 7<30E401 3.40E+0i 2.30E+01 3.00E+00 0.00E+00 1.43E+02
{ NNW 1.00E+01 5.60E+01 6.70E+01 1.30E+01 3.00E+00 2.00E+00 1.51E+02 Total 2.48E+02 9.40E+02 1.03E+03 3.82E+02 5.30E+01 1.00E+01 2.67E+03 ) ( l 3 Penods cf Calm: 3.00E+00 ' j invahd Data 1.60E+01
; 85 ,
I J l j TABLE 11 (cont'd) JOINT WIND FREQUENCY DISTRIBUTION BY STABILITY CLASS
- Data Period
- January 1,1994 December 31,1994
; STABILITY CLASS E 60 METER (Alltabled values are hours) l SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL
- N 1.00E+00 6.00E+00 4.50E+01 2.10E+01 0.00E+00 0.00E+00 7.30E+01
} NNE 4.00E+00 5.00E+00 4.20E+01 2.50E+01 3.00E+00 0.00E+00 7.90E+01 l E 2.00E+00 6.00E+00 2.90E+01 2.70E+01 2.00E+00 0.00E+00 6.60E+01 ENE 4.00E+00 9.00E+00 3.00E+01 1.70E+01 2.00E+00 0.00E+00 6.20E+01 i E 7.00E+00 2.70E+01 3.20E+01 2.70E+01 3.00E+00 0.00E+00 9.60E+01 1 ESE 1.80E+01 4.80E+01 1.90E+01 2.00E+00 0.00E+00 0.00E+00 8.70E+01 i S1 S 6.00E+00
!"0e:ll 1.70E+01
!"::: 15:l' 6.60E+01 1.20E+ 02 l0:
0 2.30E+01 l :" !"':; 1.20E+01 2.44E+02 j SSW 0.00E+00 1.70E+01 3.30E+01 7.90E+ 01 2.40E+01 0.00E+00 1.53E+02 SW 3.00E+00 1.40E+01 2.20E+01 3.20E+01 1.20E+01 2.00E+00 8.50E+01 WSW 2.00E+00 1.10E+01 3.10E+01 3.70E+01 1.10E+01 0.00E+00 9.20E+01 j W 1.00E+00 1.60E+01 2.70E+01 2.70E+01 7.00E+00 1.00E+00 7.90E+01 WNW 3.00E+00 1.60E+01 3.40E+01 2.30E+01 4.00E+00 0.00E+00 8.00E+01 NW 3.00E+00 2.70E+01 3.80E+01 7.00E+00 6.00E+00 0.00E+00 8.10E+01 i NNW 4.00E+00 1.80E+01 5.10E+01 1.10E+01 1.00E+00 0.00E+00 8 50E+01 i
- Total 7.10E+01 2.87E+02 5.99E+02 5.11E+02 1.17E+02 2.00E+01 1.61E+03 l Penods of Calm
- 3.00E+00 j invalid Data : 1.00E+00 10 METER (All tabled values are hours)
{ SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL l N 1.50E+01 4.50E+ 01 1.00E+01 0 00E+00 0.00E+00 0.00E+00 7.00E+01 l NNE 1.40E+01 3.20E+01 6.00E+00 0.00E+00 0.00E+00 0.00E+00 5.20E+01 j E 2.40E+01 3.90E+01 1.20E+01 0.00E+00 0.00E+00 0.00E+00 7.50E+01 i ENE 3.20E+01 4.00E+01 4.00E+00 0.00E+00 0.00E+00 0.00E+00 7.60E+01 l E 5.00E+01 4.20E+01 2.00E+00 0.00E+00 0.00E+00 0.00E+00 9.40E+01 ESE 4.60E+01 4.90E+01 2.00E+00 0.00E+00 0.00E+00 0.00E+00 9.70E+01 li SE 3.30E+01 5.50E+01 500E+00 0.00E+00 0 00E+00 0.00E+00 9.30E+01 i SSE 3.40E+01 7.00E+01 2.70E+01 2.00E+00 0.00E+00 0.00E+00 1.33E+02 i S 2.90E+01 9.00E+01 5.10E+01 2.10E+01 4.00E+00 0.00E+ 00 1.95E+02
- SSW 1.20E+01 9.70E+01 8.30E+01 8.00E+00 0.00E+00 ~ 0.00E+00 2.00E+01 j SW 2.10E+01 3.80E+ 01 3.10E+01 3.00E+00 1.00E+00 0.00E+00 9.40E+01 l l WSW 1.60E+01 3.20E+01 3.00E+01 4.00E+00 1.00E+00 0.00E+00 8.30E+01 j W 2.00E+01 3.30E+01 3.00E+01 1.40E+01 0.00E+00 0.00E+00 9.70E+01 l WNW 1.60E+01 5.50E+01 2.80E+01 4.00E+00 0.00E+00 0.00E+00 1.03E+02 j PMI 1.60E+01 6.00E+01 1.20E+01 3.00E+00 0.00E+00 0.00E+00 9.10E+01 j NNW 5.00E+00 3.00E+01 1.10E+01 0.00E+00 0.00E+00 0.00E+00 4.60E+01 1
l Total 3.83E+02 8.07E+02 3.44E+02 5.90E+01 6.00E+00 0.00E+00 1.60E+03 I Penods of Calm: 6.00E+00 I invalid Data - 4.00E+00 . ! l i l . 1
i
)
l TABLE 11 (cont'd) JOINT WIND FREQUENCY DISTRIBUTION BY STABILITY CLASS i Data Period: January 1,1994- December 31,19N j STABILITY CLASS F 1 , 60 METER (Alltabled values are hours) )
- SECTOR 1-3 mph 4 7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL ]
4 N 0.00E+00 3 00E+00 1.40E+01 3 00E+00 0.00E+00 0.00E+00 2.00E+01 } NNE 200E+00 5.00E+00 1.60E+01 7.00E+00 0.00E+00 0.00E+ 00 3.00E+01 l E 200E+00 5.00E+00 2.40E+01 1.70E+01 4.00E+00 0.00E+00 5.20E+01 ENE 0.00E+00 5.00E+00 1.80E+01 9.00E+00 0.00E+00 0.00E+00 3.20E+01 j E 2.00E+00 1.00E+01 1.50E+01 7.00E+00 0.00E+00 0.00E+00 3.40E+01 j ESE 9.00E+00 1.20E+01 1.00E+00 0.00E+00 0.00E+00 0.00E+00 2.20E+01 i SE 3.00E+00 4.00E+00 1.00E+01 2.00E+00 0.00E+00 0.00E+00 1.90E+01 I SSE 2.00E+00 5.00E+00 8.00E+00 9.00E+00 200E+00 200E+00 2.80E+01 j S 2.00E+00 9.00E+00 1.00E+01 2.70E+01 .1.00E+01 0 00E+00 5.80E+01 SSW 1.00E+00 6.00E+00 1.30E+01 1.00E+01 9.00E+ 00 2.00E+00 4.10E+01 2 SW 1.00E+00 4.00E+00 2.90E+01 2.40E+01 2.00E+00 0.00E+00 6.00E+01
- WSW 1.00E+00 6.00E+00 270E+01 1.10E+01 5.00E+00 0.00E+00 5.00E+01 j W 4.00E+00 8.00E+00 2.00E+01 6.00E+00 6.00E+00 0.00E+00 4.40E+01 WNW 0.00E+00 4.00E+00 1.80E+01 6.00E+00 0.00E+00 0.00E+00 2.80E+ 01 j NW 1.00E+00 9.00E+00 2.20E+01 9.00E+00 0.00E+00 0.00E+00 4.10E+01 j NNW 0.00E+00 6.00E+00 1.90E+01 3.00E+00 0.00E+00 0.00E+00 2.80E+01 4
Total 3.00E+01 1.01E+02 2.64E+02 1.50E+02 3.80E+01 4.00E+00 5.87E+02 ( Penods of Calm : 2.00E+00 i invalid Data : 1.00E+00 t l 10 METER (All tabled values are hours) j SECTOR 1-3 4-7 8-12 13-18 19-24 >24 TOTAL j N 8.00E+00 4.00E+00 0 00E+00 0.00E+00 0 00E+00 0.00E+00 1.20E+01
- NNE 1.50E+01 8.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 2.30E+0i i E 3.30E+01 3.00E+01 2.00E+00 0.00E+00 0.00E+00 0.00E+00 6.50E+01 l ENE 1.70E+01 1.10E+01 0.00E+00 0.00E+00 0.00E+00 0.00E+00 2.80E+01 l E 3.00E+01 6.00E+ 00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 3.60E+01 l ESE 1.90E+01 0.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.90E+01 SE 1.20E+01 1.10E+01 4.00E+00 0.00E+00 0.00E+00 0.00E+00 2.70E+01 l
SSE 9.00E+00 1.70E+01 5.00E+00 0.00E+00 0.00E+00 0.00E+00 3.10E+01 [ S 1.20E+01 1.60E+01 1.20E+ 01 0.00E+00 0.00E+00 0.00E+00 4.00E+01 f SSW 1.60E+01 2.50E+01 9.00E+00 0.00E+00 0.00E+00 0.00E+ 00 5.00E+01 SW 1.80E+01 2.60E+01 0.00E+00 0.00E+00 0.00E+00 0.00E+ 00 4.40E+01 WSW 2.90E+01 1.60E+01 8.00E+00 3.00E+00 0.00E+00 0.00E+00 5.60E+01
! W 1.90E+01 2.00E+01 7.00E+00 1.00E+00 0.00E+00 0.00E+00 4.70E+01
! WNW 1.50E+01 3.40E+01 1.00E+00 0.00E+00 0.00E+00 0.00E+00 5.00E+01 FM/ 1.70E+01 270E+01 1.00E+00 0.00E+00 0.00E+00 0.00E+00 4.50E+01 I NNW 4.00E+00 3.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 7.00E+00 Total 2.73E+02 2.54E+02 4.90E+01 4 00E+00 0.00E+00 0.00E+00 5.80E+02 Penods of Calm : 6.00E+00 ! Invalid Data : 4.00E+00 a , 87 2
i i TABLE 11 (cont'd)
- JOINT WIND FR8QUENCY DISTRIBUTION BY STABILITY CLASS
{ Data Period: January 1,1994 December 31,1994 i 1 STABILITY CLASS G l 60 METER (All tabled values are hours) 1-3 mph +7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL N 200E+00 1.00E+00 2 00E+00 0.00E+00 0.00E+00 0.00E+00 5.00E+00 NNE 1.00E+00 1.00E+00 4.00E+00 0.00E+00 0.00E+00 0.00E+00 6.00E+00 E 0.00E+00 1.00E+00 8 00E+00 200E+00 200E+00 0.00E+00 1.30E+01 , ENE 1.00E+00 5.00E+00 7.00E+00 8.00E+00 0.00E+00 0.00E+00 2.10E+01 E 5.00E+00 9.00E+00 1.20E+01 3.00E+00 0.00E+00 0.00E+00 2.90E+ 01 { ESE 7.00E+00 7.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.40E+01 SE 1.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.00E+00
- SSE 2.00E+00 4.00E+00 200E+00 1.00E+00 0.00E+00 0.00E+00 0.00E+00
! S 2.00E+00 5.00E+00 0.00E+00 2.00E+00 0.00E+00 0.00E+00 P 00E+00 ) SSW 1.00E+00 8.00E+00 8.00E+00 2.00E+00 0.00E+00 0.00E+00 1.90E+01 l SW 0.00E+00 3.00E+00 8.00E+00 8.00E+00 0.00E+00 0.00E+00 1.90E+01 ! WSW 1.00E+00 1.00E+00 8.00E+00 5.00E+00 0.00E+00 0.00E+00 1.50E+01 l W 3.00E+00 4.00E+00 7.00E+00 0.00E+00 0.00E+00 0.00E+00 1.40E+01 WNW 1.00E+00 3.00E+00 2.00E+00 1.M+00 0.00E+00 0.00E+00 7.00E+00 i M 100E+00 4.00E+0() 1.00E+00 3.00E+00 3.00E+00 0.00E+00 1.20E+01 NNW 1.00E+00 4.00E+00 4.00E+00 3.00E+00 0.00E+00 0.00E+00 1.20E+01 Total 2.90E+01 6.00E+01 7.30E+01 3.80E+01 5.00E+00 0.00E+00 2.05E+02 f 1 Penods of Calm Hours: 3.00E+00 i Hours ofInvalid Data: 1.70E+01 Hours of Good Deta: 7.84E+03 89.5 % of Total Hours i ! 10 METER (All tabled values are hours) l SECTOR 1-3 mph 4-7 mph 8-12 mph 13-18 mph 19-24 mph >24 mph TOTAL
~
! N 4.00E+00 1.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 5.00E+00 l NNE 8.00E+00 3.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.10E+01 i E 3.50E+01 1.90E+01 1.00E+00 0.00E+ 00 0.00E+00 0.00E+00 5.50E+01 j ENE 1.60E+01 1.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.70E+01 E 200E+00 0.00E+00 0.00E+00 0 00E+00 0.00E+00 0.00E+00 2.00E+00 i ESE 1.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.00E+00
- SE 2.00E+00 2.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 4.00E+00 l
- SSE 2.00E+00 1.00E+00 0.00E+00 0.00E+00 0.00E+ 00 0.00E+00 3.00E+00
$ S 5.00E+00 4.00E+00 0.00E+00 0:30E+00 0.00E+00 0.00E+00 9.00E+00 I SSW 8.00E+00 2.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.00E+01 j SW 1.50E+01 6.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 2.10E+01 WSW 1.00E+01 3.00E+00 0.00E+00 1.00E+00 0.00E+00 0.00E+00 1.40E+01 q W 1.30E+01 3.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.60E+01 WNW 8.00E+00 2.00E+00 1.00E+00 0.00E+00 0.00E+00 0.00E+00 1.10E+01 l M 4.00E+00 9.00E+00 0.00E+00 3.00E+00 0.00E+00 0.00E+00 1.60E+01 } NNW 1.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 1.00E+00 Total 1.34E+02 2.00E+00 4.00E+00 0.00E+00 0.00E+00 1.96E+02 1.96E+02 ] Penods of Calm : 1.10E+02 Hours ofInvahd Data : 1.80E+01 Hours of Good Date : 7.80E+03 09.1 % of Total Hours l N
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1 LIST OF REFERENCES I l l n t a f i i e i s, .__
- i. .. _ .-. _ . .- - . .
l VI. LIST OF REFERENCES AMI75 American National Standards Institute,. Inc.,
" Performance, Testing and Procedural Specifications for Thermoluminescent Dosimetry," ANSI N545-1975.
AS1M75 American Society for Testing and Materials,
" Standard Recommended Practice for Dealing with Outlying Observations," ASTM E178-75.
BR66 "Airmass, Streamlines and the Bored Forest," A. Bryson, Technical Report No. 24, University of Wisconsin; Department of Meteorology: Madison, Wisconsin, 1966. CPR Code of Federal Regulations, Title 10, Part 20 (Nuclear Regulatory Commission). CL93a CPS 1993 Radioactive Effluent Release Report. E187 " Environmental Radioactivity," M. Eisenbud, 1987. EPA 72 " Natural Radon Exposure in the United States," Donald T. Oakley, U.S. Environmental Protection Agency. ORP/SID 72-1, June 1972. FRC60 Federal Radiation Council Report No. 1, " Background Material for the Development of Radiation Protection Standards," May 13, 1960. ICRP77 International Commission on Radiological Protection, Publication 2, " Report of Committee II I on Permissible Dose for Internal Radiation," (1959) with 1962 Supplement issued in ICRP Publication 6; Publication 9, " Recommendations on Radiation Exposure," (1965); ICRP Publication 7 (1965), amplifying specific recommendations of Publication 26 (1977). ICRP84 International Commission on Radiation Protection, Publication No. 39 (1984), " Principles of Limiting Exposure to the Public to- Natural Sources of Radiation." R&84 " Radioactivity in the Environment: Sources, Distribution and Surveillance," Ronald L. Kathren, 1984. I 89
NCRP59 National Council on Radiation Protection and l Measurements, Report No. 22, " Maximum . Permissible l Body Burdens and Maximum Permissible Concentrations-of Radionuclides in Air and Water for Occupational ! Exposure," (Published as National Bureau of l Standards Handbook 69, issued. June 1959, :
- superseding Handbook 52).
j NCRP71 National Council on Radiation Protection and Measurements, Report No. 39, " Basic Radiation Protection Criteria," January 1971. : i NCRP75 National Council on Radiation Protection 'and Measurements, Report No. 44, " Krypton-85 in . the ' l' Atmosphere Accumulation, Biological Significance,. and control Technology," July 1975.
- NCRP87a National Council on Radiation . Protection 'and -
,- Measurements, Report No. 91, "Recossendations . on Limits. for Exposure . to Ionizing Radiation," June ! 1987. NCRP87b National Council on Radiation Protection and Measurements, Report No. 93, " Ionizing Radiation Exposure of the Population of the United States," September 1987. MR90 National Research Council, 1990, . Committee on Biological Effects of . Ionizing Radiation . (BEIR V), Board on Radiation Effects Research on ' Life + Sciences, "The Effects of. Exposure to Low Levels of > Ionizing Radiation". NRC74 United States Nuclear Regulatory Commission, -i ! Regulatory Guide 5.36, " Recommended . Practice for Dealing with outlying Observations," June 1974. MaC75 United States Nuclear Regulatory Constission, Regulatory Guide 4.1, " Programs 'for Monitoring Radioactivity in the Environs -of Nuclear ~ Power T Plants," Revision 1, April 1975. Mac77a- United States Nuclear Regulatory Commission, l Regulatory Guide 4.13, " Performance, Testing and l Procedural Specifications for Thermoluminescence l Dosimetry: Environmental Applications," Revision 1, July 1977. , l 1 90
i l 4 . I BRC77b United States Nuclear Regulatory Commission, Regulatory Guide 1.109, " Calculation of Annual Dose to Man from Routine Releases of Reactor Effluents j for the Purpose of Evaluating Compliance with 10CFR i Part 50, Appendix I," Revision 1, October 1977. i' MRC79a United States Nuclear Regulatory Commission Branch i Technical Position, "An Acceptable Radiological j Environmental Monitoring Program," Revision 1, i- November 1979. ' i l- MRC79b United States Nuclear Regulatory Commission , i l Regulatory Guide 4.15, " Quality Assurance for ; l Radiological Monitoring Programs (Norm Operations) ,
; - Effluent Streams and the Environment," Revision '
1, February 1979. ( ) numaG86 Technical Specification, Clinton Power Station,
- . Unit No. 1, Docket No. 50-461, Office of Nuclear l Reactor Regulation, 1986.
; PERI 88 "The Use of Diatoms (Periphyton) in Monitoring Light Water Reactor Radioactive Liquid Effluence in
- i. the Susquehanna River," Ruth Patrick and John M. '
i! Palms, 1988. ; l TEPM Analytical Procedures Manual, Teledyne Brown
- Engineering Environmental Services , Midwest
! Laboratory (Northbrook, Illinois). 60062-4197.
- USAR Illinois Power, Clinton Power Station, Updated Safety Analysis Report.
l l l 4 k i i i i 91
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APPENDICES l 4 i a 4 k i }, (.,
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l l I 1 l APPENDIX A l i l Exceptions to the REMP During 1994 ; 1 l l l I l I l l I 1 i 93
I i i I l Data from the radiological analysis of environmental samples are routinely reviewed and evaluated by the Clinton Power i Station Radiological Environmental Group. This data is 4 checked for LLD compliance, anomalous values, quality control
- sample agreement, and any positive results which are j inconsistent with expected results or which exceed any Offsite Dose Calculation Manual reporting levels. Reporting i levels for radioactivity concentrations in environmental l samples required by the Clinton Power Station Offaite Dose ,
Calculation Manual are listed in Table A-1. ' j If an inconsistent result occurs, an investigation is initiated which may consist of some of the following actions: Examine the collection data sheets for any indication of ! collection or delivery errors, tampering, vandalism and l equipment calibration or malfunctions due to electrical
- j. power failure, weather conditions, etc.
Perform statistical tests l Examine previous data for trends Review other results- from same sample media and I different sample media Review control station data { Review quality control or duplicate sample data l Review CPS effluent reports j Recount and/or reanalyze the sample j Collect additional samples as necessary During 1994, no investigations were performed as a result of j reaching any Offsite Dose Calculation Manual (ODCM) reporting ' levels. All sample analysis required by the ODCM achieved > j the LLDs specified by ODCM Table 5.1-3. Sampling and i 1 analysis exceptions are listed in Table A-2 of this appendix. i i a I Y > l 4 4
4 TABLE A 1 l ~ CPS REMP REPORTING LEVEIB FOR RADIOACTIVITY CONCENTRATIONS IN ENVIRONMENTAL SAMPLESG l Water Alvbome Particulate Fish Muk Food Products - Analysis- (pCill) or Gases (pCl/m3) (pCi/kg, wet) (pCi/I) ' (pCi/k0, Wet) H-3 20,000 a _ _ _ _ j Mn-54 1,000 - 30,000 - - i Fe-59 400 - 10,000 - - i i Co-58 1,000 - 30,000 - -- i
}
j Co40 300 - 10,000 - - 1 l Zn-65 300 .
- 20,000 - -
Zr/NtF95 400c _ _ _ l-131 2b 0.9 - 3 100 4 Cs-134 30 10 1,000 60 1,000 } Cs-137 50 20 2,000 70 2,000 i i Ba/La-140 200c _ _ 300 _ l ] a For drtnidn0 water semples. This is the 40 CFR Part 141 value. If no drinking water pathway enlets, e value of l 30,000 pCIA may be used. a b if no drinidn0 water pathway exlets, e value of 20 pCl/l may be used. a c Total for perent and dauphier. d This list does not mean these nuchdes are the only ones considered. Other nucEdes are identified and reported when appkable. 4 i 4 i 95 s
TABLE A-2 SAMPLING AND ANALYSIS EXCEPTIONS FOR 1994
- 1. January 12 CL-6 air sampler elapsed timer was found not working.
Actual time was used for sample volume calculation and a new timer was installed.
- 2. January 14 to February 16 Surface water grab samples obtained on a weekly basis at CL-91 due to the water sampler's sample line freezing.
- 3. January 26 Milk unavailable at CL-98 due to goats " drying up" during the winter months.
- 4. - February 2 CL-11 filter sample head found disconnected. The reason for this was unknown; therefore the sample was considered invalid and discarded.
- 5. February 7 Surface water grab samples obtained on a weekly basis at CL-99 due to the water samplen's sample line freezing.
- 6. February 10 Air sampler at CL-6 found with elapsed timer off by 48.6 hours. The reason was for this was unknown. The elapsed timer was used for sample volume calculation.
- 7. February 14 CL-6 air sampler elapsed timer was found not working.
Actual time used for sample volume calculation and a new timer was installed.
- 8. February 23 Milk unavailable at CL-98 due to goats " drying up" during the winter months.
Grass samples were not collected due to snow cover. 96
l 1 ! l j 9. March 16 i Air sampler at CL-15 found with elapsed timer.off by 1.9 . hours due to a power outage caused by the . electric , utility. The elapsed timer was used for . sample volume
- calculation.
- 10. March 23 Air sampler elapsed timers off at CL-2' and CL-3 by 6.6 hours each. The reason is due to loss of electrical i
power while maintenance was performed on the 12 KV loop. The 'elepsed timers were used for sample volume ,
- calculations. .
t : Air sampler elapsed timer 'off at CL-15 by 3.0 hours due t , to power outage caused by thunderstorms -during the sample period. The elapsed timer was used for sample ! volume calculation. l
- 11. March 29 >
i TLD pole at CL-50 found knocked down, TLD cage at CL-62 l damaged by gunfire. Replanted TLD pole at CL-50 and ' replaced CL-62 cage. Evaluation of CL-50 and CL-62 i results-indicated the data was consistent with other TLD . I results and considered reliable.
- 12. March 30 Air sampler elapsed timer off at CL-15 by 2.7 hours. .
The reason for this is unknown. The elapsed timer was used for sample volume calculation. i
- 13. April 6 l CL-15 air sampler elapsed timer was found not working.
Actual time was used for sample volume calculation and a . new timer was installed.
- 14. April 13 )
Air sampler elapsed timer off at CL-1 by 2.2 hours due to a power outage caused by thunderstorms during the sample period. The elapsed timer was used for sample volume calculation.
- l
- 15. April 14 :
, \
surface water grab sample obtained in lieu of composite sample at CL-91. Compositor found inoperable due -to flood damage, power was restored on April 18, when flood waters receded. 97
. . - - . - - - - - ~ - -- c--.
( ! 1 t l 16. April 22 i . Bottom sediment sample at CL-13a not obtained due to ! l heavy rains causing. creek currents to wash out the { j bottom sediments. The creekbed was left with a hard 1 i gravel bottom. ) i shoreline sediment sample at CL-105 taken on clay-cliffs j
- due to the abnormally high lake level. i
- 17. May 11 Air sampler elapsed. timers off at CL-2 by 14.6 hours and .
j CL-3 by 14.3 hours. The reason is due to loss of l electrical power while maintenance was performed on the- ! 12 KV ^ loop. The elapsed timers were used for sample volume calculations.
- 18. June 15- I Air sampler elapsed timer off at CL-8 by 27.0 hours due ,
to a power outage caused by thunderstorms during the sample period. The . elapsed timer was used for sample volume calculation. , i
- 19. June 22-f Air sample pump at CL-7 found seized, replaced. air sample pump. The ! filter was ' analyzed, and the result :
was evaluated and determined to be unreliable and I considered invalid. j i
- 20. June 28 i
The TLD holder and pole for CL-72 and CL-77 (co-located) l were stolen. The pole and cage were replaced at this , location and the TLDs rehung. .
- 21. June 29 !
Air sampler elapsed timore were off at CL-2 and CL-3 by ; 11.3 hours. The reason is due to loss of electrical power while maintenance was performed on the 12 KV loop. The elapsed timers were used- for sample voluna calculations, j Air sample pump at CL-6 found deenergized with 81.6 hours of operation. Cause determined to be a blown fuse. . CPS maintenance restored power. The sample.was 1 considered invalid and discarded due to having an inadequate volume collected. Unable to obtain vegetation samples at CL-115 due to l inadequate plant growth, slowed plant growth was t i f
l t attributed to herbicide carryover from an adjacent cornfield.
- 22. August 31 Air sampler elapsed timers were off at CL-7 by 1.5 hours j and CL-8 by 1. 0 hour due to a power outage caused by
, thunderstorms during the sample period. The elapsed
, timers were used for sample volume calculations. Unable to obtain 3 vegetation samples at CL-115 due to , inadequate plant growth. Two of the required samples , were obtained. Slowed plant growth was attributed to ) herbicide carryover from an adjacent cornfield.
- 23. september 7 Air sampler elapsed timer off at CL-8 by 3.4 hours due to a power outage caused by thunderstorms during the j
sample period. The elapsed timer was used for sample volume calculation.
- 24. september 9 to October 20 l'
Surface water grab samples obtained on a weekly basis at CL-99 due to the creek level dropping below the water sampler's inlet suction line.
- 25. september 14 4
Air sampler elapsed timers were off at CL-7 and CL-8 by 6.5 hours, and CL-94 by 3.0 hours due to construction in , the area. The elapsed timers were used for sample
- volume calculations.
j
- 26. september 21 i
CL-8 air sampler elapsed timer was found not working. 4 Actual time was used for sample volume calculation and a new timer was installed. Air sampler timer at CL-4 did not function during the sample period. The timer gears did not engage after being reset. Since the air sample pump was running and the color of the particulate filter appeared normal, the
! actual time was used for sample volume calculation.
Air sampler elapsed timer was off at CL-6 by 6.3 hours due to a power outage caused by thunderstorms during the sample period. The elapsed timer was used for sample volume calculation. 4
1
- 27. September 28 TLD at CL-55 found on the ground because the holder and i
, pole were destroyed. It is suspected that it was l destroyed by the county mower. A new TLD, pole and cage 1 were replaced at this location. Evaluation of CL-55 data indicated this data to be consistent with previous data.
- 28. September 28 Unable to obtain 3 vegetation samples at CL-115 due to 2
inadequate plant growth, 2 of the required- samples collected. Slowed plant growth attributed to herbicide
- carryover from an adjacent cornfield.
4
- 29. November 2 Air sampler elapsed timer off at CL-7 by 0.9 hours due .
l to construction in the area. The elapsed timer was used i for sampla volume calculation.
. 30. November 9 CL-7 was found with the particulate filter paper damaged )
causing it to be effectively bypassed. The analysis of ! 1 the data indicated the sample to be unreliable and , inconsistent with previous data. Results not used in l < annual average and discarded as invalid. 1
- 31. November 30 Air sampler elapsed timer off at CL-6 by 10.7 hours due I to construction in the area. The elapsed timer was used for sample volume calculations.
- 32. December 7 Air sampler elapsed timer off at CL-15 by 2.0 hours suspected to be cause by a power outage. The elapsed timer was used for sample volume calculation.
- 33. December 21 2 l
CL-1 elapsed timer was not working, replaced the timer i unit. Actual elapsed time used for sample volume calculation.
- 34. hr 28 CL-1 elapsed timer was not working, replaced the timer unit. Actual elapsed time used for sample volume calculation. I 100
l i l APPENDIX B REMP Sample Collection and Analysis Methods l l l I l l l l 101 \ h
I 102
.. . - .. . - . ~ . . - .
l
- t. i 2
TABLE B-1 i
- j. CLINTON POWER STATION 1
i RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM i f
SUMMARY
OF SAMPLE COLLECTION AND ANALYSIS METHOOS
;. Approximate Teledyne Sample Sempting Sample Size Procedure' Procedure ;
4 Analysis Medium Method Collected Number Abstract i AP-Gross Beta Conhnuous air 280m3 TIML-AP-02 Sample counted in a low
; sampling levelgas fkw proportional through filter counter j }
4 media ' I 4 l WN Grob 7.6 I TIML-W(DSW1 . Sample evaporated on a j stainless steelplanchette forlow-level gas flow l propothonal counting - l 4 ! SW Grab 3.8 ( TIML-W(DSW1 Sample evaporated on a .- .i
- stainless steel planchette - ;
j forlow-level gas flow j proportional counting . 3 1 j SW Corrposite 3.8 ( TIML-W(DSW1 Sample evaporated on a i stainless steelplanchette i forlow-level gas flow
- proportionalcounting j VE Grab 2.5kg TIML-AB 01 Sample shed for low-level l , gas flow proportional counting i
{ 4 B4 Grab 1.5-2.0kg TIML AIM 1 Sample puNenrod and . > l
! dried for low-level gas flow l: proportional counting .
l SS Grab 1.5-2.0kg TIML-AB-01 Sample pulwortred and j dried forlowlevelgas flow Proportionalcounting l CWV Composite 3.8 ( TIML-W(DS$1' Sample evaporated on a , i stainless steelplanchette i j forlow4evelges flow !
- propothonalcounting '
I l
~
i SO Grab 1.0kg TIML-AIM 1 Semple pulvertred and j dried for low-level gas flow propoetionalcounting i
. 103 1
1 ' 1
- _ _ __ _.2_ I
TABLE B-1 (Cont'd) Approximate Teledyne Sample Sampling Sample Size Procedure Procedure Analysis Medium Method Collected Number Abstract Gemme AP Composite 3640m3 TIML GS-01 Germanium gamma isotopic Spedroscopy analysis G Grab 1.0kg - TIML-GS01 Germanium gamma isotopic analysis VWV Grab 7.6 ( TIML-GS-01 Germanium gammeisotopic analysis SW Composite 3.8 ( TIML-GS-01 Germenlum gamma isotopic analysis VE Grab 2.5kg TIML-GS-01 Germanium gamma isotopic analysis BS Grab 1.5 - 2.0kg TIML-GS-01 Germanium gamma isotopic analysis SS Grab 1.5 - 2.0kg TIML-GS.01 ' Germanium gamma isotopic analysis SL Grab 0 3 - 6.0kg TIML-GS-01 Germenlum gamma isotopic analysis F Grab 2.5kg TIML-GS41 Germanium gamma isotopic analysis I hE Grab 3.Okg TIML-GS-01 Germanium gamma isotopic analysis DN Composite 3.8 ( TIML-GS-01 Germanium gamma isotopic l analysis SW Grab 3.8 ( TIML-GS 01 '4rmenium gamma isotopic analysis SO Grab 1.Okg TIML-GS41 Germanium gamma isotopic analysis M Grab 3.8 ( TIML-GS01 Germanium gamma isotopic I analysis Direct TLD Contmuous FM TIML-TLD41 Integration of thermelly Radiation Exposure stimulated visible photons 104 -) i
. . _ _ . ._.-~ . = . . - = . . . . . . . . . .. _ . - . .- ._
l l TABLE B-1 (Cont'd) Approxirnate Telodyne Sample Sampling Sample Size Procedure Procedure ; Analysis Medium Method Collected Number Abstract Gross Alpha SW Composite 3.8 ( TIML-W(DS)-01 Sample evaporated on a i (cont'd) stainless steel planchette for , low-level gas flow proportional counting WN Grab 7.6 ( TIML-W(DS) 01 Sample evaporated on a ; stainless steel planchette for low-level gas flow proportional counting ; i BS Grab 1.5 - 2.0kg TIML-AB-01 Sample pulverized and dried i forlow-level gas flow proportional counting DW ComposRe 3.8 ( TIML-W(DS)-01 Sample evaporated on stainless steel planchette for low-level gas flow . f proportionalcounting 5 SO Grab 1.0kg TIML-AB-01 Sample pulverized and dried J for low-level gas flow proportional counting SS Grab 1.5 - 2.0kg TIML-AB-01 Sample pulvenzed and dried l for low-level gas flow i l proportional counting l l Sr-90 BS Grab 1.5 - 2.0kg TIML-SR-06 Hydrochloric acid leech and l low-level gas flow proportional counting SS Grab 1.5 - 2.0kg TIML-SR-06 Hydrochloric acid leech and low-level gas flow proportionalcounting l M Grab 3.8 ( TIML-SR-07 Sample chemically , ! separated and dried for low- ! I level gas flow proportional counbng Tritium SW Composite 3.8 ( TIML-T-02 Distillation followed by counting in a liquid acintillation counter i l DN Composite 3.8 ( TIML-T-02 Distillation followed by I counting in a liqu.d scintillation counter l i l l' 105
I
, 4 TABLE B-1 fCont'Q, Approximate Teledyne Sample Ser@ ling Sample Size Procedure Procedure Analysis Medium Method Collected Number Abstract Tntium SW Grab 11.4 ( TIML-T-02 Distillation followed by (cont'd) counting in aliquid scintillation counter WN Grab 22.8( TIML-T-02 DistHlation followed by counting in aliquid scintillation counter SW Grab 3.8 f TIML-T 02 Distdlation followed by counting in a liquM scintillation courter i 1-131 14! Grab 1.4kg TIML-GS41 Germanium gamma isotopic analysts 1
Al Continuous air 280m3 TIML-l-131-02 Germenkam gamma isotopic samphng analysis through flfter mede SW Grab 3.6 ( TIML-l-131-03 lon exchange and proportional beta counting WN Grab 74( TIML-l-131-03 lon exchange and proportional beta counting G Grab 1.Okg TIML-GS41 Germanium gamma isotopic r analysis M Grab 3.8 ( TIML-t-131-01 lon exchange and proportional beta counting , i l i 106
i 4 e TABLE B-2 . i' 1 i 1994 REMP SAMPLING AND ANALYSIS FREQUENCY
SUMMARY
i i Number of Number of Number of q
'] ' ! Sample Sampling Conection Samples Type of AnalytJs Samples Type Locatens Frequency Cotoded Analysm Frequency Analyzed
- l ;
$ i
- . . Air Pedeutete 10 Weeldy 516 Gross Sete Weeldy 516 l l Gemme lootopic Quarterly Composite e i
j_ Air lodne 10 Weeldy $16' lodine-131 Weeldy 516 , i Direct Radletion 86' Quarterly 342 Gemme Exposure Quarterly 342 - l (TLD) _( continuous) } Surtsee Watei 4 MontNy 4 Gemme lootopic MontNy. 4 1 (Greb) Tritiume Quarterly Composite e 12 i j Gross Bete MontNy 4 Trttlum8 MontNye 12 ; i
' Surface Water 1 MontNy 12 Gemme lootopic Monthly 12 j (Inteles Compoelle) Tritium MontNy 12 j Groes Bete Monthly 12 >
1
- Surface Water 1 MontNy 12 Gemme lootopic MontNy 12
- (EtRuent CompoeNe) Gross Bete Monthly 12
] Gross Alphe MontNy 12 '
~
i j Tralum Quartetty Composite 4 lodine-131 MontNy 12 1 i Surtem Water 2 MontNy 24 Gemme lootopic MontNy 24 j (Upstroom Compoone) Gross Bete MontNy 24 , , Gross Alphe MontNy 24 i Tritium Quarterly Compoone 8 j WellWater 2b Semimonthly 78 loh131 Semimonthly 75 . ! Groes Alphe Monthly Compoone 35
- Groes Bete Monthly Composite 35
- Gemme lootopic Monthly Compoede 35 4 Tritium Quarterly Compoone 12 J
DrWdng Water 1 MoNNy 12 Gross Alphe MontNy 12 l Gross Bote MontNy 12 Gemme lectopic MontNy 12 ) Traium Quarterly Compoone 4 i Botom Sediments 7 Semannusty 13 Gross Alpha Semiennusty 13 j Gross Bote SemiennueNy 13 j Gemme lootopic Semiennusty 13 1 Sr410 Semiennue#y 13 l 4 I 107 ? I s
TABLE B-2 (Cont'd) l Number of Number of Number of Sample Samphng Conection Samples Type of Analysis Samples Type Locations Frequency Colected Anotysk. Frequency Analyzed
- Shoreline 8 SemiennueNy 16 Gross Alpha SemlennueBy 16 l l
Sediment Gross Beta Semiennueny 16 Gemme lootop6c Semiennusty 16 i Sr-90 SemiennueRy 16 l Aquatic 6 Semiennuely/BimontNyc 22 Gamma lootopic SemiennueNy/ Bimonthly 22 Vegetation Grass 5 Monthly / Semimonthly d 90 Gamma lootepic Monthly /SemimontNy 90 (including 1-131) Vegetables 4 Monthly (during growing 4 Gross Beta Monthly e season) Comme lootopic MontNy 4 (including 1-131) Fish 2 SemiennueBy 16 Gamma lootopic SemiennueNy 16 Milk 2 Monthly / Semimonthly d 36 Gamma lootopic Monthly /SemimontNy 36 lodine-131 Monthly /SemimordNy 36 Sr-90 MontNy/SemimontNy 36 Meat 1 AnnuaNy (when available) 3 Gamma lootopic Annue#y 3 (including 1-131) Soll 11 Triennueny/ Annually' 11 Gross Alpha TriennueNy/ Annually 11 l Gross Bete 11 l Gernma lootopic 11 Number of samples enelyzed does not indude duplicate analysis, recounts or reanalysis, a Semples taken et CL-93 are analyzed montNy for tritium, el ather surfoce water greb temples are composNed for quarterty analysis. i b Samples coiledad at CL-12 are taken prior to water treatment and after water treatment c Semples are cotoded semiennually at CL-105 and tumontNy at all other locations from AprH through October. d Samples are colected monthly from November through April and semimontNy May through October. e Samples are colected annually at CL-16, triennisty at all other locations. l I 108 l l i
TABLE B-3 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM ANNUAL
SUMMARY
l l Name of Facility: Clinton Power Station Docket No.50-461 Location of Facility: DeWtt, luinois Reporting Period January 1 - December 31,1994 (county, state) Medium or Type of 1.ower Limit AllIndicgor Imcation with Control Number of Pathway Sampled Analysis of locations: Highest Annual Mean Imedians: Nonrmnine Detectim Reported (Unit of Total Nanber Mean(0 Nar~ Mean(0 Mean (O (llD) (Range) Distam:e and Directim (Range) (Range) Maurements Measwomcat) Performed Direct m.m.a 'IU) NA 18.2(3223 22) C1 83 20.9(4'4)a 17.8(2MO) 0 342 (14.0 230) 0.5 miles NNW (19.8 23.0) (15.7- 20.3) (mR/Qtr) Air Particulates Oross Beta NA 0.020(465/465)b C1,3 0.021(52/52) 0.020(51/51) 0 (pCl/m3) 516 (a004 - a048) 0.7 miles NE (0.008 0.042)' (0.006 0.038) Oamma Spac t i Be-7 NA 0.080(36/36) Clell 0.091(4 4) 0.091(4'4) 0 (0.06M.ll4) 16 miles s (0.076 0.114) (0.076 0.114) K-40 0.042 UD - UD llD 0 Co-60 0.0010 IID - 11D 11D 0 Nb-95 0.0018 llD - IID UD 0 Zr-95 0.0024 11D - IlD UD 0 Ru 103 0.0050 11D - 'UD LLD 0 Ru-106 0.0088 11D - IlD llD 0 Cs 134 0.0009 11D - UD L1D 0 Cs-137 0.0009 LIl) - IlD 11D 0 Ce-141 0.0028 11D - UD llD o ! Co-144 0.0062 11D - 11D 11D 0 l Air ledhne 1-131 0.07 11D - UD 11D
- O l (pCWm3 ) 516 )
Burface Water Oross Beta 1.1 2.7(83'84) C1-99 3.l(12/12) 2.7(11'12) 0 l I (pCVI) 96 (0.8 8.6) 3.5 miles NNE (0.8 -8.6) (1.6 4.3) Goes Alpha 1.8 1.4(7/36) Cl 99 5.4(1/12) NA 0 l 36 (0.5 - 5.4) 3.5 miles NNE - l 1 Tritium 193 360(3/48) C193 360(3/12) 11D 0 48 (186 - 653) 9.4 miles SW (186 - 653) Note: Column explanebons et the end of Table B-3. 1 l 109
l TABLE B-3 icont'd1
. bledaan or Type of lower Umit AllIndicalor tecmion with Control Number of Psehway Sampled Analysis d lecations: Highest Annual Mean locations: Nonroutine (Unit of Total Number Detection ggcan (0 Name hican(f) Reported hfcan (O Mesurement) Performed (llD) (Range) Distance and Direction (Range) (Range) hicaswements Burence Wseer 1-131 0.5 UD . IlD UD 0 (eenrd) 12 Gamma spec 96 ,
t Be 7 29.6 11D . UD llD 0 K-40 57.5 llD . UD 11D 0 Mn-54 3.0 11D . IlD 11D 0 Fe-59 7.4 UD . L1D 11D 0 Co 58 3.2 UD . IlD 11D 0 Co-60 3.2 IlD - UD UD 0 Zn-65 5.6 11D . UD llD 0 Nb-95 3.9 11D - UD UD- 0 Zr 95 8.8 UD . IID UD 0 Ca 134 3.5 11D . 11D flD 0 Cs-137 3.7 IlD - UD llD 0 , Ba-140 10.6 UD . IlD llD 0 14 140 3.5 11D . IlD 11D 0 Co 144 44.2 UD . HD 11D 0 Detalh 8Weser Gross Boa NA 2.0(12:12) Cle14 2.0(12'12) NA 0 (pCH) 12 (1.3 - 2.3) O miles (1.3 2.3) Gross Alphs 0.6 11D - IlD NA 0 12 Tritium 193 IlD . UD NA 0 4 Gamma Spec 12 Be 7 20.4 11D - 11D NA 0 K-40 44.1 IlD . IID NA 0 Mn 54 8.4 UD . IID NA 0 Fe 59 . 5.6 11D . UD NA 0 Co $8 3.0 11D . IID NA 0 Co 60 3.2 11D . UD NA 0 Zn 65 5.2 11D . UD NA 0 Nb 95 3.7 IlD . UD NA 0 Zr-95 8.1 11D - UD NA 0 Co 134 3.2 IlD . U.D NA 0 Co-137 2.9 11D - 11D NA 0 Bn 140 10.3 11D . IlD NA 0 14 140 2.6 UD - UD NA 0 110
TABLE B-3 iCont'd) Medman or T)pe of 1mer 1.imit All Indicator 1mation with Control Number of Pathway Sampled Analysis of locations: liighest Annual Mean tuations: Nonroutme (Unit of Total Number Detection Mcan (O Name Mean(0 Mean (f) Reported Measurement) Perfornwd (LLD) (Range) Distance and Direction (Range) (Range) Mesmements Detnisms Water Co 144 27.1 IlD - 11D NA 0 (eemrd) OeE Water Oross Beta 2.5 1.8(3336) Clel2T C 2.2(9'12) NA 0 (pCH) 36 (1.0 3.0) 1.6 miles E (l.5- 3.0) Gross Alpha 3.1 1.0(4'36) Cir7D 1.0(4!36) NA 0 36 (0.8 - 1.2) 2.3 miles ESE (0.8 1.2) 1-131 0.5 LID . IlD NA 0 78 Tritium 193 IlD - 11D M 0 12 Gamma Spec 36 Ik 7 27.1 11D - IlD NA 0 K-40 52.1 UD . IlD NA 0 Mn-54 2.9 11D - IlD NA 0 Fe 59 6.0 IlD - 11D M 0 Co.58 2.8 IlD - IlD NA 0 Co-60 3.2 UD - UD NA 0 Zn 65 5.8 IID - 11D NA 0 Nb 95 3.8 11D . - 11D NA 0 Z.r 95 7.6 11D . IlD NA 0 Cs 134 2.9 11D - 11D NA 0 Cs-137 3.0 11D - IlD NA 0 Bn-140 10.8 UD . IlD NA 0 14-140 3.3 11D - IlD NA 0 Co 144 38.3 IID - 11D NA 0 Muk (pCl/I) l-131 0.5 LID - LID IID 0 36 Sr-90 NA 1.9(17/17) Cir98 1.9(17/17) 1.6(19'19) 0 36 (0.9 3.2) 3.7 miles SSW (09 3.2) (0.9 2.3) Gamma Spec 36 Be-7 29.7 IID - 11D IlD 0 K-40 . 1940(17/17) Clr98 1940(17/17) 1347(19/19) 0 (1370 2150) 3.7 miles SSW (1370 2150) (1100 1890) Mn 54 3.8 11D . IlD llD 0 Fe-59 8.4 11D . IlD 11D 0 Co-58 3.7 11D - IID 11D 0 111
- _ . - . . . . _ . - _ - _ - ~ _ - -. . ~ . . . . . . - - .- . - - . . -
TABLE B-3 (Cont'd) Mednen or Tne of 1mer Umit All Indicator lasion with Control Nwnber of Pashway Sampled Analysis of locatione Highest Annual Mean locations: Nonroutine (Unit of Total Number hection Mean (f) Name Mean(f) - Mean (f) Reported Mesurement) Perfonned (UD) (Range) Distanceand Direction (Range) (Range) - Messements M (eent'd) Co40 5,1 UD - UD llD 0 Zn45 8.4 MD - IID 11D 0 ; bb95 3.9 11D . IID HD 0 Zr-95 9.1 UD . IID llD 0 Cs 134 4.2 IID - UD UD 0 t Ch-137 4.0 11D . UD 11D 0 i Be140 12.7 11D . IID 11D 0 i 12-140 3.2 11D - 11D UD 0 i C+144 45.7 IID . IlD UD 0
+
Phh(pa 4 wet) Gamma Spec 16 i Bo 7 0.073 11D - 11D 11D .O K-40 . 2.95(8 1) C1-19 ~ 2.95(81) 2.94&1) 0 ! (2.43 3.41) 3.4 miles E '(143 3.41)- (2.24 3.32) Mn 54 0.008 11D . 11D 11D 0 Fe-59 0.021 11D . UD MD 0 I Co 58 0.009 11D - IID MD 0 , Co 60 0.009 UD - MD 11D - 0 i Zn45 0.016 IID . UD llD 0 bb95 0.012 IlD - 11D UD 0 Zr-95 0.022 11D . 11D UD 0 Ru-103 0.010 11D . IlD 11D 0 Ru lM 0.081 11D . 11D llD 0 1 Co 134 0.009 11D - IlD 11D 0 ' ) Co137 0.010 11D . 11D MD 0 l Be 140 0.025 IID . 11D 11D 0 [ 14-140 0.008 11D . 11D MD 0 Ce141 0.023 11D - IID UD 0 ' l C+144 0.051 11D - 11D 11D 0 ' Bastaan Oross Beta 3.57 18.07(10/11) C17C 0 26.82(l'2) 17.09(17) andhnente 13 (9.28 28.58) 1.3 miles SE (25.05 28.58) (15.67 . I8.50) (pCl/8 dry) Ornes Alpha 4.79 10.98(7/11) Cl-7C 13.59(l'2) 8.91(l'2) 0 13 (5.31 13.95) 1.3 miles SE (13.22 13.95) (6.76 . I1.05) i Sr40 0.016 11D C1,105 0.016(l'2) 0.016(20) 0 13 50 miles S (0.011 0.021) (0.011 0.02I) Gamma Spec 13 112
)
TABLE B-3 fcont'd! Mednan or Type of lower Limit AllIndicator location with Control Number of Pathw ay Sampled Analysis d incations- Ilighest AnnualMean Locations: Nonroinine (Unit of Total Number Detection Mean (f) Name hfcan(f) Reported Mean (f) Mesurement) Performed (LLD) (Range) Distance and Direction (Range) (Range) Measments Betteen Be-7 0.44 1.02(&ll) Cbl9 3.29(l'2) 0.97(1/2) 0 Sadhments (0.18-3.29) 3.4 miles E - - (eemt'd) K-40 - 15.01(11/11) Cb7C 19.77(12) 19.39(2'2) 0 l 1.3 miles SE l (9.08-20.97) (18.57- 20.97) (17.25- 21.52) Mn-54 0.037 IlD - IlD llD 0 . Fe-59 0.087 LID - 11D 11D 0 Co-58 0.049 11D - LID 11D 0 Co-60 0.042 11D - IlD IID 0 Zn45 0.170 IlD - IID 11D 0 Nb-95 0.076 IID - IlD 11D 0 Zr-95 0.089 IlD - LID 11D 0 Cs-134 0.076 IlD - 11D 11D 0 Cs-137 0.014 0.140(10 11) Cbl0 0.36(12) 0.32(2 7) 0 (0.017 0.380) 5.0 miles ENE (0.33-0.38) (0.28- 0.35) Ba-140 0.13 LID - 11D 11D 0 14-140 0.045 LID - llD 11D 0 Co 144 0.24 LID . - IlD llD 0 Ac-228 - 0.78(11/11) Cb7C 1.39(l'2) 1.11(2.2) 0 (0.27 1.43) 1.3 miles SE (1.35- 1.43) (0.80 1.41) Bi-212 - 0.77(11/11) Cbl0 1.36(1 7) 1. l(2/2) 0 (0.34 1.43) 5.0 miles ENE (l.29 1.43) (0.6 - 1.5) Bi-214 - 0.49(11/11) Cbl0 0.85(l'2) 0.60(l'2) 0 (O.15- 0.87) 5.0 miles ENE (0.83- 0.87) (0.36 0.83) Pb 212 - 0.75(11/11) C1 10 1.32(17) 1.11(2'2) 0 (0.22 1.52) 5.0 miles ENE (l.11 1.52) (0.86- 1.36) Pb-214 - 0.59(11/11) Cl-7C 1.01(2'2) 0.74(2/2) 0 (0.17 1.1!) 1.3 miles SE (0.91 1.1!) (0.54 0.94) Ra-226 - 1.21(11/11) C1,10 2.5(17) 1.59(2/2) 0 (0.37-3.03) 5.0 miles ENE (2.0 3.03) (0.89- 2.29) TI-208 - 0.25(11/11) C1,10 0.41(2'2) 0.37(1'2) 0 (0.086 0.44) 5.0 miles ENE (0.38 0.44) (0.27 0.47) Shoesthme Gross Beta - 9.87(14/14) Cl-105 14.5(17) 14.5(17) 0 Ged!=nents 16 (4.11 15.18) 50 miles S (7.76 21.19) (7.76- 21.19) (fCl/Ed87) Omes Alpha 4.41 6.40(5/14) C1 89 7.15(l'2) 6.61(2 7) 0 16 (4.68 8.23) 3.6 miles NNE (6.06 8.23) (3.48 9.74) Sr.90 0.012 0.012(1/14) Cl 7C 0.012(1/14) 0.009(1/2) 0
- 1.3 mile's SE - -
Osn ra Spec 16 113
. .- -~ .- . . - .- - - . - - . - . - . . . . . . - - - ... -
I i l
'PARM B-3 -(Cont 8d1
- Medium or Type of Iomer Limit AllIndicace lecmion with Control Number of i Pathmay sampled Analysis of lustions
- Highest AnnualMean locaions: Nonfoutine (Unit of Total Number Detedian Mean (O Name Reported 7 Mean(f) ' Mean (f)
, Measurement) Performed (UD) (Range) lhetance and Direction (Range) (Range) Measurements i e j HInseeline Be-7 0.20 0.Sh&l4) C1,93 UD 0 1.53(12) 1 ha 0.4 miles SW a (0.11 1.84) (1.22 1.84) ' 3 (somrd) { K-40 . 9.9 %14 14) C1,10 12.74(2 2) 12.4(l'2) 0 ! ) (6.29 16.04) 5.0 miles ENE (9.44 16.04) (8.9 15.95) Mn-54 0.017 11D . IlD UD 0 l Fe-59 0.051 UD . 11D 11D 0 i Co-58 0.027 11D . IID llD 0 Co40 0.023 UD . 11D UD 0 Zn45 0.067 UD - IlD llD 0 i l Nb-95 0.028 UD . 11D 11D 0 q Zr-95 0.036 UD . 11D UD 0 j Cs 134 0.034 11D . UD UD 0
- Cs-137 0.021 0.033(5/14) C1,89 0.039(l'2) UD 0 I (0.016 0.047) 3.6 miles NNE (0.030 0.047) j He 140 0.054 11D . LID llD 0 4 140 0.015 11D - 11D UD 0
- Co.144 0.11 UD . IlD llD 0 1 Ac-228 .
0.29(14'14) C1,105 0.62(2/2) 0.62(1 0; O 4 s (0.14 0.65) 50 miles s (0.34 0.89) (0.34 0.89) Bi 212 0.24 0.3hil/14) 01,10$ 0.60(22) 0.60(l'2) O t (0.130 0.73) 50 miles s (0.32 0.88) (0.32 0.88) ' } Bi-234 . 0.22(lW14) C1,93 0.40(l'2) 0 0.37(l'2) j (0.090 0.50) 0.4 miles SW (0.45 0.50) (0.24 0.49) l N 212 . 0.2hl4/14) C1,105 0.57(20) 0.57(12) 0 4 (0.082-0.58) 50 miles S (0.28 0.85) (0.28 0.85) l N214 . 0.26(l4 14) C1,93 0.58(l'2) 0.30(1 2) 0 j (0.12 0.61) 0.4 miles SW (0.54 0.61) '(0.23 0.59) Ra-226 0.39 C1,93 f 0.71(11'14) 1.9)(r2) 0.94(2'2) 0 (0.2 1.91) 0.4 mile: SW (1.9 1.91) (0.54 1.33)
- T1208 .
0.l(14/14) C1,105 0.19(2'2) 0 0.19(2'2) (0.047 0.2) Su miles S (0.095 0.29) (0.095 0.29) i i Agende Gamma Spec Vapemens 22 l (pCI/g wet) i
- Be-7 . C1,19 0.71(20'20) 1.07(4 4) 0.50(l'2) 0 i (0.10 1.42) . 3.4 miles E (0.7 1.4) (0.32 0.67) i '
t
- K-40 -
2.05(20/20) C1,19 3.32(4/4) 0 1.65(2/2) j (0.25 4.76) 3.4 miles E (2.52 4.76) (0.33 2.96) 3 Mn 54 0.036 UD . IID UD 0 Fe 59 0.094 UD . UD UD 0 l Co-58 0.032 UD . UD UD 0 L 4 114 4 1
- _ .. . -. . . _ _ . _.. .- _ . . _ . _ . . ~ . . _ _ . _ . _ ._ ___
1 i 4 i s , TABLE B-3 fcont'd1 1 4 i Medaan or Type of immer Limit AllIndicator location with Control Niunber of Pathway Sampled Analysis of IncWions: Highest Annual Mean locations: Nonroutine i (Unis of Total Number Detection Mean (O Name Mean(f) Mean (f) Reported Measuresnee) Performed (LIS) (Range) Distanceand Drection (Range) (Range) Measureum , l L ] Agnatic Co-60 0.035 IID . UD 11D 0 { Voyesame j (camed)
- Zn45 0.11 UD . 11D 11D 0 *
] Nb95 0.083 IID . UD llD 0 i Zr-95 0.I I UD . 11D UD. O { Cs-134 0.045 llD . IlD llD. O j Cs-137 0.051 0.049(920) Cbl05 0.071(2'2) 0.071(1'2) 0 1 (0.026 0.085) 50 miles S (0.065 0.077) (0.065 0.077) Be 140 0.12 IID . UD IlD 0 j La-140 0.031 11D . IlD 11b o ! Ce 144 0.26 UD - IID IlD 0 i l VoyeaMrs Gross Beta .- 4.52(3101) C1,118 5.40(11'12) 4.30(12/12) 0 { } (pOs wee) 43 (1.86 14.74) 0.7 miles NNE (2.31 14.74) (2.33 6.65) ] Gamma Spec 43 Be-7 0.12 0.210(24'31) C1,117 0.210(9'12) 0.183(12/12) O a j (0.010 - 0.670) 0.9 miles N (0.080 0.3w)) (0.090 0.240) K-40 . 4.27(31'31) C1,118 4.88(11'12) 3.86(11'12) 0 l (1.99- 8.59) 0.7 miles NNE (2.18- 8.59) (2.66 7.17) { Mn-54 0.012 UD . 11D llD 0 i Fe 59 0.025 11D - IlD 11D 0 l Co 58 0.01 11D . IID llD 0 j CW 0.01 11D - 11D 11D 0 j Zn45 0.024 11D . 11D 11D 0
- bb95 0,014 11D - IID 11D 0
{ Zr-95 0.023 11D . IID 11D 0 j 1-131 0.017 11D - 11D 11D 0 4 Cs-134 0.011 11D . UD 11D 0 l Co-137 0.013 11D - 11D 11D 0 ! Ba 140 0.031 11D . IlD 11D 0 g 12-140 0.028 IID . IlD UD 0 ) Co 144 0.076 IlD . IID llD 0 i a j Ceams(pCWs wee) Gamme Spec . 90 1 1 l Be 7 . 3.75(54'54) Cle2 4.55(18/18) 3.25(3606) 0 ) (0.21 22.12) 0.7 amles NNE (0.40 20.79) (0.35 13.16)
- K-40 . 6.65(5434) Cir2 7.29(18/18) 5.54(36/36) 0 0.7 nilesNNE (1.02 22.08) (1.91 22.08) (0.60 8.23) 4 Mn-54 0.021 IID . IID 11D 0 3
f i 115 4
TABLE B-3 fCont'd) i I Medium or Type of Imerlimit AllIndicator location with Control Number of i Pathway Sampled Analysis d locations: Highest Annual Mean locations: Nonroutine (Unit of Total Number Detection Name Reported Mean (f) Mean(0 Mean (f) Mcasurement) Puformed - (UD) (Ran8e) Distanceand Direction (Range) (Range) Measurements A Grass (cent'd) Fe59 0.040 11D . UD 11D 0 Co 58 0.017 UD . 11D llD 0 , 0o-60 0.028 11D . UD 11D 0 Zn 65 0.064 UD - 11D llD 0 h495 0.024 11D . IlD UD 0 Zr-95 0.035 11D . UD UD 0 I-131 0.055 IlD . IlD IID 0 Cs 134 0.020 11D . 11D 11D 0 Cs-137 0.022 IID . IID UD 0 Bn 140 0.071 IID - LID 11D 0 La-140 0.074 IlD . 11D 11D 0 Co-144 0.160 IlD - 11D 11D 0 Meet (pCFg wet) Osnma Spec 3 Be7 0.60 UD . 11D . O K-40 2.50 2.63(2/3) C1,106 NA 0 2.63(F3) (2.50 2.76) 2.0 miles NNE (2.50 2.76) ! Mn-54 0.081 11D - 11D NA. 0 l F+59 0.036 11D . UD NA 0 l Co 58 0.054 IlD - UD NA 0 Co 60 0.091 11D . LID NA 0 Im45 0.25 11D . 11D NA 0 Nb-95 0.081 11D . IlD NA 0 Zr 95 0.064 11D - 11D NA 0 Ru 103 0.040 UD . IlD NA 0 Ru 106 0.67 11D . 11D NA 0 1-131 0.11 IID . UD NA 0 Cs.134 0.068 11D . IlD NA 0 Cs-137 0.074 IlD . 11D NA 0 Be 140 0.22 11D . 11D NA 0 La-140 0.024 - 11D . IID NA 0 Cel41 0.046 UD . 11D M 0 0 144 0.24 11D - LID NA 0 SaE(pC1/g dry) Oross Beta - 21.96(10/10) Cir4 25.0(1/1) 20.37(1/l) 0 11 (19.24 25.0) 0.8 miles SW . . Gross Alpha 9.96(la'10) C1 94 12.92(l!!) 9.94(1/1) 0 11 (6.58 12.92) 0.6 miles E - . GamuneSpec 11 Be' O.29 11D . 11D IlD 0 K.40 . 18.37(1010) Cir7 22.07(1/1) 16.18(1/l) 0 (16 84 22.07) 2.3 miles SE - - 116
TABLE B-3 fCont'd) Medarn or Type of 1mer Limit AllIndicaor location with Control Number of Pathmay Sampled Analysis d Incations: lii hest E AnnualMean locations: Nonroutine (Unit of Total Number Detection Mean (f) Name Mean(f) Reported [ Mean (f) Measurement) Performed (LLD) (Range) Distance and Direction (Range) (Range) Measurements l Sag (tamt'd) Mn-54 0.028 11D - IlD UD 0 Fe-59 0 065 11D - IlD UD 0 Co 58 0.044 UD - 11D LID 0 Co-60 0.026 11D - 11D LID 0 Zn45 0.110 11D - IID 11D 0 Nb-95 0.062 11D - LID UD 0 Zr-95 0.095 ll.D - IID 11D 0 Cs-134 0.049 11D - LID 11D 0 Cs-137 0.027 0.21(7/10) Cbil 0.44(1/l) 0.44(1/1) 0 (0.037- 0.37) 16 miles S - - 14 140 0.078 11D - 11D 11D 0 La-140 0.026 11D - 11D 11D 0 C+.144 0.23 11D - IlD 11D 0 Ac-228 - 1.07(10/10) Cbil 1.35(1/1) 1.35(t ri) 0 (0.70 1.26) 16 miles S - - Bi-212 - 1.05(10/10) Cbil 1.4?'l/1) 1.42(1/l) 0 (0.67 1.22) 16 miles S - - Bi-214 - 0.74(10'10) Cb3 0.94(1.1) 0.88(1.1) 0 l (0.48 0.94) 0.7 miles NE - - Pb 212 - 1.06(i0/10) Cbil 1.33(1/1) 1.33(1/1) 0 , j (0.68 1.27) 16 miles S - - Pb-214 - 0.92(10/10) Cb2 1.08(1/l) 0.97(1/1) O t j (0.59-1.08) 0.7 miles NNE - . j Ra-226 - 1.92(10/10) Cb94 2.48(1/I) 2.241/I) 0 (1.06 2.48) 0.6 miles E - - 11208 - 0.36(10/10) Cbil 0.46(1/l) 0.46(1/l) 0 l (0.24 0.42) 16 miles S - - { i l e Hghest querlerfy mean ) I b Values exduded due to insufhesent semple volume couected c (T) Treated weg water semple or (U) Untreated weg water semple j 117 i 1
] TABLE B-3 fcont'd) i I j Medaan or Type of laser Lima AllIndicator Inearinn with Control Number of Pathway Sampled Analysis d locations: Highest Annual Mean laations: Nonroutine
- (Unit of Total Number Detection Name Reported Mean (f) Mean(f) Mean (f)
I M:asurement) Perfonned (11D) (Range) Distance and Direction (Range) (Range) Measurements l Colunm 1 Cohann 2 Column 3 Column 4 Column 5 Colune 6 Column 7 ) I TABLE EXPLANATIONS: Column 1: The Urut of Measurement desenbos all the numerical values for LLD, Mean and Range reported for a perhcular semple j medium. For example: the Gross Bete LLD in AIR PARTICULATES is 0.010 pCi/m 3 . Abtreviations used are: pC1/m 3 = j peocune per cubic meter of sempted air; mR/querter = exposure measured for miender quarter period; pCill = picocurle l . per iter of semple; pCilg = picocurie per gram of semple. I Cohamn 2: The Types of Analyses are described as follows: Gemme Spec = measurement of each radioisotope in a emmple using j Gemme Spectroscopy; Groes Betes and Groes Alphes = measurement of the radioactrnty in a semple by measurement of j omtted botes and alphes - no determination of individual radioisotopes is possible; Tntium = measurement of tntium (H-3) , is semple by liquid edntillebon counting method; TLD = direct measurement of gemme exposure using thermoluminescent j doesmeters. 3 Column 3: LLD reported is the highest of those reported for each of enelysis during the year; if all enetyees reported positive values, nu LLD is reported Column 4: Semples taken et Indcolor Locations during en operational radiological environmental monlloring program (REMP) q follably measure the quantites of any radioisotopes cycling through the pathways to men from the nucteer station. The 5 reported values are the meen or everage for the year of all semples of that type which had values grooter then the LLD. j T is the fredson of et the semples teken at all indiator locahone for the medium which reported values greater then the { LLD. Exemple: 7 results greater then LLD out of 15 semples taken would be reported 7/15. The Range is the values of I the lowest to lughest esmple results greater then LLD reported et all the indstor tomtions for that medium. I 4 Column 5: The Mean, f-frechon and Range along with the name of the loceton, detence from the CPS geoeous ofRuont eleck in , j miles, and the letter (s) nome of the compees sector in the direden of the semple lomtion from the CPS geoeous ofIluent eleck. The loaten with the fughest annual mean is compared to both indcator and control locations of the medium I Column 6: Controllocations are sited in areas with low relative depositen and/or deepersion lectors. Sample results are used as l reference for the controllomten. ) 3 Column 7: NRC Regulations (Branch Todinimi Positen, Rev.1, November ig7g) include a tobie of rodeisotope concentrations that, If exceeded by conlitmed compie measurements, indicate that a Nontouline Reported Meesurement exists. Such 4 measurements require further inveehgetion to validets the source. 3 i 1 t 5 i 1
}
j 118 i
e 4 e k e d i 4 APPENDIX C i i Glossary e he t d j i. I i l b b i i4 e 5 ? i 4 i 1 8 n 1 s J t i a 1 r Y d t t i a j 1 119 t 1
l i [ GLOSSARY ! activation - the process in which stable atoms become l l radioactive atoms by absorbing neutrons. -
- ALMtA - acronym for "As Low As Reasonably Achievable" which
- applies to many . facets of nuclear power, i.e., radiation exposure for personnel kept low, minimizes number / activity.of i effluent discharges.
alpha particle - a charged particle emitted from the nucleus of an atom having a mass and charge equal in magnitude to a helium nucleus which has two protons and two neutrons.. atem - the smallest component of an element having all the properties of that element. Comprised of protons, neutrons and electrons such that the number of protons determines the element. t background radiation - source of radiation that mankind has no control over, such as cosmic (from the sun) and terrestrial (naturally occurring radioactive elements). beta particle - a charged particle equivalent to an. electron if negative or a positron if positive, originating near the nucleus of an atos during radioactive decay or fission. i control location'- a sample collection location considered to be far enough away from Clinton Power Station so as not to be affacted by station operations. i cosmic radiation - penetrating ionizing radiation originating in outer space. curie (ci) - the unit of radioactivity equal to'2.2 trillion ; disintegrations per minute. , I dead unter - water that contains no tritium. dose - a quantity (total or accumulated) of ionizing
- radiation received.
dose equivalent - a quantity used in radiation. protection which expresses all radiations on a common scale for calculating the effective absorbed dose (the unit of dose equivalent is the res). ecology - a branch ' of biology dealing with the relations I
- between organisms and their environment. l J
120 ' i 1
i electromagnetic radiation - a traveling wave motion resulting from changing electric or magnetic fields. Familiar sources
- of electromagnetic radiation range from x-rays (and gamma rays) of short wavelength, through the ultraviolet, visible and infrared regions, to radar and radiowaves of relatively long wavelength. All electromagnetic radiation travels in a 1
vacuum at the speed of light. l , element - one of 103 known chemical substances that cannot be l broken down further without changing its chemical properties. environment - the aggregate of surrounding things, ! conditions, or influences. 2
- exposure - a measure of the ionization produced in air by x-ray or gamma radiation. Acute exposure is generally accepted to be large exposure received over a short period of time. Chronic exposure is exposure received over a long period of time.
fission - process by which an atomic nucleus splits into two smaller nuclei and releases neutrons and energy. fission products - the nuclei formed as part of the fissioning of an atomic nucleus. gassna rays - high energy, short wavelength electromagnetic radiation emitted from the nucleus. half-life - the time required for half of a given amount of a radionuclide to decay. indicator location - a sample collection strategically placed to monitor dose rate or radioactive material that may be the result of Clinton Power Station operations. ionization - the process Dy wnich a neutral atom or molecule acquires a positive or negative charge. irradiation - exposure to radiation. Lower Limit of Detection (LLD) - the smallest anount of sample activity that will give a net count for which there is a confidence at a predetermined level that the activity is present. I microcurie - one millionth of a curie and represents 2.2 million decays per minute. ) neutron - one of the three basic parts of an atom which has no charge and is normally found in the nucleus (center) of an atom. 121
1 't l l nucleus - the center of an atom containing ' protons and neutrons; determines the atomic weight and contributes to the
- net positive charge of an at.om. nuclei-(plural) i
\
j nuclides - atoms which all have the same atomic number and l mass number. ' periphyton - water plant life (i.e., algae). radiation - the process by which energy is emitted from a l i nucleus as particles (alpha, beta, neutron) or waves (gamma). radionuclide - a radioactive species of an atom characterized by the constitution of its nucleus. The nuclear constitution
- is specified by the number of protons, number of neutrons, and energy content.
rem - the unit of dose of any ionizing radiation that
- produces the same biological effects as a unit of absorbed
; dose of ordinary x-rays. Acronym for Roentgen Equivalent
- Man.
1 roentgen - a measure of ionization produced in air by x-ray or gamma radiation. i statistics - the science that deals with the collection, 3 classification, analysis and interpretation of numerical data ; by use of mathematical theories of probabilities. ! target tissue - any tissue or organ of the body in which i i radiation is absorbed. terrestrial radiation - source of radiation pertaining to the ground (Earth's crust). wind rose - a graphic representation indicating from which 4 direction and speed the wind blew. 4 x-rays - high energy, short wavelength electromagnetic radiation, emitted from the electron shells of an atom. 2 j l 122
N l 4
, 1 a
4 4 1 l i
- APPENDIX D 3
Teledyne 1994 EPA Intercomparison
- Results i
n 9 4 0 t
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) I I i a i e t ) i 4 4 i i l 1 e l 123
.. . , . . - .- ._ . , - - - - . _ - - . - . . . - . . . . . - ~ . . - - . . - - _ -
4 TABLE D-1 U. S. EPA CROSSCHECK PROGRAMa Concentration in pCl/l* Lab Sample Date . . TBEESML EPA Result' Code Type Collected Analysis Result 220' *10,N=1 Control Limits 1 81W-702 Noter Jan 1994 Sr-89 '20.011.7 25.015.0 16.3-33.7 , ar-90 14.011.0 15.015.0 6.3-23.7 81W-703 Water Jan 1994 Gr. Alpha 20.310.6 15.015.0 6.3-23.7 Gr. Beta- 55.313.2 62.0110.0 44.7-79.3 51W-704 Nater Feb 1994 I-131 110.012.7 119.0112.0 98.2-139.8 81W-705 Water Feb 1994 Ra-226 19.411.5 19.913.0 14.7-25.1 Ra-228 15.0t0.8 14.713.7 8.3-21.1 Uranima 9.710.4 10.113.'O' 4.9-15.3 81W-706 Water Mar 1994 E-3 4843.32231.2 4936.02494.0 407fe.9-5M 3.1_ _ 51W-707 Water Mar 19h Pu-239 28.210.9 27.612.8 22.7-32.5 j 81W-708 Nater Apr 19M Gr. Alpha 73.312.9 86.0122.0~ 47.8-124.2 Ra-226 16.911.2 20.013.0 14.8-25.2 Ra-228 19.710.7 20.115.0 11.4-28.8 Uranian 25.110.1 25.f,13.0 19.8-30.2 81W-709 unter Apr 1994 M0 20.310.6 20.015.0 11.3-28.7 Co-134 32.320.6 34.015.0 25.3-42.7 Co 137 31.310.6 29.025.0 20.3-37.7 i
- t. Beta 101.0110.5 117.0218.0 85.8-148.2 Sr-L9 15.011.7 '20.015.0 11.3-28.7 ar-90 14.310.6 14.015.0 5.3-22.7 ,
81W-710 Nater Jta 1994 En-133 87.320.6 98.0210.0 80.7-115.3 co-60 48.713.2 50.015.0 41.3-58.7 Co-134 35.012.7 40.015.0 31.3-48.7 Co-137 51.310.6 49.015.0 40.3-57.7 Ru-106* 184.716.7 252.0225.0 208.6-295.4 In-65 135.312.3 134.0113.0 111.4-156.6
- A letter fram the IPA was received with the report. It states, = 'Ehe maMation Quality Assurance ; Program has been egeriencing problems with Ru-106 currently used in the Perf- Evaluatica (75) Studies and the Standards DisWibution Program. If these problems een be satisfactorily resolved, this analyte will emos again be placed into this PE study. If the problems cannot be resolved, the Re-106 will be replaced. Fosmal written notice will be given to all participants in the Gauna in Watee PE study before the Ru-106 is !
reintrodnoed or ray 1=aad. At that time, new am1 h atica standards will be available to all participants in the Gauna in Water PE study. Toledyne will continue to monitor this situation, but at this time, plans to take no additional action. I t 124
i TABLE D-1 (Cont'd) ' l l l Lab Sample Date TBEESML EPA Result' Code Type Collected Analysis Result 320' *10,N=1 Control Limits m -711 Nater .7un 1994 Ita-226 15.010.4 15.012.3 11.0-19.0 Ra-228 14.810.3 15.413.9 8.6-22.2 Uranium. 45.710.2 52.615.3 43.4-61.8 l m -712 unter Jul 1994 ar-89 26.011.7 30.015.0 21.3-38.7 . Sr-90 18.710.6 20.015.0 -11.3-28.7. STW-713 Nater Jul 1994 Gr. Alpha 19.311.2 32.018.0 18.1-45.9 Gr. Beta 12.711.5 10.015.0 1.3-18.7 , M -714 Nater Aug 1994 E-3 10186.7166.6 9951.01995.0 8224.7-11677.3 8tAF-715 Air filter Aug 1994 Co-137 14.010.0 15.015.0 6.3-23.7 Gr. Alpha 29.311.2 35.019.0 19.4-50.6 Gr. Beta 56.010.0 56.0110.0 38.7-73.3 ' Br-90 18.011.0 20.015.0 11.3-28.7 m -716 Water Sep 1994 Ea-226 10.110.3 10.011.5 7.4-12.6 Ita-228 9.820.1 10.212.6 5.6-14.7 Uranium 31.911.8 35.023.0 29.8-40.2 l m -717 Milk sep 1994 Cs-137 61.310.6 59.015.0 50.9-67.7 1-131(g) 76.011.7 75.018.0 61.1-88.9 K-40 1770.0140.0 1715.0286.0 1565.8-1864.2 Cs-137 23.011.7 25.015.0 16.3-33.7 ! Sr-90 14.710.6 15.015.0- 6.3-23.7 STW-718 Water Oct 1994 I-131 81.313.1 79.018.0 61.5-92.9 l l STWW-721 Nater oct 1994 Gr. Alpha 47.014.6 57.0114.0 32.7-81.3 Gr. Beta 25.312.1 23.015.0 14.3-31.7 SIWW-722 Nater Nov 1994 Ba-133 67.710.6 73.017.0 60.9-85.1 co-60 58.311.2 59.015.0 50.3-67.7 co-134 20.012.0 24.015.0 15.3-32.7 Cs-137 46.711.2 49.015.0 40.3-57.7 En-65 93.710.6 100.0210.0 82.7-117.3
- 1tesults obtained by Telodyne's Midwest Laboratory as a participant in the. environmental sample crosscheck program operated by the Interoomparison and Calibration section, Quality ;
j Assurance Branch, Environmental Monitoring and Support Laboratory, U.S. Environmental } Protection Agency (EPA), Las Vegas Nevada. 1 I
- All results are in pCi/ liter, except for elemental Potassium (K) data in milk, which are in
- i. mg/ liters air filter samples which are in pci/ filters and food products which are in j mg/ kilogram.
125
TABLE D-1 (Cont'd) ; Lab Sample Date TBEESML EPA Result' Code Type Collected Analysis Result 32a* *10,N=1 Control Limits
- Unless otherwise indicated, the Telodyne results are given as the mean 12 standard deviations for three determinations.
d U.S. EPA results are presented as the known values and expected laboratory precision (1s, 1 determir.ation) and control limits are defined by the EPA. i t s 1 126
l a i i 4 TABLE D-2 TLD crosscheck Results (mR) - Teledyne
; Lab TLD Results Known Average *2a Code Type Date Measurement 32o Value 32o ~ (All Participants)
I 94-1 Tmledyne Nov 1994 Lab 1 15.610.4 14.9 10 j LiF-100 Chips 4 94-1 Teledyne Nov 1994 Lab 2 30.210.4 29.8 10 i LiF-100 Chips 4 94-1 Teledyne Nov 1994 Lab 3 59.210.3 59.7 10 1 LiF-100 I Chips 1 94-1 Toledyne Nov 1994 Reader 1 14.910.1 14.9 10 j Caso4 Dy #1 me 94-1 Teledyne Nov 1994 Reader 1 30.810.1 29.8 10 {j Caso4 Dy #2 l l Cards i l M-1 Telodyne Nov 1994 Reader 1 58.920.3 59.7 10 i CaSo4 Dy #3 Cards < l l l'- 94-1 Teledyne Nov 1994 Reader 2 15.410.2 14.9 10 , 4 Caso4 Dy #1 )
- cards 1
j 94-1 Teledyne Nov 1994 Reader 2 31.410.2 29.8 10
- Casos Dy #2 I Cards
+ 1 94-1 Teledyne Nov 1994 Reader 2 60.110.3 59.7 10 j Caso4 Dy #3 i Cards i , M>-Bo Detal Teledyne testing was caly perfonned by Toledyne. ' Cards were irradiated by Teledyne Isotopes Inc., Westwood, New Jersey, in November, 1994. i + l 127 i 1
a- a + s A - - u -w. t 5 l 1 I I; i l 1 I l f f l
t l l 4 l 1 1 i l APPENDIX E l l CPS Radiological Environmental Monitoring i Results During 1994 l 1 l i l a 129
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I i TABLE E-1 ) GROSS BETA AND IODINE-131 ACTIVITY l IN AIR PARTICULATES FOR 1994a (pCi/m312a) DATE COLLECTED CL-1 CL-2 CL-3 CL-4 CL-6 01/05 0.022 e 0.003 0.027 e 0.004 0.025 e 0.003 0.029 a 0.004 0.027 e 0.003 01/12 0.031 e 0.004 0.031 e 0.004 0.033 e 0.004 0.028 m 0.003 0.033 e 0.004 01/20 0.034 e 0.004 0.032 e 0.003 0.041 e 0.004 0.032 e 0.003 0.038 e 0.004 01/26 0.030 e 0.004 0.027 e 0.004 0.032 a 0.004 0.030
- 0.004 0.028 e 0.004 02/02 0.022 e 0.003 0.018 e 0.003 0.023 e 0.003 0.022 e 0.003 0.026 e 0.003 02/10 0.023 e 0.004 0.020 s 0.003 0.026 e 0.003 0.023 a 0.003 0.028 e 0.004 02/16 0.019 e 0.003 0.022 e 0.004 0.023 e 0.004 0.018 e 0.004 0.024 e 0.004 02/23 0.020 e 0.003 0.019 e 0.003 0.028 e 0.004 0.023 a 0.003 0.027 g 0.003 03/02 0.022 a 0.003 0.021 0.003 0.019 e 0.003 0.021 e 0.003 0.022 e 0.003 03/09 0.020 s 0.003 0.020 s 0.003 0.024 a 0.003 0.026 e 0.003 0.024 e 0.003 03/16 0.023 a 0.003 0.020 a 0.003 0.023 e 0.003 0.018 e 0.003 0.021 e 0.003 03/23 0.015 e 0.003 0.018 e 0.003 0.018
- 0.003 0.014 e 0.003 0.014
- 0.003 03/30 0.014 e 0.003 0.016 e 0.003 0.012 a 0.003 0.014 e 0.003 0.017
- 0.003 04/06 0.016 e 0.003 0.017 e 0.003 0.015
- 0.003 0.017 e 0.003 0.017 e 0.003 04/13 0.011 e 0.003 0.010 e 0.002 0.012a 0.003 0.011 a 0.002 0.011 a 0.002 )
04/20 0.011 a 0.003 0.011 0.003 0.011e 0.003 0.011 a 0.003 0.012 a 0.003 l 0.016 e O'.003 ! 04/27 0.018 e 0.003 0.016 e 0.003 0.016 e 0.003 0.018 e 0.003 05/04 0.006 e 0.003 0.007 e 0.003 0.008 e 0.003 0.008 e 0.003 0.007 e 0.003 05/11 0.010 s 0.003 0.017 e 0.003 0.015 e 0.003 0.013 a 0.003 0.013 e 0.003 05/18 0.008 e 0.002 0.011 0.002 0.011 e 0.002 0.010 e 0.002 0.012 a 0.003 05/25 0.014 e 0.003 0.014 e 0.003 0.015 e 0.003 0.015 e 0.003 0.015 0.003 06/01 0.016 e 0.003 0.014 e 0.003 0.014 e 0.003 0.017 e 0.003 0.015 e 0.003 ' 06/08 0.013 e 0.003 0.015 e 0.003 0.015 e 0.003 0.014 e 0.003 0.015 e 0.003 ) 06/15 0.013e 0.003 0.016 e 0.003 0.017 e 0.003 0.017 e 0.003 0.017 e 0.003 06/22 0.023 e 0.003 0.023 a 0.003 0.023 e 0.003 0.022 a 0.003 0.027 e 0.003 06/29 0.014 a 0.003 0.022 a 0.003 0.016 e 0.003 0.019 e 0.003 ND 07/06 0.021 e 0.003 0.022 e 0.003 0.019 e 0.003 0.019 0.003 0.021 e 0.003 07/13 0.013 e 0.002 0.012 a 0.002 0.015 e 0.003 0.012 s 0.002 0.012 e 0.002 07/20 0.017 e 0.003 0.018 3 0.003 0.021 e 0.003 0.021 e 0.003 0.019 e 0.003 07/27 0.013 a 0.003 0.014 e 0.003 0.017 e 0.003 0.016 e 0.003 0.015 e 0.003 08/03 0.018 e 0.003 0.016 e 0.003 0.021 e 0.003 0.016 e 0.003 0.018 e 0.003 1 l 08/10 0.011 e 0.003 0.015 e 0.003 0.014 e 0.003 0.014 e 0.003 0.015 e 0.003 08/17 0.017 e 0.003 0.023 e 0.003 0.021 e 0.003 0.021 a 0.003 0.023 e 0.003 08/24 0.020 s 0.003 0.023 e 0.003 0.027 e 0.003 0.025 m 0.003 0.024
- 0.003 08/31 0.025 e 0.003 0.026 e 0.003 0.025 e 0.003 0.025 e 0.003 0.023 e 0.003 09/07 0.014 e 0.003 0.015 e 0.003 0.016 e 0.004 0.016 m 0.003 0.015 e 0.003 09/14 0.029 e 0.004 0.036 e 0.004 0.033 e 0.003 0.031 e 0.004 0.035 e 0.004 09/21 0.019 e 0.003 0.024 a 0.003 0.028 e 0.003 0.024 e 0.003 0.024 e 0.003 09/28 0.018 e 0.003 0.013 e 0.003 0.019 e 0.003 0.016 e 0.003 0.015 e 0.003 10/05 0.017 e 0.003 0.018 e 0.003 0.018 e 0.003 0.019 e 0.003 0.016 e 0.003 10/12 0.022 a 0.003 0.023 e 0.003 0.022 e 0.003 0.023 a 0.003 0.023 e 0.003 131
- . - . . _~ _ . . . - . . . --
l 4 l f TABLE E-1 iCont'd) 4 DATE ) COLLECTED CL-7 CL-8 CL-11" CL-15 CL-94 1 01/05 0.023 e 0.003 0.025 e 0.003 0.024 a 0.003 0.025 e 0.003 0.026 e 0.003 . ) 01/12 0.027 e 0.003 0.031 a 0.004 0.029 a 0.004 0.031 a 0.004 0.021e 0.003 { 01/20 0.028 e 0.003 ' O.031 e 0.003 0.033 e 0.003 0.036 e 0.004 0.034 e 0.003 [ 01/26 0.025 a 0.004 0.026 e 0.004 0.030 e 0.004 0.025 e 0.004 0.034 e 0.004 { 02/02 0.017 e 0.003 ' O.020 a 0.003 M) 0.023 a 0.003 0.019 e 0.003
- 02/10 0.021 : 0.003 -0.023 2 0.003 0.023 a 0.003 0.021 a 0.003 0.024 a 0.003 l 02/16 0.017 a 0.004 0.023 a 0.003 0.021 a 0.004 0.020 a 0.004 ' O.022 a 0.004 02/23 0.019 a 0.003 0.024 a 0.004 0.021 a 0.003 0.024 a 0.003 0.024 e 0.003 ;
j 03/02 0.016 m 0.003 0.023 a 0.003 0.017 a 0.003 40.019 a 0.003 - 0.020 a 0.003 03/09 0.023e 0.003 0.024 e 0.004 0.020 a 0.003 0.023 e 0.003 0.024 a 0.003
'03/16 0.022 a 0.003 0.020 e 0.003 0.017 e 0.003 0.022 e 0.003 0.021e 0.003 03/23 0.009 m 0.003 0.014 a 0.003 0.015 e 0.003 0.017 e 0.003 0.017 e 0.003 -
03/30 0.013 a 0.003 0.015 e 0.003 0.018 e 0.003 0.017 e 0.003 - 0.016 e 0.003 04/06- 0.015 a 0.003 0.015 e 0.003 0.015 e 0.003 . 0.014 e 0.003 0.017e 0.003 04/13 0.009 a 0.002 0.010 e 0.002 0.013 e 0.003 0.013 a 0.003 0.011e 0.003 04/20 0.009 a 0.003 0.011 a 0.003 0.014 a 0.003 0.012 a 0.003 0.012 a 0.003 04/27 0.027 e 0.003 0.015 a 0.003 0.017 a 0.003 0.016 a 0.003 0.019 a 0.003 05/04 0.004 a 0.002 0.007 a 0.003 0.006 a 0.003 0.005 a 0.002 0.006 a 0.003 05/11 0.012 2 0.003 0.013 a 0.003 0.013 a 0.003 0.015 a 0.003 0.016 a 0.003 05/18 0.006 a 0.002 0.010 a 0.002 - 0.012 a'0.002 0.010 e 0.002 0.009 s 0.002 05/25 0.010 a 0.002 0.014 e 0.003, 0.012 e 0.003 0.013 's 0.003 0.014 e 0.003 06/01 0.012 s 0.003 0.014 a 0.003 0.015 e 0.003 ' O.013 e 0.003 0.013a 0.003 06/08 0.009 e 0.002 0.014 e 0.003 0.018 e 0.003 0.012 a 0.003 0.013 e 0.003 06/15 0.013e 0.003 0.017 e 0.003 0.018 e 0.003 0.017 e 0.003 0.015 e 0.003 - 06/22 ND 0.020 a 0.003 0.024 s 0.003 0.019 e 0.003 ' O.017 e 0.003 06/29 0.018 a 0.003 0.018 a 0.003 0.019 a 0.003 ' O.021 a 0.003 0.016 a 0.003 07/06 0.013 2 0.003 0.018 2 0.003 0.020 a 0.003 0.019 a 0.003 0.023 a 0.003 07/13 0.010a0.002 0.013 a 0.002 0.013 a 0.002 0.012 e 0.002 ' O.012 a 0.002 07/20 0.013 a 0.003 0.020 a 0.003 0.020 a 0.003 0.017 a 0.003 0.012 a 0.003 07/27 0.012 a 0.002 0.018 a 0.003 0.017 a 0.003 0.015 a 0.003 0.016 a 0.003 08/03 0.016 a 0.003 0.017 m 0.003 0.017 a 0.003 0.017 a 0.003 0.017a 0.003 08/10 0.013 e 0.003 0.014 e 0.003 0.011 e 0.003 0.013 e 0.003 0.014 a 0.003 08/17- 0.013 e 0.002 0.022 a 0.003 0.019 a 0.003 0.020 e 0.003 0.020 e 0.003 l 08/24 0.017 e 0.003 0.024 a 0.003 0.021 e 0.003 0.025 e 0.003 0.020a 0.003 ] 08/31 0.017 e 0.003 0.025 e 0.003 0.021 a 0.003 0.023 e 0.003 0.024 a 0.003 09/07 0.009e 0.003 0.015 e 0.003 0.015
- 0.003 0.017 e 0.003 0.014 e 0.003 09/14 0.026 a 0.004 0.035 e 0.004 0.029 e 0.004 0.031 a 0.004 0.033a 0.004 09/21 0.022 a0.003 0.024 a 0.003 0.023* 0.003 0.017 a 0.003 0.026 a 0.003 09/28 0.013 a 0.003 0.016 e 0.003 0.015 a 0.003 - 0.015 a 0.003 0.016 e 0.003 10/05 0.016 a 0.003 0.015 a 0.003 0.018 e 0.003 0.017 a 0.003 0.018 a 0.003 10/12 0.016 e 0.003 0.020 e 0.003 0.020
- 0.003 0.020 a 0.003 0.023 a 0.003 132 I
l l I
, _ . . . - . - ~ .. .. ~ .. . . . . . - -
1 li i i. t i TABLE E-1 (Cont'd) .i 4 DATE COLLECTED ~CL-1 CL-2 CL-3 CL-4 CL-6 l 10/19 0.015 m 0.003 0.015 e 0.003 0.019 e0.003 0.019e 0.003 0.019 e0.003 , '; 10/26 - 0.020 e 0.003 0.023e 0.003 0.023 e0.003 0.023e 0.003 0.023 e0.003 l 11/02 0.0154 0.003 0.019 e 0.003 0.019 e0.003 0.015e 0.0L. 'O.017 e0.003 l 11/09 0.020 e 0.003 0.021 e 0.003 0.021 e0.003 0.022a 0.003 0.021 e 0.003 .l 11/16 0.019 e 0.003 0.019 e 0.003 0.020 a0.003 0.018e 0.003 0.018 e0.003 { 11/23 0.022 e 0.003 0.028e 0.003 0.021 ec.003 0.021e2 003 0.021 0.003 .t 11/30 0.017 e 0.003 0.021e 0.003 'O.025 e0.003 0.023e 0.003 0.021 a0.003' > 12/07 0.019e 0.003 0.024 e 0.003 0.029e0.003 0.025e 0.003" 0.023 a0.003 ; 12/14 0.039 e 0.004 0.039 e 0.004 0.037 e0.003 0.043e 0.004 0.040 a0.004 ! 12/21 0.038 e 0.004 0.039 e 0.004 0.042 e 0.004 0.048e 0.004 0.043 e0.004 , 12/28 0.029 e 0.003. 0.025 e 0.003 0.030 e 0.003 0.030s 0.003 0.028 e0.003 DATE COLLECTED CL CL-8 CL-11* CL-15 CL-94 .s 10/19 0.014 e 0.003 0.018 e 0.003 0.017 e 0.003 0.019 e 0.003 0.018e 0.003 10/26 0.018 e 0.003 0.019 e 0.003 0.021e 0.003 0.023e 0.003 0.025e 0.003 l 11/02 0.015 e 0.003 0.017 e 0.003 0.018e 0.003 0.015e 0.003 0.020e 0.003 j 11/09 E 0.017 e 0.003 0.022 e 0.003 0.020e 0.003 0.022a 0.003 ' 11/16 0.026 e 0.004 0.015 e 0.003 0.020e 0.003 0.019e 0.003 0.016e 0.003 11/23 0.022 a 0.003 0.022 s'0.003 0.022 a 0.003 0.022e 0.003 0.023a 0.003 11/30 0.021 e 0.003 0.021 a 0.003 0.021 s 0.003 0.019e 0.003 0.018e 0.003 , 12/07 0.019 e 0.003 0.024 a 0.003 0.027e 0.003 0.022e 0.003' O.025e 0.003 12/14 0.034 e 0.004 0.039 e 0.004 0.038 e 0.004 , 0.039e 0.004 0.040e 0.004 l 12/21 0.038 e 0.004 0.039 e 0.004 0.038 e 0.004 0.041e 0.004 0.047e 0.004 ! 12/28 0.025 e 0.003 0.027 e 0.003 0.024 a 0.003 0.026 e 0.003 0.027e 0.003 l l a all I-131 activity is <0.07 pci/m3 b control loostion, all other looeticos are indicators E No Data 133
l TABLE E-2
]
1 GAMMA ISOTOPIC ACTIVITY IN AIR PARTICULATES FOR 1994 ' (pCi/m'*20) SITE ISOTOPE 1" OTR 2* OTR 3* 0TR 4* QTR CL-1 Be-7 0.07310.015 ' O.087AO.015 0.072*0.014 0.067*0.010 K 40 <0.036 <0.026 <0.029 <0.025 Co 60 <0.0007 <0.0003 4.0003 <0.0009 Nb-95 <0.0004 <0.0006 <0.0010 <0.0004 Zr-95 <0.0009 <0.0009 <0.0012 <0.0013
- Ru-103 <D.0004 <0.0009 <0.0012 <0.0010 Ru-106 <0.0030 <0.0029 <0.0062 <0.0026 Cs-134 <0.0005 <0.0005 <0.0003 <0.0003 . ,
Cs-137 <0.0003 <0.0007 <0.0008 <0.0003 Ce-141 <0.0014 <0.0013 <0.0016 <0.0014 Cc-144 <0.0041 <0.0022 <0.0053 .<0.0 N 2 CL-2 Be-7 0.091*0.015 0.098*0.018 0.091*0.015 0.067*0.011 K 40 <0.037 <0.026 <0.028 <0.023 Co-60 <0.0004 <0.0006 <0.0004 <0.0008 Nb-95 <0.0006 <0.0005 <0.0018 .<0.0004 Zr-95 <0.0006 <0.0005 <0.0005 <0.0008 ' Ru-103 <0.0006 <0.0012 <0.0005 <0.0005 Ru-106 <0.0088 <0.0054 . <0.0056 <0.0033
.Cs-134 <0.0005 <0.0003 <0.0006 <0.0009 ,
Cs-137 <0.0007 . <0.0008 <0.0007 <0.0006 Cc-141 <0.0008 <0.0028 <0.0008 <0.0015 Cc-144 <0.0062 <0.0032 <0.0025 <0.0041 CL-3 Be-7 0.083*0.016 0.107*0.011 0.093*0.015- 0.072*0.011 K 40 <0.042 <0.018 <0.028 <0.023 Co 60 <0.0004 <0.0005 <0.0003 . <0.0008 Nb-95 <0.0004 <0.0010 - <0.0009 <0.0007 Zr-95 <0.0006 <0.0011 <0.0005 <0.0011 Ru-103 <0.0006 <0.0009 <0.0010 <0.0004 Ru-106 <0.0034 <0.0045 <0.0057 <0.0058 Cs-134 <0.0006 <0.0003 <0.0006 <0.0002 ' Cs-137 <0.0006 <0.0006 <0.0004 <0.0004 l Cc-141 <0.0014 <0.0012 <0.0015 <0.0010 ! Cc-144 <0.0027 <0.0042 <0.0042 <0.0035 l l l 134 j i l
TABLE E-2 (Cont'd) Sl7E ISOTOPE 1"0TR 2* QTR 3" QTR 4" QTR CL-4 Be-7 0.086*0.016 0.104*0.023 0.096*0.014 0.069*0.010 K 40 <0.037 <0.028 <0.027 <0.023 Co 60 <0.0004 <0.0004 <0.0006 <0.0003 Nb-95 <0.0006 ~ <0.0007 <0.0006 <0.0005 Zr-95 <0.0006 <0.0014 <0.0008 <0.0012 Ru-103 <0.0004 <0.0005 <0.0008 - <0.0011 Ru-106 <0.0054 <0.0057 <0.0032 <0.0046 Cs-134 - <0.0004 <0.0005 <0.0007 <0.0004 Cs-137 <0.0009 <0.0006 <0.0005 <0.0003 Ce-141 <0.0007 <0.0016 <0.0010 <0.0010 Cc-144 <0.0038 <0.0049 <0.0054 <0.0042 CL-6 Be-7 0.068i0.015 0.114*0.020 0.083*0.014 0.068*0.009 K 40 <0.037 <0.029 < 0.028 <0.018 Co 60 <0.0004 <0.0006 < 0.0003 <0.0007 Nb-95 <0.0006 <0.0013 <0.0009 <0.0007 Zr 95 <0.0013 <0.0007 <0.0007 <0.0012 Ru 103 <0.0004 <0.0007 <0.0009 <0.0008 Ru 106 <0.0025 <0.0053 <0.0046 <0.0021 Cs-134 <0.0006 <0.0008 <0.0003 <0.0004 Cs-137 <0.0005 <0.0007 <0.0005 <0.0004
- Ce 141 <0.0012 <0.0016 <0.0012 <0.0007
.! Cc-144 <0.0028 <0.0030 <0.0032 <0.0026 CL-7 Be-7 0.075*0.014 0.070*0.016 0.060*0.012 0.061*0.011 K-40 <0.036 <0.026 <0.022 <0.025 i Co-60 <0.0004 <0.0005 <0.0004 <0.0010 Nb-95 <0.0005 <0.0011 <0.0006 <0.0011 4 Zr-95 <0.0024 <0.0005 <0.0014 <0.0006 1 Ru 103 <0.0006 <0.0008 <0.0009 <0.0005 i Ru-l% <0.0083 ' <0.0069 <0.0057 <0.0025 i
- Cs-134 <0.0005 <0.0006 <0.0005 n,.Joo, L Cs-137 <0.0003 <0.0006 <0.0005 <0.0005
- Cc-141 <0.0012 <0.0011 <0.0016 <0.0015 4
Cc 144 <0.0045 <0.0053 <0.0040 <0.0038 CL-8 Be-7 0.067*0.014 0.102*0.018 0.073*0.014 0.074*0.010 i K-40 <0.037 <0.026 <0.028 <0.023 l Co 60 <0.0004 <0.0009 <0.0007 <0.0008 l M-95 <0.0004 <0.0011 <0.0008 <0.0007 l Zr-95 <0.0011 <0.0012 <0.0012 <0.0005 1 Ru-103 <0.0004 <0.0009 <0.0009 <0.0007 I Ru-106 <0.0026 <0.0029 <0.0040 <0.0051 Col 34 <0.0004 <0.0003 <0.0004 <U.0003 Cs 137 <0.0006 <0.0008 <0.0004 <0.0007 Cc-141 <0.0017 <0.0028 <0.0012 <0.0007 i
- Cc 244 <0.0044 <0.0048 .<0.0045 <0.0042 i i
135 l
TABLE E-2 (Cont'd) SITE ISOTOPE 1" QTR 2* OTR 3" QTR 4* OTR CL 11 Be-7 0.098*0.018 0.114*0.017 0.076*0.013 0.077*0.012 K-40 <0.040 <0.025 <0.028 <0.023 Co40 <0.0006 <0.0004 <0.0004 <0.0008 2-95 <0.0010 <0.0006 <0.0008 ' <0.0004 Zr-95 <0.0012 <0.0011 <0.0005 <0.0007 Ru-103 <0.0009 <0.0010 <0.0008 <0.0009 Ru 106 <0.0088 <0.0064 <0.0049 <0.0027 Cs-134 <0.0004 '<0.0005 <0.000.3 <0.0004 Cs-137 <0.0005 <0.0007 <0.0004 <0.0005 Ce-141 <0.0010 <0.0009 <0.0015 <0.0011 Ce 144 <0.0059 <0.0042 <0.0045 <0.0030 CL-15 Be-7 0.071*0.016 0.080*0.024 0.077*0.019 0.064*0.010 K-40 <0.037 S <0.025 <0.028 <0.023 Co-60 <0.0004 <0.0010 <0.0003 <0.0010 - Nb-95 <0.0008 <0.0006 <0.0006 <0.0007 Zr-95 <0.0007. <0.0011 <0.0007 <0.0009 Ru 103 4.0005 <0.0006 <0.0017 <0.0005 Ru-106 <0.0064 <0.0022 <0.0048 <0.0058 Cs-134 4.0005 <0.0003 - <0.0003 <0.0004 Cs-137 <0.0005 <0.0007 <0.0008 <0.0005 Ce-141 <0.0012 <0.0022 <0.0017 <0.0015 Cc-144 <0.0036 <0.0054 <0.0038 <0.0044 CL-94 Be 7 0.080*0.014 0.109*0.018 0.072*0.015 0.070*0.014 K-40 <0.037 <0.025 <0.028 <0.023 Co-60 <0.0007 <0.0005 <0.0003 <0.0009 Nb-95 <0.0009 <0.0007 <0.0008 <0.0009 Zr 95 <0.0016 <0.0009 <0.0014 <0.0010 Ru-103 <0.0006 <0.0005 <0.0008 <0.0008 Ru-106 <0.0046 <0.0069 <0.0050 <0.0051 Cs-134 <0.0004 <0.0004 <0.0005 ' <0.0003 Cs-137 <D.0006 <0.0007 <0.0004 <0.0005 Cc-141 <0.0009 <0.0018 <0.0009 <0.0010 Ce.144 <0.0033 <0.0049 <0.0051 <0.0046 e 136
TABLE E-3 1994 CPS REMPOUARTERLYTLD RESULTS (mR/ quarter Net Exposure) Imcation 1" OTR 2* OTR 3' OTR 45 OIR CL-1 173103 18.9io.2 175i0.2 183*0.2 Cb2 17.8*0.2 18.0t0.2 18.7 0.2 18.810.2 CL-3 17.410.3 16.6*0.3 17.610.2 17.110.2 Cb4 17.4i0.2- 15.7i0.2 173i0.2 15.5i0.2 Cb5 18.4i03 185to.2 19.8io.2 17.9i03 CL-6 14.7*0.2 15.7*0.2 15.8i0 3 15.2-0.2 Cb7 16.5i0.2 163i0.2 18.0 0.2 16.7i0.2 Cb8 165i0.2 15.6i0.2 17.7*0.2 153i0.4 CL-11 15.910.2. 15.7i0.2 17.2i0.2 15.7i0.2 CL-15 14.0io.2 153i0.2 14.7*0.2 - 15.0iO5 CL-20 20.110.2 19.7i0.2 21.0i0.2 19.5i0.2 Cb21 20.0i0.4 18.5i0.2 20.9i0.4 18.910.2 Cb22 18.7i0.3 16.9t0.3 20.0*0.2 17.1*0.2 Cb23 14.7io.3 14.li0.2 15.li0.3 14.8i0.2 CL-24 17.9i0.2 16.8to.3 19.4i0.2 17.4i0.2 C b25 14.4i03 14.4i0.2 15.0i0.2 14.2i0.2 C b26 16.4*0.2 15.2io.3 . 16.7io.2 15.5i0.3 C b27 173iO3 16.4i0.2 18.2i0.2 15.8iO3 CL-28 17.0i0.2 18.110.2 18.0io.2 18.0i0.2 Cb29 18.2i0.3 18.4i0.2 19.110.2 18.8i0.2 CL-30 16.6to.2 183io.2 19.7i0.2 18.210.2 CL-31 14.0i0.2 16.lio.2 15.2i0.2 16310.2 CL-32 15.1t0.4 163i0.2 17,4i0.2 17.0i0.2 Cb33 18.6103 18.8i0.2 20 3i0.3 17.9i0.2 CL-34 17.9to.2 19.2io.2 20.7*0.2 19.4i0.3 CL-35 17.110.2 16.010.2 18.7i0.2 155i03 Cb36 16.5i0.2 17.8i0.2 185i0.2 17.6i0.2 Cb37 17.8103 16.8io.3 18.7t0.3 18.0i0.2 CL-38 17.8i03 20.010.7 19.0i0.2 18.7i0.3 CL-39 17.610.2 17.1103 17.8iO3 173i0.2 CL-40 17.8 0.2 16.9t0.2 17.510.2 185i03 C b41 18.6i0.2 18.0i0.2 20.li0.2 17.6*0.2 C b42 17.7*03 16.0io.2 20.0io.2 16.7i0.2 Cb43 18.6i03 185io.2 20.lio.2 20.1*0.2 Cb44 18.4i0.2 18.6i0.2 20.410.2 19.7i0.2 Cb45 195*0.4 18.810.2 21.9t0.2 '21.5i0.2 CIA 6 16.8iO3 . 17.0io.2 18.0t03 185i0.2 CL47 183i03 18.110.2 20.0t0.2 19.8i0.5 Cb48 17.8i03 18.0io.2 - 18.2i0.2 18.810.2 CIA 9 19.4103 18.6*03 20.2*0.2 ' 19.710.5 CL-50 193i0.3 18.6*03 19.910.2 19.9*0.4 Cb51 18.010 3 18.6i0.2 19.0*0.2 19.710.2 CL-52 18.6*0.2 183s0.2 193i0.2 19.1i0.3 CL-53 17.4i0.2 16.7i0.2 18.810.2 18.410.2 137 i_ _ _ _ _ _ _ _ _ _ _ _ . _ _ _ . . . _ _
'i TABLE E-3 (Cont'd)
Location 1" OTR 2* OTR 3"'OTR 4'" OTR Cb54 18.110.3 18.910.2 19.0*0.2 17.6*0.2 CL-55 18.lio.3 19.210.3 195f0.6 19.9i0.4 CL56 18.9*03 19.0i0.2 193*0.2 20.110.4 CL 18.710.2 153i0.2 ' 20.010.2 17.9to.2 Cb58 18.810.2 175*0.2 19.9i0.2 19.2i0.2 CL 19.0io.2 18.910.2 21.4t0.2 20.710.2-CL-60 18.2io.2 18.410.2 1 21.9*0.2 20.1*03 CL-61 18.7 0.2- 19.0io.2 20.410.2 20.110.2 Cb62 19.0i0.4 18.4i0.2 20.110.3 19.lio.'4 CL-63 ' 193i03 19.7i0.2 21.410.2 20.210.2 CIA 4 18.6i0.2 20.4i0 3 19.9i0.2 _193*03 CL45 19.410.2 20.0i0.2 22.110.2 19.6i0.5 CL.66 14.8i03 15.7i0.2 16.0iO3 15.7103 CL-67 17.8i0.2 17.8i0.2 20.li0.3 18.4t03 CL 68 153103 18.li0.2 183i0.2 18.4103 CL-69 163io.2 16.110.3 -18.4i0.2 17.4i0.2. CL-70 17.9*0.2 16.4t0.3 19.1i0.2 183t0.2 C b71 -17.710.2 173t0.2 17.2i0.2 17.5i0.2 Cb72 17.7i0.2 NDa 195i0.2 18.410.2 CL-73 19.410.3 18.910.4 21510.2 21310.2 CL-74 17.0t0.2 18.4i03 19.9i0.2 19.liOJ CL-75 18.6i0.2 18.210.2 20.4i0.2 20.0i0.4 C b76 15.5i0 3 19.0*0.2 203i03 20.1*03 - CL-77 17.3i0.2 NDa 18.210.2 18.5i03 CL-78 17.4i0.3 18.9i0.2 19.8i0.2 21.4i0.2 CL-79 17.710.2 18.4i03 20.2i0.4 18.9103 CL-80 19.4iO3 17.8i0.2 22.7*0 3 183io.3 Cb81 18310.2 20.0i0.3 205i03 20.8i0.2 Cb82 18.2io.2 16.6i03 203*03 18.li0.3 CL-83 205f0.2 19.8i0.2 23.0i0.2 202iO3 CL-84 17.9i0.2 16.4103 18.7 0.2 17.6io.3 Cb85 195103 18.2A03 22.lio.2 20.4i0 3 Cb86 17.7 0.2 15.9i0.2 17.6i0.2 16.9*03 CL-87 16.9i0.2 18.1i03 19.2103 19.8i0.2 Cb95 18.2103 19.0i0.2 20.1*0.2 185i03-CL-% 16.9i0.2 16.0t03 175t0.2 16.1t0.4 i Cb97 -185i0.2 16.7iO3 19.9i0.2 18.4i0.2 j Cb109 15.0iO3 16.410.3 16.1*0.2 16.010.2 Cb110 18.0f0.2 17.4i0.2 19.6i03 17.7103 - C b111 20.0i0.3 20.0103 22.1i0.5 19.610.5
- CL-112 . 17.7i0.2 16.6i0 3 18.4*03 16.010.2 CL-113 18310.2- 16.910.2 20.4i0.2 17.1103-l a ND = No data; lost in the field. l
? 4 138 1
E l . TABLE E-4 , l SURFACE WATER BETA AND GAMMA ISCrrOPIC ACTIVITY (pCi/l) - CL-9 Date Collected 01-26-94 02-23 94 03-30 94 04-27-94 05-25-94 06-29-94 Gross Beta 5.6i0.9 23i0.6 2.9i0.7 2.7i0.7 <1.1 2.6i0.4 Be-7 <16.7 - <10.9 -<13.4 <17.7 <20.2 <17.9 , l K-40 <34.8 <32.6 <20.6 <27.2 <343 <32.7 Mn-54 <2.2 <1.0 <1.2 <1.6 <1.6 <2.2 Fe-59 <4.2 <2.4 <2.1 <3.4 <3.2 <1.9 Co-58 <1.0 <2.0 <1.1 <2.1 <1.6 <1.1 Co.60 <1.0 <2.4 <1.2 - <1.1 <2.2 <1.8 : Zn-65 <2.2 <33 <1.6 <1.8 <3.7 <2.0 Nb-95 <1.7 <1.5 <1.5 <23 <1.6 <2.7 Zr-95 <2.6 <3.4 <2.6 <3.4 <3.1 <1.9 Cs-134 <1.7 <2.1 <1.4 <2.1 <1.0 <1.7 Cs-137 <2.0 <2.1 <1.6 <2.1 <1.2 <23 Ba-140a <8.4 <4.9 <4.6 <3.6 <6.9 <6.3 La-140a <1.0 <2.2 <1.4 <1.3 <2.1 <2.1
- Ce-144 <18.5 <20.1 <21.9 <30.1 <20.0 <113 Q&,,, Collected 07-27-94 08-31-94 09-28-94 10-26-94 11-30 94 12-28-94 Gross Beta 2.510.6 3.010.6 2.0i0.7 2.910 5 2.510.6 2.6i0.6 Be-7 <14.8 <20.9 <21.9 <24.1 <133 <8.8 K-40 <26.1 <34.9 <32.4 - <43.0 <44.4 <24.4 Mn-54 <0.9 <23 <2.4 <2.8 <2.0 <8.8 Fe-59 <3.6 <3.6 <4.8 <5.1 <2.5 <2.6 Co-58 <1.7 <2.3 <1.9 <23 <1.8 <0.7 Co-60 <1.9 <2.1 <2.4 <2.3 <2.2 <1.1 Zn-65 <3.5 <3.3 <1.9 <4.6 <3.8 <23 Nb-95 <13 <2.6 <1.9 <3.7 <2.6 <1.7 Zr-95 <2.4 <3.5 <2.0 <3.8 <4.6 <2.0 -
Cs-134 <2.2 <1.4 <2.4 <3.2 <1.2 <1.3 Crr.137 <2.1 <1.8 <13 <3.3 <2.0 <0.8 Ba-140s <5.6 <8.7 <4.7 <5.9 <5.7 <4.7 La-140a <1.4 <2.1 <2.4 <2.4 <1.6 <1.5 Ce-144 <14.5 <16.1 <31.8 <12.1 <14.6 <23.7 I LLD at time of counting. 139
TABLE E-5 SURFACE WATER BETA AND GAMM A ISOTOPIC ACrlVITY (pCi/l) - CL-10 ( control) Date Collected 01-26-94 02-23-94 03-30-94 04-27-94 05-25-94 06-29-94 Gross Beta 32io.7 1.910.6 1.6i0.6 2.lio.7 2.510.8 2.810.4 Be-7 <15.9 <9.6 <9.1 <12.7 <28.0 <11.9 K-40 <29.0 <323 <26.6 <17.5 <43.0 <31.5 Mn-54 <2.2 <1.9 <1.7 <1.1 <2.6 <1.7 Fe-59 <1.9 <1.8 <3.2 <1.9 <3.9 <2.2 Co-58 <1.8 <1.0 <1.6 <13 <3.1 <2.4 Co 60 <1.5 <1.0 <1.9 <1.4 <3.2 <23 Zn-65 <2.1 <3.9 <1.7 <2.0 <3.4 <4.0 Nb-95 <1.5 <1.8 <1.6 <1.7 <3.4 <23 Zr-95 <2.5 <4.0 <3.2 <2.2 <3.4 <2.6 Cs-134 <1.8 <1.3 <2.2 <1.1 <33 <2.8 Cs-137 <2.1 <1.1 <2.0 <1.5 <3.0 <2.1 Ba-140a <7.5 <6.2 <5.1 <4.9 <6.7 <6.9 La-140a <1.0 <1.1 <1.6 <1.1 <1.8 <1.6 Ce-144 <10.1 <29.4 <28.0 <20.8 <24.4 <17.2 Date Collected 07-27-94 08-31-94 09-28-94 10-26-94 11-30-94 12-28-94 Gross Beta 2.910.6 43i0.7 3.0io.5 3.210.6 2.210.6 2310.6 Be-7 <17.7 <28.1 <17.2 <133 <11.1 <16.6 i K-40 <40.6 <39.5 <24.9 <32.8 <46.9 <57.5 Mn-54 <3.0 <2.2 <0.9 <2.1 <1.1 <1.4 j Fe-59 <43 <6.1 <2.1 <1.9 <5.0 <4.2 Co-58 <3.0 <1.3 <1.6 <2.2 <1.8 <2.2 1 Co.60 <2.2 <3.1 <1.9 <1.4 <2.3 <1.8 l Zn-65 <2.9 <3.4 <2.7 <3.3 <3.2 <5.0 Nb-95 <3.9 <3.6 <1.8 <2.1 .<23 <2.7 Zr-95 <8.2 <8.8 <2.7 <53 <5.0 <5.2 Cs-134 <3.1 <3.4 <1.8 <2.0 <1.2 <2.5 Cs-137 <3.0 <2.4 <2.4 <1.1 <23 <23 Ba-140a <10.0 <8.0 <4.6 <6.0 <7.4 <7.5 La-140a <1.8 <2.7 <0.8 <2.2 <1.9 <2.0 Ce-144 <233 <23.7 <17.0 <17.1 <9.4 <17.5
*LLD at time of counting.
140
=. . -
- TABLE E-6 SURFACE WATER BETA AND GAMMA ISOTOPIC ACTIVITY '
(pCi/1) - CL-13 Date Collected 01-26-94 02-23-94 03-30-94 04-27-M 05-25-94 06-29-94 Gross Beta 2.7i0.7 2.2t0.6 2.9*0.7 33f0.8 2.1*0.8 2.4i0.4 ' l Be-7 <145 <7.9 <13.1 <17.2 <14.9 . <16.6 K-40 <475 <23.9 <20.8 <27.4 <24.1 <27.1
<13 Mn-54 <1.1 <0.8 <1.2 <2.0 <1.4 Fe-59 <2.1 <2.6 <2.3 <1.7 <4.0 <1.4 Co-58 <1.5 <13 <1.0 <1.5 <0.8 <1.4 -
Co-60 <2.3 <2.1 <1.1 *
<1.6 <1.9 <1.6 Zn-65 <4.0 <2.2 <1.7 <2.0 <1.6 - <1.6 Nb-95 <2.2 <0.9 <1.6 <1.1 <1.6 <2.2 Zr-95 <1.5 <2.5 <2.4 <2.6 <2.9 <2.9 Cs-134 <2.7 <1.2 <1.4 <1.9 <2.2 <0.9 Cs-137 <2.0 - <1.7 <1.4 <2.1 <2.1 <1.9 .
Ba-140a <6.8 - <5.2 <2.5 <6.1 <6.1 <5.9 . La-140a <1.5 <1.0 <1.0 <0.7 <1.2 <1.3 - i Ce-144 <113 <12.4 <22.9 <263 <24.1 <14.8 , Date Collected 07-27-94 08-31-94 09-28-94 10-26-M 11-30-94 12-28-M Gross Beta 2.9i0.6 3.lio.6 33i0.7 2.6iO3 2.9i0.6 3.4 0.7 Be-7 <12.0 <20.9 <12.9 <19.1 <14.0 <13.5 K-40 <34.9 <32.5 <19.7 <27.1 <34.7 <33.2 Mn-54 <1.6 <1.9 <1.2 <0.9 <1.7 <1.0 ; Fe-59 <43 <4.4 <3.0 <2.4 <3.3 <23 Co-58 <2.5 - <1.8 <0.9 <1.5 <0.8 <0.7 Co-60 <2.2 <2.4 <0.7 <1.9 . <1.9 <1.6 Zn-65 <2.1 <2.5 <3.9 <1.8 <23 <2.0 , I Nb-95 <2.0 <2.2 <1.3 <1.7 <2.0 <1.8 Zr-95 <4.3 <2.0 <2.9 <2.5 <3.8 ' <3.9 Cs-134 <2.2 <2.5 <1.0 <1.0 <1.7 <1.1 Cs 137 <1.1 <1.4 <1.4 <2.2 <1.7 <1.6 Ba-140a <4.0 <7.5 <2.7 <3.4 ' <6.1 <5.4 La-140a <2.0 <2 2 <0.6 <0.8 <0.8 <0.7 Ce-144 <113 <3d <16.8 <7.7 - <25.0 <12.7 aLLD at time of counting. 1 141
TABLE E-7 SURFACE WATER GROSS BETA. GROSS ALPHA, I-131 )' AND GAMMA ISOTOPIC ACTIVITY (oCi/l)- CL-90 Date Collected 01-26-94 02-23-94 03-30-94 04-27-94 05-25-94 06-29-94 Gross Alpha <0.8 <0.6 0.7105 <05 0.610.4 <0.7 Gross Beta 2.6i0.4 2.0f0.4 2.2io.4 33i0.4 3.010.4 2.910.4 I-131 <0.4 <0.5 <03 <03 <0.2 <0.2 Be-7 <9.2 <12.2 <155 <8.1 <9.7 <20.8 K-40 <46.6 <25.2 <26.7 <18.7 <23.4 <34.0 Mn-54 <1.5 <1.6 <2.0 <1.2 <13 <13 Fe-59 <4.1 <2.2 <23 <2.0 <3.0 <3.6 Co.58 <1.5 <1.5 <1.2 <1.4 <1.6 ' <1.6 Co 60 <2.7 <1.7 <1.8 <1.4 <2.0 <2.2 Zn45 <1.7 <3.0 <3.0 <2.1 <2.2 <4.2 Nb-95 <1.7 <1.6 <2.2 <1.1 <1.6 <2.3 Zr-95 <2.1 <2.5 <3.2 <1.5 <1.9 <3.7 Cs-134 <1.3 <1.7 <2.1 <1.5 <1.8 <2.4 Cs 137 <2.0 <1.8 <2.3 <1.3 <2.0 <1.1 j Ba 1408 4.4 <3.6 <33 <4.8 <4.2 <6.2 > La-1408 <1.8 <1.9 <2.1 <1.5 <1.5 <13 Ce-144 <8.5 <11.2 <265 <22.0 <23.7 <19.6 Date Collected 07-27-94 08-31-94 09-28-94 10-26-94 11-30-94 12-28-94 Gross Alpha <1.0 <0.5 <0.5 0.5i03 0.9iO3 <0.9 Gross Beta 2.4 0.6 25iO3 2.8i0.4 2.6i03 25i03 2.4i0.6 I-131 <0.2 <0.3 <0.5 <0.5 <0.2 <0.4 Be-7 <145 <19.1 <253 <13.7 <28.7 <5.8 K-40 <305 <25.7 <38.2 <44.7 <43.4 <21.8 Mn-54 <2.3 <15 <2.9 <2.6 <1.6 <1.2 Fe-59 <4.1 <1.4 - <4.4 <6.0 <2.9 <1.4 Co <1.8 <1.8 <2.1 <2.4 <1.2 <0.7 Co-60 <2.2 <1.7 <13 <2.6 <2.4 <1.2
. Zn-65 <2.6 <3.2 <2.9 <4.9 <2.2 <3.9 !
Nb-95 <1.9 <13 <3.1 <3.6 <2.4 - <1.2 Zr-95 <2.7 <2.6 4.5 <5.3 <4.0 <2.1 Cs-134 <1.8 <1.6 <3.1 <3.1 <1.9 <1.2 Cs-137 <2.4 <2.1 <3.1 <3.1 <2.6 <1.4 Ba-140s 4.2 <6.5 <9.8 <8.2 - 4.4 <3.2 La-1408 <0.9 <1.9 <2.9_ <1.2 <2.1 <0.6 Ce-144 <11.1 <25.6 <15.6 <413 <34.7 <21.1 aLLD at time of counting.
- 7. -
142
TABLE E-8 SURFACE WATER GROSS BETA. GROSS ALPHA.1-131 AND GAMMA ISOTOPIC ACTIVITY (oCi/l)- CL-91 Date Collected 01-26-94 02-23-M 03-30-94 04-27-94 05-25-94 06-29-94 Gross Alpha <1.7 <0.6 <0.5 <0.6 <1.0 <0.6 Gross Beta 1.Si0.6 1510.4 1.910.4 3.0iO3 1.610.4 1.810.4-Be-7 <13.7 <113 <21.0 <18.0 <22.5 <10.6 K-40 <28.2 <30.1 <45.1 <29.0 <433 <28.1 Mn-54 <1.5 <1.9 <2.1 <2.0 <2.0 <13 Fe-59 <43 <3.2 <4.5 <3.6 <3.5 <2.4 Co-58 <1.3 <1.1 <2.7 <2.2 <2.4 <1.8 Co-60 <1.5 <1.0 <2.6 <1.9 <2.5 <1.4 Zn-65 <3.1 <2.5 <5.1 <4.4 <3.6 <1.4 Nb-95 <2.0 <1.5 <2.9 <2.2 <23 <1.4 Zr-95 <3.5 <1.8 <2.7 <2.1 <5.1 <1.7 Cs 134 <1.4 <1.7 <1.7 <1.6 <33 <2.0 i Cs-137 <1.6 <2.2 <2.4 <2.1 <3.7 <1.9 a Ba-140a 4.0 <3.5 <7.9 - <4.4 <103 <6.4 l La-140a <1.4 <1.0 <2.3 <1.5 <1.6 <1.4 ) Ce-144 <10.8 <9.8 <24.6 <31.7 <25.7 <26.5 1 Date Collected 07-27-94 08-31-94 09-28-94 10-26-94 11-30-94 12-28-94 Gross Alpha <1.1 <0.5 <0.5 0.9iO3 0.5103 <1.0 Gross Beta 2.1f0.6 2.2io.4 2.610.4 3.010 3 2.liOJ 2.0i0.6 Be-7 <16.6 <16.5 <27.9 <26.4 - <13.2 <202 K.40 <25.1 <33.8 <40.6 <41.9 . <36.5 <43.8 Mn-54 <1.8 <1.7 <1.3 <2.6 <1.8 <1.9 Fe-59 <1.9 <3.8 <5.4 <2.2 <5.1 <4.4 Co-58 <2.0 <1.7 <23 <2.5 <13 <1.0
. Co40 <2.1 <2.3 <2.5 <3.0 <2.0 <1.9 Zn45 <3.6 <4.1 <4.4 <43 <3.5 <4.1 Nb-95 <2.4 <2.5 <3.1 <3.5 <2.3 <2.5 Zr-95 <2.5 <2.6 4.5 <2.8 <4.4 <4.5 Cs134 <2.1 <1.2 <3.5 <2.8 <2.2 <1.7 Ce137 <2.2 <2.2 <2.9 <3.0 <1.7 <13 Ba-140" <6.5 43 <8.3 <8.7 4.8 <3.7 La-140a <1,9 <1.8 <1.4 <2.1 <1.6 <2.0 Ce-144 <25.2 - <19.2 <253 <442 <14.7 <31.6 a LLD at time of counting.
143 s-
4 TABLE E-9 i SURFACE WATER GROSS BETA. TRITIUM,
,AND GAMM A ISOTOPIC ACTIVITY (pCi/l) - CL-92 Date Collected 01-26-94 02-23-94 03-30-94 04-27-M 05-25-94 06-29-94 Gross Beta 22i0.6 23io.6 '2.1*0.6 2.9i0.7 2.210.8 3.2i0.6 H-3 <188 <188 <189 <191 <191 <159 Be 7 <18.4 <20.2 <17.1 <10.7 <13.7 <19.6 K-40 <333 <29.8 <26.0 <28.6 <343 <32.0 Mn-54 <2.0 <1.6 <1.1 <1.2 <1.8 - <1.9 Fe-59 <3.8 <3.6 <3.2 <2.8 <4.2 <5.2 Co 58 <1.8 <1.9 <0.7 <1.6 <1.2 <2.0 Co40 <1.9 <1.9 <1.8 <1.6 ' <1.8 <0.9 Zn-65 <3.6 <3.4 <2.4 <4.6 <3.0 <3.6 Nb-95 <23 <2.2 <1.5 <1.6 <1.4 <2.4 Zr-95 <2.8 <3.7 <2.8 <2.1 <2.5 <4.0 Cs-134 <2.5 <2.2 <1.9 <1.8 <2.1 <2.4 Cs-137 <2.6 <2.4 <1.6 <1.9 <2.1 <1.1 Ba-140a <8.0 <8.9 <6.3 <6.0 <5.7 <6.2 La-140a <2.6 <1.5 <0.8 <1.1 <1.1 <1.8 Ce-144 <13.1 <13.4 <25.9 <14.0 <32.1 <31.7 Date Collected 07-27-94 08-31-94 09-28-94 10-26-94 11-30-94 12-28-94 Gross Beta 2.7i0.6 4.510.7 2.6i0.6 2.410.4 2.6i0.6 2.410.6 i
H-3 <157 <164 <150 <161- <169 <162 Be-7 <193 <16.9 <13.4 <183 <9.7 <9.9 K-40 <33.9 <27.1 <20.0 <32.8 . <43.5 <30.6 Mn-54 <2.4 <1.9 <1.4 <1.6 <1.7 <13 Fe-59 <4.0 <3.2 <3.1 <3.8 <3.0 <2.1 Co 58 <1.9 <1.1 <0.8 <1.7 <1.0 <1.2 Co-60 <1.9 <1.9 <1.3 <2.0 <1.0 <1.5 Zn-65 <3.7 <2.8 <1.7 <3.2 <3.4 <4.9 Nb-95 <3.2 <2.0 <1.6 <2.6 <2.4 <1.8 Zr-95 <2.0 <2.4 <1.2 <2.2 <2.2 <3.3 Cs134 <2.2 <23 <1.6 <2.0 <1.0 <1.8 Cs-137 <2.4 <2.1 <1.2 <1.8 <1.9 <1/J Ba-1408 - <7.6 <4.5 <5.4 <3.8 <3.6 <5.7 La-140a w <1.8 <0.6 <0.7 <2.1 <1.2 Ce-144 <34.4 <10.9 <30.4 <17.5 <123 <23.7 a LLD at time of counting. 144
v I TABLE E-10
;. SURFACE WATER GROSS BETA. TRITIUM.
j AND GAMMA ISOTOPIC ACTIVITY (pCi/l) - CL-93 j 1 i !
! Date Collected 01-26-94 02-23-94 03 30-94 04-27-94 05-25-94 06-29-94 ; Gross Beta 7.012.9 4.011 3 4.011 2 2.2i13 2310.6 4.1112 H-3 <187 <188 <189 <187 <191 <159 j Be-7 <15.4 <11.6 <16.9 - <27.9 <11.9 <15.6 ,
- K-40 <29.2 <25.2 <23.5 <44.6 <32.0 <18.9 i Mn-54 <1.0 <1.6 <1.7 <2.6 <2.2 <0.6 j Fe-59 <2.1 <2.0 <3.4 <3.2 <4.1 <2.8 Co-58 <13 <1.3 <1.6 <1.9 <2.0 <1.2 l Co-60 <1.8 <2.0 <1.7 <1.2 <2.2 ' - <1.2 -
i Zn-65 <2.5 <3.1 <3.5 <43 <3.5 .<1.3 Nb-95 <13 <1.4 <1.8 - <2.9 <2.4 <1.8 Zr-95 <3.4 <2.7 <2.8 <4.2 <3.5 <1.2 Crr134 <1.6 <1.4 <1.9 - <2.2 <2.1 <1.6 Cs-137 <2.1 <1.9 <2.2 <3.3 <2.0 <1.5 Ba-140a <7.3 <4.8 <33 <8.5 <7.9 <4.3 La-140a <1,g <o,7 <1,9 .<23 <2.1 <13 i Ce-144 <11.6 <10.7 <25.7 <24.9 <305 <233 1 Date Collected 07-27-94 08-31-94 09-29-94 '10-26-94 11-30-94 12-28-94 Gross Beta 2.811.1 2.111.0 1.7tl.0 '23i0.9 25i1.0 2310.7 H-3 186i89 653i106 <150 242iB9 <169 <162 Be-7 <26.5 <14.2 <223 <10.8 <15.6 <16.0 K-40 <38.6 <20.1 <32.8 <26.6 <32.1 <24.0 Mn-54 <2.5 <1.2 <1.2 <13 <1.5 <0.9 Fe-59 <7.4 <2.4 <3.5 <2.6 <1.9 . <1.2 Co-58 <3.1 <0.7 <1.4 <1.0 <1.1 <0.9 Co.60 <2.4 <1.4 <2.4 <1.2 <1.4 <13 Zn-65 <5.6 <1.3 <3.4 <1.3 <2.2 <1.9 Nb-95 <3.6 <13 <13 <1.8 <1.7 - <1.7 Zr-95 <8.2 <1.5 <4.0 <3.4 <2.1 <2.9 Crr134 <2.6 <1.5 <2.4 <0.8 <0.8 <0.7 Cs-137 <2.8 <1.2 <2.5 <1.8 <1.5 <1.5 Ba-140a <10.6 <5.4 <5.6 <3.2 <43 '<4.0 La-140s <3.5 <0.6 <1.0 <1.6 <1.8 <1.1 Ce-144 <39.2 <24.1 <12.4 <10.0 <14.0 <15.0
~
aLLD at time of counting. 145 L____________ ._. - . -- . . - -
TABLE E-11 SURFACE WATER GROSS BETA. TRITIUM. AND GAMM A ISOTOPIC ACTIVITY (oCi/h - CL-94 Date Collected 01-31-94 02-23-94 03 30-94 04-27-94 05-25-94 06-29-94 Gross Alpha <0.7 5.410.9 <0.7 <0.7 <0.8 <0.9 Gross Beta 1.2i0.5 8.6t0.6 2310.4 1.8i0.4 0.8i0.4 15i0.4 Be-7 <24.0 <19.4 <12.2 <14.0 <29.6 <13.0 K-40 <39.7 <30.9 <19.7 <28.0 <41.7 <35.0 Mn-54 <1.1 <1.7 <1.0 <2.0 <2.9 <2.0 Fe 59 <2.2 <3.8 <2.4 <3.4 <63 <4.6 Co-58 <2.4 <1.1 <1.2 <2.0 <3.2 <2.2 Co40 <2.6 <2.2 <1.3 <1.7 <1.7 <2.0 Zn-65 <4.2 <3.8 <1.2 <1.7 <4.6 <23 Nb-95 <2.1 <2.3 <1.6 <1.7 <3.0 <23 Zr-95 <4.4 <3.2 <2.0 <3.3 <4.0 <3.7 Cs-134 <2.6 <1.7 <1.6 <1.9 <2.5 <2.5 Cs.137 <3.0 <2.3 <1.6 <2.1 <2.7 <2.4 Ba-140a <7.8 <5.2 <4.6 <6.2 <7.6 <73 l La-140a <2.4 <2.3 <0.6 <15 <1.8 <1.2 i Ce-144 <28.7 <122 <22.7 <26.4 <223 <20.2 i Date Collected 07-27-94 08-31-94 09-28-94 10 26-94 11-30 94 12-28-94 Gross Alpha <1.6 <0.9 <1.1 <0.8 <1.0 <1.8 Gross Beta 3.7f0.9 3.7 0 5 4.7to.6 3.4i05 3210.4 2.510.6 Be-7 <15.7 <213 <14.2 <22.0 <28.1 <103 K-40 <27.1 <323 <255 <33.2 <50.2 <29.6 Mn-54 <1.7 <1.4 <1.1 <1.8 <2.2 <1.2 Fe-59 <2.2 <4.6 <2.8 <2.5 <5.8 <2.2 - Co-58 <1.5 <1.7 <1.1 <1.5 <2.6 <1.2 Co-60 <1.7 <1.5 <1.7 <1.8 <2.5 <1.4 Zn-65 <2.8 <3.8 <1.5 <2.2 <43 <1.4 Nb-95 <2.6 <2.4 <1.8 <2.0 <3.1 <1.6 l Zr-95 <1.5 <3.5 <2.2 <4.1 <4.2 <1.5 Cs-134 <2.0 <23 <1.6 <2.4 <33 <1.6 i Cs-137 <2.1 <1.9
<1.6 <1.2 <3.0 <1.6 Ba-140a <6.6 <7.2 <3.7 <4.1 <8.6 <4.4 La-140a <1.0 <2.2 <13 <1.9 <2.6 <1.1 Ce-144 <23.6 <19.1 <123 <15.1 . <21.9 <12.9
- LLD at time of counting, i
146 , I;
l f TABLE E-12 SURFACE WATER OU ARTERLY TRITIUM COMPOSITE (pCi/l) 1221 CL:2 CL-lif CL::13 CL.?fl CL:21 CL-22 1st Quarter <189 <189 <189 <189 <193 '<189 2nd Quarter <163 <163 <156 <156 <156 <163 3rd Quarter <148 <148 <148 <149 <149 <149 - 4th Quarter <160 <160 <160. <160 . <159 <159 a controllocation TABLE E-13 SURFACE WATER OUARTERLY TRITIUM COMPOSITE i (pCi/l) 1921 M CL-12 (Untreated) CL-12 (Treated) l
)
1st Quarter <193 <193 <193 l 2nd Quarter <163 <159 <159 ! 3rd Quarter <149 <143 <143 4th Quarter <160 <159 <160 TABLE E-14 i DRINKING WATER OU ARTERLY TRITIUM COMPOSITE (pCi/l) 1221 1st Quarter <172 2nd Quarter <178 3rd Quader <186 4th Quader <187 147
5 4 TABLE E-15 1 WFII WATERSEMIMObTTHLYIODINE ACTIVITY (pci/l) l Datg M CL-12 Untreated CL-12 Treated l i l I } 01/12/94 <0.5 <0.4 <0.4 01/26/94 <03 <03 <0.4 02/10/94 <0.4 <0.4 <0.2 ; l { 02/23/94 <03 <0.4 <0.4 { 03/09/94 <0.4 <0.4 <0.4 ! 03/23/94 <0.4 <0.4 - <0.4 04/06/94 <0.4 <03 <0.4 , 04/20/94 <0.4 <0.2 <0.1 3 05/04/94 <0.4 <0.3 <0.4 05/18/94 <0.5 <03 <0.2 , 06/01/94 <0.4 <0.4 <0.4 06/15/94. <0.4 <03 <03 4 06/29/94 <0.2 <0.2 <0.3 i 07/13/94 <0.2 <0.3 <0.2 1 07/27/94 <0.5 <0.4 <0.4 l 08/10/94 <0.4 <0.5 <03 08/24/94 <0.4 <0.4 <0.4 ) 09/07/94 <0.2 <0.2 '<0.2 l 09/21/94 <0.4 <0.4 <0.4 l 10/05/94 <0.4 <0.4 <03 10/19/94 <0.2 <03 <0.2 11/02/94 <0.5 <0.* <0.4 l 11/16/94 <0.3 <03 <0.4 l 11/30/94 <D.2 <0.5 <0.2 12/14/94 <03 <03 <03 12/28/94 <03 <0.5 <0.4 148 '
TABLE E-16 WELL WATER MONT)iLY COMPOSITE ACTIVITY CL-7D (DCi/l) Collection Period Ianuarv Februarv March Anril May lune Gross Alpha 1.lio.6 <0.6 <0.7 <0.8 1.2i0.7 ' <0.6 Gross Beta 1.9i0.4 1.1105 1.0i0. 1.1105 1.810.5 1.210.4 Be-7 <12.9 <16.1 <155 <225 <18.2 <20.8 K 40 <26.1 ' <26.2 <27.1 <28.1 <24.2 <31.7 Mn-54 <1.4 <1.4 <1.7 ~ <1.4 - <1.8 <1.9 1 Fe-59 <23 <2.0 - <3.2 <3.8 <3.6 ' <4.1 ! Co-58 <1.6 <1.9 <1.4 <2.0 <0.9 <2.4 - j Co-60 <1.9 <2.0 <2.1 <2.4 <1.8 <1.3 2n-65 <3.1 <2.8 <1.9 <5.8 <2.7 <2.7 Nb-95 <1.5 <1.8 <1.6 <2.0 <1.2 <2.4 Zr-95 <3.0 <23 <3.3 <3.6 <3.8 <3.9 4 l Cs-134 <1.7 <1.6 <1.7 <1.7 <1.9 <2.1 2 Cs-137 <2.1 <1.8 <1.9 <1.9 <2.0 <1.8 Ba-140a <4.0 <3.6 <4.6 <6.4 <3.8 <6.7 i La-140a <13 <0.9 <1.1 <1.6 <1.2 <2.1 - 1 Ce-144 <12.8 <10.6 <25.4 <32.2 <15.7 <12.2 4 1 i j Collection Period fulv Aueust Scotember - October November December i
- Gross Alpha <0.9 <1.0 <1.1 0.8t0.5 0.9105 <1.4 .
- Gross Beta 13t03 1.6i0.4 1.4i0.4 13io.4 13i0.4 1.4 0.5 i
j Be-7 <14.1 <13.2 <10.8 <20.4 <165 <18.6 K-40 <17.8 <34.6 <36.1 <25.0 <32.0 <34.6 l Mn-54 <0.8 <1.2 <23 <1.7 <2.0 <1.1 J Fe-59 <2.8 <25 <45 <2.6 <2.0 <3.2 l Co-58 <1.6 <1.8 <1.6 <1.8 <1.5 <1.2 I Co40 <1.2. <1.1 <1.6 <1.9 <1.9 <2.0 i Zn-65 <3.4 <3.5 <3.8 <33 <1.6 <3.1 ! Nb-95 <1.9 <3.2 <2.2 <2.4 <2.1 ' <2.0 j Zr-95 <3.0 <3.4 <2.2 <4.6 <3.7 <4.7 j Cs-134 <1.2 <2.3 <2.5 <2.1 <1.3 ' <1.1 Cs-137 <1.3 <1.8 <1.7 <2.2 <2.1 <13 Ba-140s <4.1 <6.8 <6.2 <5.4 <6.5 <5.5 . La-1408 <0.8 <1.1 <1.0 <2.2 <0.9 <1.4 ] Ce 144 <233 <33.2 <32.6 <26.1 - <24.1 <185 i,
~ ' a LLD at time of counting.
149 9 4
TABLE E-17 WELL WATER MONTHLY COMPOSITE ACTIVITY CL-12 UNTREATED fDCi/li Collection Period Ianuary February March April May lune Gross Alpha <1.5 <13 <1.4 <2.1 <13 <1.4 Gross Beta 1.110.9 1.7i0.9 1.110.8 2510.9 2.610.9 13i0.9 Be-7 <12.7 <195 <17.0 <122 <23.7 <9.2 K-40 <26.0 <323 <41.2 <28.4 <333 <28.0 Mn-54 <1.5 <1.0 <2.4 <1.4 <1.8 <1.5 Fe-59 <3.4 <3.8 <3.9 <2.0 <5.2 <1.5 Co-58 <1.8 <2.1 <1.3 <1.5 <2.5 <1.6 Co 60 <1.8 <2.0 <2.5 <1.6 <2.4 <1.6 Zn-65 <4.7 <3.6 <3.8 <4.8 <3.5 <2.6 Nb-95 <1.5 <1.9 <2.7 <1.6 <2.9 <2.1 Zr-95 <2.5 <1.8 <4.7 <1.7 <3.9 <2.5 Cs-134 <1.2 <1.7 <1.6 <1.1 <2.4 <1.4 Cs-137 <1.8 <13 <3.0 <1.9 4 <1.8 Ba-140a <5.8 <3.6 <5.2 <3.6 .5.7 <4.5 La-140a <0.6 <2.0 <33 <1.2 <1.0 <1.5 Ce-144 <245 <11.0 <125 <28.6 <143 <24.4 Collection Period fulv Aueust Seotember October November December Gross Alpha <2.1 <1.9 <2.0 <1.2 <1.4 <3.1 Gross Beta 1.811.0 2.Si0.9 1.6i0.9 1.lio.8 1.910.8 2.8i15 Be-7 <24.0 <27.1 <23.8 <20.2 <20.5 <25.2 K-40 <33.7 <43.8 <36.1 <41.4 <39.9 <52.1 Mn-54 <1,1 <2.4 <1.0 <2.9 <2.1 <2.8 Fe-59 <3.7 <3.2 <4.8 <2.7 <4.0 <3.6 Co-58 <1.0 <2.8 <2.2 <1.4 <1.5 <2.7 Co40 <2.1 <3.0 <2.3 <23 <0.8 <3.2 Zn-65 <2.9 <2.3 <2.5 <2.8 <4.1 <3.0 Nb-95 <2.9 <3.8 <2.7 <2.8 <1.8 <3.1 Zr-95 <2.5 <7.6 <5.3 <7.2 <4.4 <6.0 Cs-134 <1.1 <2.9 <1.6 <1.6 <2.6 <2.4 Cs-137 <2.2 <1.4 <2.0 <2.8 <1.2 <2.2 Ba-140a <6.0 <9.7 <5.6 <10.2 <7.0 <10.8 La-140a 42.0 <2.4 <2.6 <1.4 <1.5 <1.6 Ce-144 <18.0 <383 <18.7 <143 <183 <155 a LLD at time of counting. 150
TABLE E-18 i f- WELL WATER MONTHLY COMPO(ITE ACTIVITY L CL-12' TREATED (DC? (,1,), Collection Period Ianuarv Februarv March Anril May lune-j Gmss Alpha <1.8 <1.8 <2.1 <1.4 <1.9 <1.6 Gross Beta 2.6tl.0- 2.Si0.9 <1.3 <13 2.6t0.6 2.0t0.8 - i Be-7 <10.8 <24.5 <193 <11.4 <8.3 <25.8 K-40 <35.4 <32.7 <30.2 <28.8 <18.4 <353 l Mn-54 <1.2 <2.0 <13 <2.0 <13 <1.9 - J Fe-59 <3.8 <3.8 <2.0 <2.8 <2.4 <6.0 Co-58 <1.9 <2.0 <1.9 <1.9 <0.7 <1.7
?
Co-60 <1.5 <23 <2.0 <2.0 . <1.5 <2.1 Zn45 <4.0 <1.7 <3.4 <2.6 <1.4 <3.1 Nb-95 <1.7 <1.9 ~<2.4 <2.0 <1.9 <2.9 j Zr <2.6 <2.9 <3.0 <1.8 <2.5 <3.8 i Cs-134 <1.6 <2.0 ' <2.0 <1.2 <1.6 - <2.4 ~ Cs 137 <1.9 <1.9 <1.8 <2.0 <1.7 <2.1 Ba-140a <4.1 <5.5 - <6.2 <5.4 <3.7 <8.3 La-140a <2.0 <1.6 <2.0 <1.0 - <0.7 <1.0 i Ce-144 <9.3 <182 <9.6 .<255 <23.6 <16.9 ' 4 Collection Period fulv August September October November December q Gross Alpha <2.5 <1.4 <2.2 <1.6 <1.4 <3.1 Gross Beta 2.20.7 3.010.9 1.7i0.9 1.510.8 2.0i0.7 <2.5 Be-7 <20.4 <17.4 <23.1 <23.0 <20.9 ~ <16.2 K-40 <31.1 <263 <41.5 <34.5 <37.6 <44.5 - l Mn-54 <1.7 <1.3 <2.5 <2.0 <23 <1.0 , l Fe-59 <4.7 <3.4 <5.5 <4.8 <2.6 <3.2
- Co-58 <13 <1.8 <1.2 <2.0 <1.9 <1.9
- Co40 <1.4 <1.3 <1.9 <1.4 <1.9 <1.8 j Zn45 <2.8 <1.5 <5.8 <2.4 <4.1 <3.7 Nb-95 <2.7 <1.8 <3.8 <2.6 <2.7 <2.5 i Zr-95 <2.8 <1.7 <63 <3.0 <4.1 <5.1 Cs-134 <2.4 <1.1 <2.9 <2.5 <1.9 <23 i Cs-137 <2.4 <1.8 <2.7 <1.8 <2.0 <2.1 Ba-140a <43 <5.4 <10.5 <6.5 <6.0 <53.
[' La-140a <j 2 <1.5 <2.0 <0.8 <0.7 <1.0 Ce-144 <193 <25.7 <16.0 <9.7 <16.9 <31.7 LLD at time of counting. 151 4
TABLE E-19 DRINKING WATER ACTIVITY - CL-14 (DCi/1) Date Collected 01-26-M 02-23-94 03-30-94 M-27-94 05-25-94 06-29-94 Gruss Alpha <03 <0.4 <0.4 <03 <0.2 <0.2 Gross Beta 1.910.1 2.1102 2.0i0.1 23i02 1.8i0.2 - 2.110.1 Be.7 <18.2 <8.0 <15.1 <10.8 <103 <11.6 K-40 <34.0 <25.9 <40.0 <28.1 <182 <323 Mn-54 <1.9 <1.4 <5.0 <l.2 <1.0 <1.8 Fe-59 <1.9 <1.8 <2.8 <3.1 <2.4 - <1.9 - Co-58 <1.8 <1.0 <3.0 <1.5 - <0.6 <2.0 Co-60 <1.9 <1.4 <2.5 <1.8 <13 <1.6 Zn-65 <2.1 <2.4 <3.6 <2.2 <1.9 <2.7 Nb-95 <1.7 <1.5 <2.5 <1.6 <1.5 <2.3 Zr-95 <3.5 <2.2 <2.4 <2.8 <1.8 <2.6 Cs-134 <2.1 <1.3 <3.0 <1.3 <1.1 <2.0 Cs-137 <2.0 <1.2 <1.4 <1.8 <1.5 <1.2 Ba-1404 <5.3 <3.4 <8.1 <5.4 <4.6 <4.6 La-140a <1.5 <1.2 <23 <0.8 <13 <1.6 Ce-144 <13.0 <253 <24.5 <27.1 <20.6 <17.9 Date Collected 07-27-94 08-31-94 09-28 94 10-26-94 11-30-94 12-28-94 Gross Alpha <0.5 <03 <0.4 <0.6 <0.2 <0.5 Grom Beta 2.010 3 2.2io.2 2.110.2 13103 2.0i0.1 23103-l Be-7 <18.0 <12.2 <20.4 <20.1 <15.6 <6.9 K-40 <393 <403 <44.1 <28.4 <24.4 <223 Mn-54 <3.1 <1. 6 <1.6 <1.8 <0.8 <8.4 Fe-59 <5.6 <2.2 <4.7 <4.6 <2.5 <1.9 . Co-58 <2.5 <1.9 <1.8 <1.0 <0.7 <0.8 Co44 <1.7 <4 <3.2 <1.8 <1.2 <1.0 Zn-65 <2.8 l
<3.0 <5.2 <2.6 <3.8 <3.5 Nb-95 <3.2 <3.4 <3.7 <1.8 <1.5 <13 1 Zr-95 <8.1 <8.0 <7.9 <2.6 <1.2 <13 !
Ce-134 <2.6 <3.2 <2.5 <1.8 <1.2 <1.4 ) Co.137 <2.9 <13 <2.7 <1.8 <1.3 <1.2 j Ba-140a <103 <10,0 <g,9 <5.5 <4.0 <3.9 .; La-1408 <13 <1.6 <2.6 <0.9 <1.2 <1,1 l Ce-144 <25.6 <17.5 <24.1 <25.2 <23.0 <22.9
- LLD at time of counting .
I 152
)
i
+ ;
TABLE E-20 MILK ACTIVITY - CL-98 (nci/1) Date Collected 01-26-94 02-23-94 03-30-94 04-27-94 05-11-94 I Sr-90 ' NS6 NS* 2.210.4 2.5105 2.410.5 l l-131 ' - - <03 <0.2 <0.3 !
. i Be-7 - -
<14.9 <20.4 <10.2 i K.40 - - 1590i80 1770i80 1880150 Mn-54 - -
<2.5 <3.0 <1.2 ;
Fe-59 - - 4.8 <5.2 <1.7 i Co-58 - -
<3.1 <2.7 <1.4 Co.60 - -
<4.1 <3.5 <2.0 l Zn45 - -
<8.4 <6.4 <4.6 ,
Nb-95 - -
<3.9 <2.3 <1.5 Zr-95 - -
<6.1 <4.8 <1.4 Ce 134 - -
<4.2 <3.2 <1.9 ,
<1.8 Cs-137 - - <4.0 <3.6
- Ba-1408 - -
<10.6 <8.5 <5.4
- La-140a - -
<3.0 <2.1 <1.2 ,
i Ce-144 - -
<24.6 <18.8 <24.2 Date Collected 05-25-94 06-08-94 % 22-94 07-06-94 07-20-94 Sr-90 2.7i0.5 3.210.6 1.lio.4 2.210.5 1.lio.5 i
- I-131 <0.4 <0.4 <0.4 <0.2 <0.4 -
j Be-7 <22.2 <25.4 <15.0 <19,0 <183
- K-40 2050180 2040180 2150160 2110170 2080i70 i Mn-54 <3.2 <3.8 <1.9 <1.8 <2.2 FeuS9 <5.0 <5.4 <3.2 <53 <5.3 I
, Co-58 <1.8 <3.7 <2.1 <1.5 <1.6 Co.60 <5.1 <5.0 <2.8 <3.5 <3.8 j Zn-65 <6.8 <7.4 <2.6 <4.7 <3.9 l Nb-95 <1.8 <3.2 <2.1 <2.5 <2.3 4 Zr-95 <3.6 <4.7 <2.6 <4.6 <3.3
- Cs-134 <3.8 <3.1 <2.4 <2.4 <2.9 l Cs 137 <33 <4.0 <2.3 <2.0 <2.8
, Ba-140a <12.7 <103 <6.3 <8.6 <83 i- La-140a <2.5 <2.4 <0.7 <1.9 <0.8 ; ! Ce-144 <24.8 <13.9 <29.7 <11.9 <31.2 a LLD at time of counting, i
- b NS- No sample; sample not available.
1 153
l i TABLE E-20 (Cont'd) Date Collected 08-03-94 08-17-94 08-31-94 09-14-94 09-28-94 l Sr-90 1.4.10 5 1.910.6 2.0t0.5 1.8i0.5 1.910.6 ? I-131 <0.2 <0.4 <0.2 <0.4 <0.5 l Be 7 <223 <29,1 <20.1 <20.2 <26.1 K 40 1990180 2010190 2050180 2150180 1370170 Mn-54 <2.1 <2.5 <2.5 <2.8 <2.0 Fe-59 <5.6 <6.0 <3.1 <6.1 <3.4 l Co-58 <3.1 <3.2 <3.2 <2.8 <1.3 l Co-60 <3.5 <4.1 <2.9 <2.7 <2.2 Zn-65 <7.0 <5.0 <6.6 <6.2 <5.4 Nb-95 <3.1 <3.9 <3.2 <2.6 <3.2 ; Zr-95 <7.7 <9.1 <7.6 <4.0 <6.7 Cs-134 <2.4 <1.9 <3.9 <2.9 <2.9 Cs-137 <2.0 <3.4 <3.6 <1.3 <2.3 Ba-140' <10.9 <9.5 4.2 4.4 <63 . La-140s <1.6 <2.5 <1.2 <2.2 <1.2 Ce-144 <20.9 <25.4 <14.5 <34.5 <19.0 i DateCollected ' 10-12-94 10-26-94 11-30-94 12-28-94 Sr-90 13i0.5 0.9i03- 1.4f0.4 1.7*0.4 1-131 <0.4 <0.2 <03 <0.4 Be-7 <213 <22.1 <18.6 <13.7 K-40 1990190 1930180 1900160 1920170 Mn-54 <2.8 <2.1 <1.7 <2.7 Fe-59 <8.4 <6.6 <3.3 <4.1 Co-58 <2.6 <2.7 <2.0 <2.1 Co-60 <3.2 <2.7 <23 <3.3 l Zn-65 <4.7 <4.8 <3.7 <2.6 ) Nb-95 <33 <3.5 <1.5 <23 Zr-95 4.9 4.7 <2.6 <4.7 Cs-134 <3.7 <1.7 <2.7 <2.9 Cs-137 <3.7 <2.8 <2.4 <2.9 Ba-1408 4.9 <11.5 <4.4 '<9.7 La-140s <3.0 <2.5 <1.6 <2.5 Ce-144 <45.7 <41.2 <18.6 <16.8 a LLD at time of countin6-154
TABLE E-21 MIL]L&CTIVITY - CL-116 Icontrol1(DCi/1) Date Collected 01-26-M 02.23-94 03-30-94 04-27-94 05-11-94 Sr-90 2.li0 5 1.5i0.4 1.7i0.4 23i0.5 1.910.4 I-131 <03 <0.4 <0.5 <0.1 <0.2 Be-7 <153 <18.8 <18.1 <13.0 <13.9 K-40 1330160 1220f60 1330160 1250170 1400170 Mn-54 <2.1 <2.1 <2.1 ' <3.0 . <2.9 Fe-59 <3.4 <4.9 <4.8 <6.7 <5.2 Co-58 <1.3 <2.2 <2.8 <2.5 <3.2 Co-60 <2.5 <3.3 <3.3 <3.7 <4.4 hvo5 <3.0 <2.7 <4.9 <3.7 <4.0 Nb 95 <1.6 <2.4 <3.0 <3.0 <3.6 Zr-95 <1.8 <4.0 <4.4 <53 <3.8 Cs-134 - <1.2 <1.4 <1.7 <2.5 <3.2 Cs-137 <2.2 <2.6 <2.8 <3.1 <3.2 Ba-140a <4,9 <4.5 <6.5 <10.9 <12.0 La-140a <0.8 <1.0 - <2.1 <2.1 <1.3 Ce-144 <14.2 <9.4 <34.8 - <22.8 <22.5 Date Collected 05-25-94 06-0494 06-22-94 07-06-94 07-20 Sr-90 1.710.4 1.710.4 1.7i0.4 1.4f0.5 2.110.6 I-131 <0.2 <0.4 <0.4 <0.2 - <0.4 Be-7 <203 <133 <17.4 <21.1 <18.0 K-40 1250f60 1450160 1250160 1400160 1330i60 Mn-54 <2.2 <1.9 <2.3 <2.5 <1.9 Fe-59 <4.4 <5.8 ' <4.5 <4.4 <5.5 Co-58 <1.9 <1.4 <1.7 <1.8 <2.1 Co-60 <23 <1.8 <3.2 <1.6 <3.1 Zn-65 <3.4 <5.3 <3.7 <2.6 ' <4.5 Nb-95 <2.0 <1.9 <1.5 <2.3 <1.6 Zr-95 <3.8 <1.9 <1.8 <3.7 <3.2 Crr134 <2.4 <2.6 <2.3 <1.4 <2.0 Cs.137 <2.6 <2.5 <2.8 <2.8 <2.5 Ba-1408 <8.0 <7.5 <4.6 <4.5 <3.8 La-140s <1.8 <1.6 <0.9 <1.2 <0.7 Ce-144 <163 <19.4 <203 <18.4 <26.6 aLLD at time of counting. 155
f J TABLE E-21 (Cont'd) Date Colleded 08-03-94 08-17-9s 08-31-94 09-14-94 09-28-94 Sr-90 15i05 1.2i0.4 1.6i0.5 1510.5 1.810.6 1-131 <0.5 <0.4 <0.3 ' <0.4 <0.2 Be-7 <12.8 <20.1 - <265 <29.7 <19.8 K-40 1430140 1280i70 1380170 1360i80 1890i60 Mn-54 <1.1 <2.7 <2.5 <3.4 <1.2 Fe-59 <23 <2.4 <3.1 <:6.0 <4.9 Co-58 <1.0 <1.2 <3.2 <3.2 - <2.3 Co.60 <1.1 <1.2 <3.5 <3.4 <2.6 Zn-65 <2.7 <4.8 <7.8 <3.5 <5.2 Nb-95 <1.5 <2.7 <3.6 <3.6 <2.7 Zr-95 <2.0 <2.9 <8.3 <9.1 <4.5 Cs-134 <1.6 <2.0 <3.7 <1.8 <2.6 Cs-137 <13 <2.4 <2.5 <3.0 <23 Ba-140a <2.4 <5.7 <9.1 <10.8 <8.2 La-140a <0.6 <1.8 <2.7 <1.6 <1.5 Ce-144 <19.6 <15.9 <143 <18.0 <31.9 Date Colleded 10-12-94 10-26-94 11-30-94 12-28-94 Sr-90 1.SiO5 1.70.5 0.9i0.4 1.1t0.5 1-131 <03 <0.2 <0.2 <0.5 Be-7 <14.7 <15.0 <12.4 <14.0 K-40 1360i60 1410160 1100150 1170i70 Mn-54 <1.4 <2.0 <1.6 <3.4 Fe-59 <5.1 <5.4 <4.4 . <3.3 Co-58 <2.2 <2.4 <1.7 <3.0 Co 60 <2.8 <1.9 <2.2 <3.6 Zn-65 <5.8 <3.1 <5.2 . <6.8 Nb-95 <2.0 <1.6 <1.6 <3.2 Zr-95 <4.6 <5.4 <3.8 <7.0 Crr134 <1.7 <2.6 <1.5 <3.8 Cs-137 <2.3 <3.1 <2.4 <2.6 Ba-140a <4.7 <73 <6.8 <8.7 La-1404 <23 <1.8 . <13 ' <3.2 Ce i44 <20.0 <18.4 <14.9 <25.1 U LLD at time of counting. 156
,0ABLE E-22 GRASS ACTIVITY - CL-1 foci /a wet)
Date Collected 01-27-94 February 03-30-94 04-28-94 05-11-94 Be-7 7.01 *0.22 NSb 22.12i0.46 4.33i0.17 0.9110.10 K-40 1.0210.16 - 21.3810.27 5.5310.22 6.2210.22 Mn-54 <0.010 - <0.018 <0.007 <0.008 Fe-59 <0.012 -
<0.038 <0.017 <0.018 Co-58 <0.009 - <0.017 <0.009 <0.007 Co-60 <0.011 - '<0.016 <0.011 <0.010 Zn45 <0.019 - <0.064 <0.024 <0.028 Nb-95 <0.007 - <0.022 <0.009 <0.008 Zr-95 <0.018 -
<0.030 <0.014 <0.013 1-131 <0.007 -
<0.030 <0.006 <0.007 Cs-134 <0.011 - <0.020 <0.009 <0.007 Cs-137 <0.012 -
<0.019 <0.009 <0.010 Ba-140a <0.036 -
<0.052 <0.032 <0.020 La-140a <0.004 - <0.009 <0.003 <0.003 Ce-144 <0.053 - <0.13 <0.047 <0.047 Date Collected 05-25 44 06-08-94 06-22 94 07-06-94 07-20-94 Be-7 0.7710.06 0.5010.05 1.3010.10 2.1610.10 2.03i0.14 K-40 5.88i0.15 4.30i0.12 7.03io.24 7.1110.35 7.0510.30 Mn-54 <0.005 <0.006 <0.006 <0.005 <0.009 Fe-59 <0.014 <0.012 <0.011 <0.014 <0.024 Co-58 <0.002 <0.004 <0.010 <0.006 <0.006 Co-60 <0.007 <0.009 <0.014 <0.009 <0.006 Zn-65 <0.016 <0.017 <0.018 <0.018 <0.018 Nb-95 <.0.007 <0.007 <0.008 <0.007 <0.022 Zr-95 <0.006 <0.006 <0.008 <0.012 <0.011 1-131 <0.009 <0.005 <0.010 <0.010 <0.015 Cs-134 <0.004 <0.008 <0.010 <0.006 <0.010 Cs-137 <0.006 <0.008 <0.010 <0.007 <0.013 Ba-140a <0.020 <0.018 <0.027 <0.022 <0.030 La-140a <0.002 <0.002 <0.003 <0.002 <0.003 Ce-144 <0.041 <0.049 <0.055 <0.021 <0.068 aLLD at time of counting, b NS- No sample; sample not available.
s ! 157 t
TABLE E-22 (Cont'd) Date Collected 08-03-94 08-17-94 08-31-94 09-14-94 09-28-94 Be-7 1.53f0.11 2.7210.13 1.24t0.10 233i0.12 S.4510.22 K-40 636i0.21 7.04i0.23 6.59*0.26 6.%io.23 654i0.32 Mn-54 <0.008 <0.007 <0.007 <0.010 <0.015 Fe-59 <0.014 <0.022 <0.018 <0.011 <0.027 Co-58 <0.005 <0.004 <0.005 <0.007 <0.009 Co 60 <0.005 <0.011 <0.011 <0.011 <0.012 Zn45 <0.026, <0.016 <0.016 <0.031 <0.032 Nb-95 <0.009 <0.009 <0.010 <0.011 <0.014 Zr-95 <0.012 <0.008 <0.007 <0.015 <0.012 1-131 <0.007 <0.013 <0.010 <0.009 <0.015 Cs-134 <0.009 <0.010 . <0.010 <0.006 <0.015 Cs-137 <0.010 <0.010 <0.010 <0.010 <0.007 Ba-140a <0.017 <0.028 <0.032 <0.039 <0.042 La-140a <0.005 <0.006 <0.003 <0.008 <0.009 Ce-144 <0.069 <0.064 <0.060 <0.061 ' <0.053 Date Collected 10-12-94 10-26-94 11-30-94 12-28-94 Be-7 1.42*0.09 232i0.14 6.50i0.15 10.28i0.24 K-40 73510.19 6.06i0.24 4.15i0.17 1.4910.19 Mn-54 <0.003 <0.011 <0.007 <0.008 Fe-59 <0.012 <0.023 <0.014 <0.016 Co-58 <0.006 <0.010 <0.008 <0.011 i Co40 <0.007 <0.007 <0.007 <0.011 Zn-65 <0.021 <0.023 <0.027 <0.020 Nb-95 <0.007 <0.007 <0.005 <0.006 Zr-95 <0.010 <0.022 <0.014 <0.011 1-131 <0.005 <0.015 <0.006 <0.013 > Cs-134 <0.009 <0.012 <0.008 <0.013 Cs-137 <0.008 <0.012 <0.007 <0.011 l Ba-1408 <0.015 <0.030 <0.021 <0.030. I La-140a <0.003 <0.006 <0.005 <0.005 l Ce-144 <0.051 <0.065 <0.042 <0.066
*LLD at time of counting.
l i 158 l P
l l TABLE E-23 GRASS ACTIVITY - CL-2 f oCi/a wet) A Date Collected 01-27-94 Februarv 03-30-94 04-28 ~ 05-11-94 Be-7 4.9310.18 NSb 20.7910.45 3.60i0.25 0.87*0.05 K-40 1.9110.19 - 22.0810.31 7.45i0.42 5.8610.12 Mn-54 <0.010 - <0.020 <0.021 <0.006 Fe-59 <0.017 - <0.030 <0.040 <0.008 Co-58 <0.009 - <0.017 <0.011 <0.005 Co-60 <0.013 - <0.021 <0.028 <0.004 ' Zn-65 <0.012 - <0.031 <0.037 <0.013 Nb-95 <0.010 - <0.017 <0.024 <0.005 Zr-95 <0.016 -
<0.032 <0.016 <0.010 I-131 <0.012 - <0.015 <0.016 <0.009 Cs134 <0.012 -
<0.018 <0.013 <0.004 Cs-137 <0.012 - <0.021 <0.022 <0.005 Ba-140a <0.031 -
<0.062 <0.071 <0.018 La-140a <0.011 - <0.011 <0.011 <0.002 ,
Ce-144 <0.094 - <0.076 <0.080 <0.046 Date Collected 05-25-94 06-08-94 06-22-94 07-06-94 07-20-94 Be-7 0.8410.07 0.40iO.% 1.0110.12 2.6810.14 8.68 0.29 K-40 6.1910.19 4.9610.17 6.7410.28 7.4910.25 11.8810.36 Mn-54 <0.006 <0.005 <0.012 <0.008 <0.012 Fe-59 <0.013 <0.008 <0.028 <0.015 <0.024 Co-58 <0.003 <0.006 <0.014 <0.006 <0.013 Co40 <0.007 <0.009 <0.014 <0.011 <0.019 Zn-65 <0.013 <0.024 <0.014 <0.022 <0.025 Nb-95 <0.007 <0.004 <0.008 <0.008 <0.006 Zr-95 <0.009 <0.012 <0.023 <0.015 <0.021 1-131 <0.009 <0.010 <0.009 <0.009 <0.016 Cs-134 <0.007 <0.007 <0.012 <0.010 <0.016 , Cs-137 <0.008 <0.007 <0.011 <0.011 <0.013 ; Ba-140a <0.025 <0.027 <0.038 <0.022 <0.030 ! La-140a <0.003 <0.005 <0.004 <0.006 <0.007 Ce-144 <0.045 <0.052 <0.038 <0.068 <0.011 aLLD at time of counting. b NS = No sample; sample not available. 159
4 TABLE E-23 (Cont'd) j Date Collected 08-03-94 08-17-94 08-31-94 09-14-94 09-28 04 l Be-7 22110.11 3.0710.15 3.62io.14 3.9810.13 7.3210.24 K-40 7.4710.20 7.2210.30 5.04i0.20 7.7310.22 5.8310.31 Mn-54 <0.007 <0.011 <0.005 <0.004 <0.012 Fe-59 <0.014 <0.016 <0.011 <0.014 <0.026 Co-58 <0.005 <0.009 <0.008 <0.008 <0.012 Co40 <0.008 <0.014 <0.007 <0.009 <0.010 Zn-65 <0.026 <0.020 <0.027 <0.026 <0.013 Nb-95 <0.006 <0.014 <0.008 <0.008 <0.014 Zr-95 <0.011 <0.019 <0.006 <0.015 <0.018 I-131 <0.008 <0.009 <0.011 <0.010 <0.018 Cs-134 <0.008 <0.007 <0.007 <0.008 <0.014 Cs-137 <0.008 <0.008 <0.006 <0.009 <0.014 Ba-140a <0.021 <0.043 <0.025 <0.022 <0.046 La-140a <0.002 <0.006 <0.004 <0.007 <0.074 Ce-144 <0.057 <0.053 <0.024 <0.069 <0.084 DateCollected 10-12-94 10-26-94 11-30-94 12-28-94 Be-7 2.4010.09 2.8910.12 8.28i0.25 4.27io.11 K-40 65610.22 6.6110.22 4.8510.30 5.26i0.17 Mn-54 <0.007 <0.010 <0.009 <0.005 Fe-59 <0.018 <0.018 <0.018 <0.011 Co-58 <0.006 <0.009 ' <0.007 <0.006 Co-60 <0.005 <0.009 <0.014 <0.009 Zn-65 <0.018 <0.015 <0.020 <0.011 Nb-95 <0.006 <0.007 <0.014 <0.005 Zr-95 <0.013 <0.020 <0.022 <0.009 I-131 <0.011 <0.011 <0.016 <0.007 Cs-134 <0.008 <0.007 <0.014 <0.006 Cs 137 <0.008 <0.009 <0.012 <0.007 Ba-140a <o,olg <o,019 <0.033 <0.019 La-140a <0.003 <0.005 <0.010 <0.004 Ce-144 <0.042 <0.056 <0.050 <0.026 aLLD at time of counting. l I 160 l
l I TABLE E- 24 GRASS ACTIVITY - CL-8 (DCi/a wet) Date Collected 01-27-94 Februarv 03-30 94 04-28-94 05-11-94 1 i Be-7 l 7.58*0.23 NSb 13.64f0.27 1.34i0.12 037i0.07 K-40 233i0.20 - 3.53i0.22 8.90i0.29 6.6010.18 , Mn-54 <0.011 -
<0.010 <0.009 ; <0.004 '
Fe-59 <0.024 -
<0.022 <0.019 - <0.015 : !
Co-58 <0.010 - <0.006 <0.009 <0.006 Co-60 <0.016 -
<0.014 <0.014 <0.010 'l Zn-65 <D.035 - <0.040 <0.033 <0.024 ,
Nb-95 <0.009 -
<0.011 <0.011 <0.009 -
Zr-95 <0.022 -
<0.021 <0.013 <0.012 ,
1-131 <0.000 -
<0.017 <0.011 <0.008 [
Cs.134 <0.014 -
<0 014 ' <0.013 <0.008 -l Cs-137 <0.015 -
<0.015 <0.010 <0.006 .f Ba-140a <0.041 -
4.042 <0.023 ~<0.024 { La-140a <0.009 -
<0.014 <0.008 <0.002 Ce 144 <0.090 -
<0.058 <0.073 <0.040-t 05-25-94 06-08-94 06-22-94 07-06-94 07-20-94' i
- Qate Collected Be-7 0.31f0.09 0.49i0.06 0.7310.10 - 133io.09 034i0.08 K-40 733fD.28 4.7010.14 7.7710.25 6.23i0.20 7.2910.25 Mn <0.009 <0.004 <0.009 <0.007 . <0.003 Fe-59 <0.014 <0.012 <0.019 , <0.018 <0.017 Co-58 <0.008 <0.005 '<0.009 ' <0.004 <0.004 ,
Co 60 <0.015 <0.007 <0.012 <0.010 <0.004 Zn-65 <0.023 <0.008 ' <0.021 <0.017 <0.009 Nb-95 <0.006 <0.004 <0.007 <0.007= <0.015 : Zr-95 <0.018 <0.007 <0.017 <0.007 <0.006 1-131 <0.008 <0.006 <0.010 <0.008 <0.017 Cs-134 <0.005 <0.006 <0.011 <0.009 <0.009 - Co-137 <0.012 <0.006 <0.009 <0.008 <0.005 Ba-140a <0.036 <0.019 <0.023 <0.014 <0.016 La-1408 <0.007 <0.002 <0.004 <0.003 <0.005 Ce-144 <0.037 <0.036 <0.046 <0.042 <0.046 aLLD at time of counting. .i b NS- No sample;samplenot available. l 161
TABLE E-24 (Cont'd) Date Colleded 08-03-94 08-17-94 08-31-94 09 % 09-28-94 Be-7 0.7210.08 0.21f0.09 1.0410.11 0.3910.08 2.2010.14 ! K-40 6.87i0.24 5.99f0.26 8.0810.29 6.2910.23 6.2210.26 i Mn-54 <0.008 <0.012 <0.011 <0.009 <0.007 Fe-59 <0.018 <0.024 <0.021 <0.009 <0.010 , Co-58 c0.004 <0.008 <0.010 <0.007 <0.005 l Co40 <0.010 <0.012 <0.009 <0.005 <0.010 Zn-65 <0.016 <0.024 <0.015 <0.018 <0.013 Nb-95 <0.008 <0.012 <0.010 <0.011 <0.009 Zr-95 <0.015 <0.031 <0.011 <0.028 <0.016 ' 1-131 <0.012 <0.014 <0.014 <0.012 <0.006 Cs-134 <0.009 <0.006 <0.011 <0.006 <0.006 Cs-137 <0.010 <0.013 <0.011 <0.006 <0.010 Ba-140a <0.026 <0.024 <0.037 . <0.020 <0.030 . La-140a <0.007 <0.005 <0.006 <0.009 <0.004 Ce-144 <0.032 <0.081 <0.084 <0.040 <0.060 1 Date Colk<ted 10-12-94 10-26-94 11-30-94 12-28-94
]
Be-7 2.13t0.13 1.91to.09 5.28t0.14 5.97io.18 K-40 62010.27 6.91i0.19 5.86t0.23 3.1410.20 Mn-54 <0.008 <0.007 <0.011 <0.009 Fe-59 <0.023 <0.016 <0.030 <0.020 Co 58 <0.006 <0.008 <0.008 <0.006 Co40 <0.010 <0.010 <t,.313 <0.010 Zn-65 <0.024 <0.018 <0.017 <0.027 , Nb-95 <0.010 <0.010 <0.008 <0.011 Zr-95 <0.016 <0.020 <0.022 <0.011 1-131 <0.007 <0.012 <0.011 <0.014 Cs-134 <0.013 <0.011 <0.009 <0.010 ! Cs-137 <0.011 <0.006 <0.013 <0.009 Ba-140a <0.031 <0.026 <0.027 <0.034 La-140a <0.008 <0.003 <0.006 <0.007 Ce-144 <0.085 <0.054 <0.061 ' <0.073 l aLLD at time of counting. 162 l
i a TABLE E-25 i GRASS ACTIVITY - CL-11 iDCi/a wet) Date Collected 01-27-M Februarv 03-30-M 04-28-M 05-11-M ~ Be-7 10.18i0.27 NSb 13.16i0.31 4.36*0.18 0.55i0.09
- K-40 .0.% i0.16 - 3.52*0.27 5.72 0.28 6.05i0.23 '
4 Mn-54 <0.011 - <0.016 . <0.012 <0.008 Fe-59 <0.011 -
<0.035 <0.022 <0.018
- Co 58 <0.009 - . <0.00'7 <0.009 <0.005 j
l Co40 <0.014. - <0.008 <0.013 <0.012 Zn-65 <0.012 - - <0.042 _ <0.024 <0.018 j j . Nb-95 <0.008 - <0.017 <0.010 <0.009 : Zr-95 <0.016 - <0.026 <0.020 <0.015 I-131 <0.009 -
<0.012 <0.008 <0.010 Cs134 <0.008 - <0.016 <0.014 <0.008 Cs-137 <0.014 -
<0.016 <0.015 <0.009 4
Ba-1408 <0.043 - <0.062 <0.034 <0.028 }. La-140a <0.009 - <0.014 <0.008 <0.007 Ce-144 <0.085 -
<0.11 <0.073 4.053 i
1 Date Collected 05-25-M 06-08-94 06-22-M 07-06-M 07-20-M Be-7 1.1410.10 0.6910.10 1.71t0.12 0.3510.06 0.6910.09 K-40 5.26f0.20 5.13f0.22 8.2310.23 5.93i0.16 7.4710.20 ! Mn-54 <0.006 <0.008 <0.008 <0.005 <0.005 j Fe-59 <0.017 <0.016 <0.017 ' <0.014 <0.010 ( l- Co-58 <0.007 <0.007 <0.008 <0.006 <0.005 ! Co40 <0.010 <0.008 d.010 <0.008 <0.009 l Zn45 <0.018 <0.018 <0.009 <0.012 <0.017 l Nb-95 <0.008 <0.005 <0.006 <0.007 - <0.007 Zr-95 <0.014 <0.013 <0.017 <0.011 <0.009 i 1-131 <0.007 <0.009 <0.010 <0.010 <0.009 ! Cs134 <0.004 <0.009 <0.006 <0.004 <0.003 f Cs 137 <0.004 <0.009 <0.008 <0.007 ' ' <0.008 Ba-140a <0.019 <0.028 <0.032 <0.010 <0.024 La-1408 <0.003 <0.004 <0.006 <0.005 <0.002 ! Ce-144 <0.056 <0.058 <0.069 <0.023 <0.048- {
- LLD at time of counting .
- b NS = No sample;mple not available.
i 4 163 i
TABLE E-25 (Cont'A1. Date Collected 08-03-94 08-17-94 08-31-94 09-14-94 09-28-94 Be-7 0.49 0.09 2.05f0.15 1.58*0.09 1.57*0.10 12810.83 K-40 7.00io.26 7.40f0.31 6.68to.20 7.40t0.20 63010.20 Mn-54 <0.009 <0.006 <0.007 <0.006 <0.006 Fe-59 <0.022- <0.020 <0.015 <0.007 <0.016 i Co-58 <0.009 <0.009 <0.005 <0.007 <0.004 { Co40 <0.010 <0.013 <0.007' <0.003 <0.008 l Zn45 <0.011 <0.029 <0.010 <0.024 <0.022 1 Nb-95 .
<0.004 <0.008 <0.008 <0.008 <0.007 Zr-95 <0.014 - <0.011 <0.011 <0.011 d.012 1-131 <0.009 <0.009 <0.010 <0.055 <0.608 i Cs134 <0.009 <0.009 <0.008 <0.005 <0.007 Cs137 <0.011 <0.012 <0.008 <0.007 <0.007 Ba-140a <0.032 <0.035 <0.026 <0.013 <0.022 La-140a <0.004 <0.006 <0.005 <0.002 c0.006 Ce-144 <0.030 <0.078 <0.064 <0.055 <0.039 Date Collected 10-12-94 10-26-94 11-30-94 12-28 I Be-7 139i0.08 1.63*0.09 8.08*0.23 6.5210.18 K-40 6.%+0.17 7.91f0.23 3.0610.22 237i0.17 Mn-54 <0.004 <0.005 - <0.012 <0.008 Fe-59 <0.006 <0.010 <0.019 <0.009 Co-58 <0.005 <0.005 <0.011 <0.009 Co40 <0.006 <0.008 <0.010 <0.010 Zn-65 <0.022 <0.025 <0.011 <0.029 Nb-95 <0.005 <0.008 <0.012 <0.010 Zr oS <0.007 <0.016 <0.020 <0.014 1-131- <0.007 <0.005 <0.016 <0.015 Cs-134 <0.007 <0.007 <0.010 <0.011 Cs-137 <0.005 - <0.009 <0.013 <0.010 Ba-140a <0.010 <0.031 <0.034 <0.029 La-140a <0.003 <0.005 <0.009 <0.007 Ce-144 <0.038 <0.045 <0.040 <0.064 aLLD at time of counting.
164 WW%$r8h8 ?h0Yt Y MUtAYO Y $N$ 5Y$$bVYVONh0b6$1?bSTO 5 bi$iibn% W S%TQLT&tsfa
TABLE'E-26' l GRASS ACTIVITY - CL-116 foci /a wet)- Date Collected 01-27-94 Februaw 03-30-94 0428-94 05-11-94 l l l ' Be-7 5.76to.22 NSb 13.08i0.24 ' 4.95i0.19 2.49f0.13 l K-40 2.63i0.24 - '4.86i0.23 6.0110.30 6.4410.22 Mn-54 <0.013 - <0.011 <0.006 - <0.008 l Fe-59 <0.017 - <0.017 - <0.023 . <0.015
' Co 58 <0.006 - <0.008 - <0.013 <0.007 Co40 <0.014- - <0.013 <0.009 <0.012 Zn45- <0.026- - <0.034 <0.024 <0.012
. Nb-95 <0.008 - <0.012 <0.008 <0.009 Zr-95 <0.013 - <0.017 <0.022 <0.007 1-131 <0.014 -
<0.010 <0.016 <0.009 Cs-134 <0.012 - <0.009 <0.009 <0.010 Cs-137 <0.016 - .<0.011 <0.012 <0.010 Ba-140a <0.046 - . <0.032 <0.025 - <0.032
<0.007 - <0.008 <0.004 -
La-140a <0.010 - Ce-144 <0.086- - <0.16 <0.088 <0.056 Date Collected 05-25-94 06-08 06-22-94' 07-06-94 07-20-94 Be-7 0.8210.09 1.2910.11 1.9310.09 '2.0210.13 0.9010.10 K-40 4.9210.16 3.98i0.21 7.03i0.19 7.3910.18- 7.62i0.23 Mn <0.006 <0.004 ' <0.007 - <0.006 <0.008 Fe-59 <0.008 <0.015 <0.017 - <0.016 <0.019 Co-58 <0.006 <0.007 <0.006 <0.005 <0.007 Co40 <0.009. .<0.011 . <0.010 <0.009 <0.009 Zn45 <0.022 <0.026 <0.018 <0.024 <0.028 Nb-95 <0.0'16 <0.009 <0.007 <0.007 <0.009 Zr-95 <0.007 <0.017 <0.011 <0.010 <0.014 I-131 <0.009 <0.010 <0.010 <0.010 '<0.008 Cs-134 <0.006 <0.009 <0.008 <0.006 <0.009 Co-137 <0.007 <0.009 <0.006 <0.007 <0.008 Ba-140s <0.021 <0.026 <0.020 - <0.031 <0.025 La-140m <0.005 <0.006 <0.004 <0.006 <0.005 Ce-144 <0.048 <0.061 <0.036 <0.054 <0.064 a LLD at timeof counting. b NS- No sample; sample not available. 165 L
TABLE E-26 (Cont'd) Date Collected 08-03-94 08-17-94 08-31-94 09-14-94 09-28 94 Be-7 0.95i0.12 1.55i0.12 1.54i0.11 2.5610.13 1.42i0.15 K-40 5.78t0.25 0.6010.27 6.1410.24 6.2810.25' 5.87i0.28 Mn-54 <0.008 <0.009 <0.009 <0.011 <0.012 Fe-59 <0.024 <0.010 <0.019 <0.021 <0.014 Co-58 <0.011 <0.004 <0.010 <0.010 <0.011 Co40 <0.006 <0.010 <0.010 <0.011 <0.015 Zn-65 <0.018 <0.013 <0.015 <0.031 <0.030 Nb95 <0.010 <0.009 <0.010 <0.009 <0.015 Zr-95 <0.017 <0.012 <0.018 <0.016 <0.035 I-131 <0.008 <0.008 <0.011 <0.013 <0.012 Cs-134 <0.005 <0.010 <0.006 <0.012 <0.014 Ce.137 <0.010 <0.009 <0.011- <0.009 <0.013 Ba-140a <0.037 <0.016 <0.028 <0.036 <0.048 La-140" <0.003 <0.003 <0.006 <0.008 <0.005 Ce-144 <0.060 <0.13 <0.041 <0.089 <0.089 Date Collected 10-12-94 10-26-94 11-30-94 12-28 94 Be-7 1.71i0.12 2.5110.12 7.3610.18 6.8920.18 K-40 5.1910.24 7.01i0.20 3.6610.18 4.54i0.19 Mn-54 <0.009 <0.007 <0.008 <0.006 Fe-59 <0.010 <0.016 <0.013 <0.015 Co-58 <0.006 <0.008 <0.006 <0.008 i Co40 <0.012 <0.008 <0.008 <0.010 ! Zn-65 <0.019 <0.029 <0.027 <0.026 I N b95 <0.010 <0.008 <0.009 <0.009 i I Zr-95 <0.017 <0.012 <0.012 <0.021 l i I-131 <0.006 <0.010 - <0.014 <0.020 Cs-134 <0.011 <0.009 <0.008 <0.009 Cs-137 <0.011 <0.010 <0.010 <0.010 Ba-140a <0.019 <0.025 <0.034 <0.014 La-140a <0.005 <0.003 <0.008 <0.005 Ce-144 <0.050 <0.058 <0.128 <0.068 aLLD at time of counting. 166 I
TABLE E GREEN T.WUY VEGETART.R ACTIVITY - CL-114 fcontrol')fDCi/li SamoleTvoe Kale 12ttuce Cabbane Imttuce Cabbare Kale 1 DateCollected %29-94 % 29-94 % 29-94 07-27-94 07-27-94 07-27-94 ' Gross Beta 5.2710,19 6.1610.23 2.8610.09 3.65i0.12 2.8110.10 -3.3410.11 Be-7 0.0910.04 02010.08 <0.042 0.14i0.07 <0.036 <0.048 K-40 4.26i0.12 3.1410.12 2.97 0.14 4.19i0.19 2.77io.09 4.1110.14 ~ , Mn-54 <0.003 <0.003 <0.004 <0.007 <0.002 <0.005 : I Fe-59 <0.008 <0.007 <0.012 <0.016 <0.006 <0.012 Co-58 <0.003 <0.005 <0.004 <0.006 <0.002 <0.004 Co-60 <0.005 <0.004 <0.008 <0.007 <0.003 _<0.005 i Zn45 <0.016 <0.014 <0.012 <0.012 <0.004 <0.010 Nb-95 <0.005 <0.003 <0.006 <0.008 <0.004 <0.003 Zr-95 <0.008 <0.006 <0.009 <0.015 <0.006 <0.008 I-131 <0.004 <0.015 <0.009 <0.006 <0.008 <0.003 Cs-134 <0.004 <0.004 <0.005 <0.008 <0.004 <0.004 ' . Cs 137 <0.005 <0.004 <0.006 <0.004 <0.003 - <0.006 Ba-140a <0.011 <0.013 <0.015 <0.017 <0.011 - <0.016 La-140a <0.003 <0.001 <0.002 <0.006 <0.003 <0.004 > Ce-144 <0.030 <0.015 <0.063 ' <0.045 <0.026. -<0.034 SamoleTvoe Cabbaee Kale Soinach Cabbare Kale Spinach - Date Collected 08-31-94 08-31-94 08-31 09-28-94 09-28-94 09-28-94 Gross Beta 2.3310.07 4.8910.19 6.2110.21 327io.13 4.10f0.11 6.65i0.21 Be-7 <0.040 0.21t0.04 02010.03 0.1610.04 0.2410.05 0.2210.07 K-40 2.6610.10 3.3410.11 4.2210.12 3.01*0.14 - 4.51i0.12 7.17*0.24 Mn-54 <0.003 <0.005 <0.003 <0.005 <0.004 <0.008 Fe-59 <0.010 <0.008 <0.008 <0.010 <0.006 <0.020 Co-58 ch.003 <0.005 <0.005 <0.005 <0.003 <0.004 Co 60 <0.034 <0.004 <0.004 <0.005 <0.004 <0.010 Zn-65 <0.008 <0.012 <0.010 <0.012 <0.007 <0.016 Nb-95 <0.005 <0.004 <0.004 <0.005 <0.005 <0.008 Zr-95 <0.008 <0.010 <0.007 <0.009 <0.006 <0.013 I-131 <0.006 <0.003 <0.006 <0.007 <0.005 <0.007 l Cs-134 <0.004 <0.004 <0.004 <0.006 <0.004 - <0,0% l i Cs 137 <0.004 <0.005 <0.004 <0.006 <0.011 . <0.008 Ba-140a <0.012 <0.012 <0.012 <0.017 <0.011 <0.026 La-140a <0.002 <0.005 <0.003 <0.002 <0.002 <0.028 Ce-144 <0.030 <0.027 <0.016 <0.044 <0.012 <0.044 a LLD at time of counting. 167
TABLE E-28 GREEN LEAFY VEGETABLE ACTIVITY - CL-115 (oci/1) SamoleTvoc Lettuce Cabbaee Kale Date Collected NSb NSb NSb 07-27-94 07-27-M 07-27-94 Gross Beta - - - 7.05i0.22 3.1210.13 2.510.10 Be ? - - - 0.1710.07 <0.065 <0.12 K-40 - - - 5.4210.22 3.8710.20 4.9510.24 Mn-54 - - -
<0.008 <0.008 <0.012 Fe-59 - - -
<0.011 <0.017 <0.025 Co-58 - - - <0.007 <0.00~7 <0.010 Co40 - - . - <0.008 <0.010 <0.010 Zn-65 - - -
<0.016 <0.024 <0.013 Nb-95 - - -
<0 007 <0.007 <0.014 Zr-95 - - - <0.008 <0.011 <0.023 1-131 - - -
<0.010 <0.012 <0.017 Cs-134 - - -
<0.005 <0.004 <0.011 Cs-137 - - -
<0.008 <0.007 <0.013 Ba-1408 - - -
<0.027 <0.012 <0.018 La-1408 - - -
<0.004 <0.008 <0.007 Ce-144 - - -
<0.062 <0.070 <0.076 SamoleTvoe Cabbaee Kale Cabbace Kale Date Collected 08-31-94 08-31-94 09-28-94 09-28-94 Giuss Beta 2.77i0.11 3.8810.16 3.2010.12 4.61to.22 Be-7 <0.068 <0.080 0.2110.05 0.23i0.05 K-40 3.2410.17 3.9710.20 2.7410.13 4.3610.14 Mn-54 <0.008 <0.008 <0.005 <0.005 Fe-59 <0.014 <0.010 <0.005 <0.012 Co-58 <0.005 <0.006 <0.002 <0.003 1
Co40 <0.009 <0.010 <0.004 <0.005 Zn-65 <0.013 <0.017 <0.005 <0.017 Nb-95 <0.006 <0.007 <0.004 <0.005 Zr-95 <0.014 <0.012 <0.008 <0.004 1-131 <0.011 <0.011 <0.009 <0.008 i Cs-134 <0.006 <0.011 <0.002 <0.006 i Cs-137 <0.007 <0.010 <0.004 <0.005 Ba-140a <0.029 <0.031 <0.014 <0.019 ; La-140s <0.005 <0.004 <0.018 <0.004 ' Ce-144 <0.039 <0.034 <0.029 <0.070
- LLD at time of counting.
b NS-no sample; sample unavailable i 168
TABLE E-29 GREEN TRAFY VEGETprR ACTIVITY - CL-117' foci /l) Samole Tvoe Chard Lettuce Cabbare Chard Cabbane Kale Date Collected 06-29-94 06-29-94 06-29-94 07-27-94 07-27 27-94 Gross Beta 6.22f0.20 1.86i0.06 3.1210.10 6A2f0.20 3.4610.13 4.25i0.15 - Be-7 0.22i0.03 0.2610.06 <0.039 0.15i0.05 0.1810.05 0.08t0.04 K-40 5.22io.12 2.7010.12 2.7010.11 5.70i0.17 3.77t0.14 3.9910.13 Mn-54 <0.004 <0.004 <0.004 <0.005 <0.005 <0.005 Fe-59 <0.008 <0.010 <0.008 <0.014 <0.006 <0.011 Co-58 <0.004 <0.005 <0.003 <0.003 <0.003 <0.004 Co40 <0.006 <0.006 <0.004 <0.004 <0.005 <0.006 Zn45 <0.009 <0.010 <0.012 <0.008 <0.012 <0.008 Nb-95 <0.003 <0.005 <0.003 <0.006 <0.005 <0.004 Zr-95 <0.004 <0.009 <0.007 <0.004 <0.007 <0.007 I-131 <0.006 <0.006 <0.006- <0.006 <0.010 <0.007 Cs-134 <0.004 <0.006 <0.003 <0.006 <0.006 <0.004 Cs-137 <0.003 <0.005 <0.005 <0.005 <0.006 <0.006 Ba-140a <0.009 <0.018 <0.012 <0.015 <0.014 <0.016 La-140a <0.002 <0.004 <0.004' <0.003 <0.002 <0.003 Ce-144 ' <0.046 <0.019 - <0.032 <0.034 <0.055 <0.031 Samole Tvoc Chard Cabbane Kale Chard Cabbane Kale Date Collected 08-31-94 0831-94 08-31-94 09-28-94 09-28-94 09-28-94 Gross Beta 4.63i0.19 4.78i0.19 4.10f0.12 3.43i0.11 2.47*0.07 2.9210.10 Be-7 0.18i0.04 0.38i0.05 0.21i0.03 <0.055 <0.046 0.23*0.07 K-40 5.4710.16 3.63t0.11 2.8410.48 3.75i0.16 1.99t0.1 3.58io.14 Mn-54 <0.005 <0.005 <0.002 <0.005 <0.004 <0.005 i Fe-59 <0.007 <0.009 <0.004 <0.015 <0.013 <0.010 Co-58 <0.006 <0.004 <0.002 <0.004 <0.005 <0.004 Co40 <0.006 <0.005 <0.002 <0.007 <0.006 <0.006 Zn45 <f).014 <0.013 <0.008 <0.013 <0.010 <0.011 Nb-95 <0.005 <0.005 <0.004 <0.005 <0.006 <0.006 Zr-95 <0.006 <0.009 <0.005 <0.007 <0.006 <0.009 , 1-131 <0.005 <0.006 <0.006 <0.006 <0.007 <0.010 Cs-134 <0.006 <0.004 <0.004 <0.007 <0.003 <0.003 Cs-137 <0.005 <0.005 <0.004 <0.005 <0.006 <0.006 Ba-140m <0.016 <0.010 <0.012 <0.014 <0.018 <0.024 La-140a <0.002 <0.002 <0.003 <0.005 <0.004 <0.002 Ce-144 <0.035 <0.035 <0.028 <0.040 <0.036 <0.043 aLLD at time of counting. l 169 i
TABLE E-30 GREEN LEAFY VEGETABLE ACTIVITY - CL-118 (DCi/l) SampleType Chard Imttuce Kale Chnrd 12ttuce Cabbaee DateCollected % 29-94 % 29-94 % 29-94 07-27-94 07-27-94 07-27-94 Gross Beta 7.1210.22- 2.7010.09 4.51io.16 9.0810.26 5.1110.15 2.46i0.08 Be-7 0.6710.07 0.33i0.05 0.010io.04 0.23i0.05 0.18i0.06 0.0710.03 K-40 82 010.21 2.83io.13 420i0.12 8.5910.21 5.54i0.18 233io.08 Mn-54 <0.005 <0.004 <0.004 <0.006 <0.007 <0.003 Fe-59 <0.014 <0.009 <0.005 <0.017 <0.016 <0.006 Co-58 <0.005 <0.003 <0.003 <0.003 <0.006 <0.002 Co-60 <0.008 <0.007 <0.006 <0.006 <0.008 <0.003 Zn-65 <0.017 <0.012 <0.007 <0.014 <0.007 <0.006 Nb-95 <0.005 <0.005 <0.005 <0.005 ~<0.007 <0.004 Zr-95 <0.012 <0.007 <0.008 <0.007 <0.010 <0.005 1-131 <0.010 <0.006 <0.004 <0.009 <0.009 <0.003 Ce-134 <0.008 - <0.005 <0.005 <0.006 <0.005 <0.004 ; Cs-137 <0.008 <0.006- <0.004 <0.007 <0.005 <0.003 Ba-140' <0.022 <0.020 <0.008 <0.018 <0.011 <0.010 La-140s <0.004 <0.002 <0.002 <0.005 <0.004 <0.001 Ce-144 <0.027 <0.060 <0.029 <0.029 <0.026 <0.024 SamoleTvoc Chard Cabbnee Kale Chard Cabbare Kale Date Collected 08-31-94 E 31-94 % 31-94 09-28-94 09-28-94 09-28 94 Gross Beta 14.7410.47 2.7910.11 2.97io.12 7.1410.20 231io.07 3.81io.13 Be-7 026i0.05 0.0910.03 0.15i0.04 0.2110.05 0.05i0.03 0 2010.07 K-40 8.11t0.22 2.2510.07 3.07i0.12 7.6210.16 2.1810.08 3.63i0.17 Mn-54 <0.005 <0.003 <0.004 <0.004 <0.003 <0.004 Fe-59 <0.008 <0.005 <0.005 <0.009 <0.006 <0.008 Co.58 <0.006 <0.002 <0.004 <0.005 <0.003 <0.006 Co-60 <0.004 <0.003 <0.005 <0.006 <0.003 <0.006 l Zn-65 <0.020 <0.005 <0.012 <0.006 <0.007 <0.014 I Nb-95 <0.006 <0.003 <0.005 <0.006 <0.004 <0.007 I Zr-95 <0.039 <0.004 <0.008 <0.009 <0.006 <0.009 l
<0.009 <0.002 l 1-131 <0.003 <0.008 <0.005 <0.011 Cs-134 <0.007 <0.004 <0.005 <0.003 <0.004 <0.006 Cs-137 <0.008 <0.002 <0.005 <0.003 <0.003 <0.007 l Ba-1408 <0.023 <0.011 <0.011 <0.016 <0.007 <0.023 I La-140s <0.005 <0.001 <0.003 <0.004 <0.002 <0.004 Ce-144 <0.045 <0.051 <0.026 - <0.039 <0.050 <0.035 l aLLD at time of counting.
l 1 170
l l TABLE E-31 MEAT ACTIVITY - CL-106 foci /a wet) Date Collected 01-31-94 01-31-94 01-31-94 Type Bovine Thyroid ' Bovine Liver - Beef (Edible Portions) Be-7 <0.60 '<0.054 <0.030 K-40 <2.5 2.50i0.14 2.76t0.16 , Mn-54 <0.081 <0.006 <0.006 Fe-59 <0.086 <0.010 <0.011 2 Co-58 <0.054 <0.006 <0.006 Co-60 <0.091 <0.008 <0.008 Zn-65 <0.25 <0.007 <0.014 Nb-95 <0.081 <0.006 <0.006 Zr-95 <0.064 <0.006 <0.011 , Ru-103 <0.040 <0.005 <0.004 Ru-106 <0.67 <0.053 <0.062 1-131 <0.11 <0.010 <0.009 Cs-134 <0.068 <0.006 <0.005 Cs-137 <0.074 <0.007 <0.007 Ba-1404 <0.22 <0.013 <0.017 La-140a <0.024 <0.002 <0.006 Ce-141 <0.046 <0.009 <0.008 Ce-144 <0.24 <0.051 <0.030 a LLD at time of counting. 171 1 1
1 l TABLE E-32 FISH ACTIVITY - CL-19 foci /a wet) Date Collected 04-21-94 04-21-94 04-21-M 04-21-94 Type Crappie Carp Largemouth Bass Blue Gill Be-7 <0.034 <0.030 <0.034 <0.046 , K-40 3.1210.11 2.8710.15 3.4110.16 2.4310.18 Mn-54 4.003 <0.003 <0.006 <0.008 Fe-59 <0.010 <0.009 <0.014 <0.017 Co-58 <0.002 <0.003 <0.006 <0.009 Co40 <0.005 <0.005 <0.009- <0.009 Zn-65 <0.014 <0.014 <0.007 <0.016 Nb-95 <0.005 <0.007 <0.006 <0.005 Zr-95 <0.004 <0.010 <0.009 <0.014 Ru 103 <0.004 <0.003 <0.005 <0.008
~
Ru-106 <0.024 <0.052 <0.050 <0.081 Cs-134 <0.002 <0.006 <0.007 <0.009 Cs-137 <0.004 <0.006 <0.007 <0.010 Ba-140a <0.010 <0.010 <0.018 <0.025 La-140a ,0.003 <0.002 <0.004 <0.008 Ce-141 <0.008 <0.006 <0.010 <0.013 t Ce-144 <0.021 <0.031 <0.040 <0.038 i Date Collected 10-21-94 10-21-94 10-21-94 10-21-94 Type Crappie Carp Largemouth Bass Blue Gill Be-7 <0.045 <0.048 <0.%8 <0.072 K-40 321t0.16 2.7810.18 3.15i0.17 2.6310.14 Mn-54 <0.005 <0.006 <0.004 <0.005 Fe-59 <0.012 <0.009 <0.021 <0.017 ! Co-58 <0.003 <0.007 <0.007 <0.003 ! Co-60 <0.007 <0.007 <0.008 <0.007 ' Zn-65 <0.015 <0.016 <0.014 <0.015 ) Nb-95 <0.005 <0.007 <0.009 <0.005 Zr-95 <0.009 <0.012 <0.008 <0.014 Ru-103 <0.003 <0.006 <0.007 <0.010 Ru-106 <0.042 <0.050 <0.%3 <0.047 Cs-134 <0.006 <0.008 <0.008 <0.003 Cs137 <0.007 <0.009 <0.007 <0.006 l Ba-140a 4.016 <0.024 <0.018 <0.016 i La-140a <0.004 <0.007 <0.005 <0.003 Ce-141 <0.007 <0.008 <0.010 <0.006 Ce-144 <0.016 <0.048 <0.044 <0.031 a LLD at time of counting. i 172 l
b TABLE E-M FISH ACTIVITY - CL-105 fcontrol)(DCi/a wet) Date Collected 04-22-94 04-22-94 04-22-M 04-22-M Type- Largemouth Bass Carp Crappie Bluegill Be-7 <0.033 '<0.049 <0.053 <0.041' K-40 3.18i0.12 3.10f0.15 2.98i0.16 2.47 0.12 Mn-54 <0.005 <0.005 - <0.006 <0.003 Fe-59 <0.009 <0.014 <0.016 <0.011 Co-58 <0.005 <0.006 <0.004 <0.004 Co40 <0.004 <0.009 <0.006 <0.005 Zn45 <0.006 <0.015 <0.007. <0.006 Nb-95 <0.004 <0.006 <0.008 <0.006 Zr-95 <0.005 <0.008 <0.010 <0.007 Ru-103 <0.005 <0.005 -<0.006 <0.003 Ru-106 <0.044 <0.047 <0.057 .<0.025 Cs-134 <0.005 <0.004 <0.007 <0.004 Cs-137 <0.005 <0.006 <0.006 <0.006 Ba-140a <0.017 <0.010 - <0.019 <0.016 La-140a <0.003 <0.003 <0.005 <0.002
' Ce-141 <0.007 <0.010 <0.012 .' <0.010 Ce-144 <0.028 <0.032 <0.037 . <0.024 Date Collected 10-24-94 10-24.M 10-24-94 10-24-94 Type Largemouth Bass Carp Crappie Blue Gill Be-7 <0.073 <0.062 <0.053 <0.073 K-40 3.3210.18 2.9810.14 3.2510.18 2.2410.13 Mn-54 <0.007 <0.004 <0.004 - <0.004 Fe-59 <0.020 <0.008 <0.021 <0.017 :
Co-58 '<0.007 <0.004 <0.005 <0.004 Co40 <0.006 <0.004 <0.007 <0.007 Zn45 <0.009 <0.012 <0.016 <0.010 Nb-95 <0.010 <0.007 <0.012 <0.011 Zr-95 <0.022 <0.014 <0.021 <0.016 Ru-103 <0.008 <0.004 <0.007 <0.010 Ru-106 <0.052 <0.058 <0.065 <0.056 Cs-134 <0.004 <0.005 <0.008 <0.006 Cs-137 <0.006 <0.005 <0.007 <0.005 Ba-140a <0.021 <0.015 <0.025 <0.022 La-140a <0.004 <0.003 <0.004 <0.003 Ce-141 <0.023 <0.015 <0.018 <0.019 Ce-144 <0.038 <0.021 <0.045 <0.051 a LLD at time of counting. 173
TABLE E-34 AQUATIC VEGETATION ACTIVITY - (DCi/o wet 1 Location CL-7B CL-7C CL-9 CL-10 Date Collected 04-21-94 04-21-94 04-21-94 04-21-94 , Be-7 1.4210.29 0.64i0.19 0.9410.23 0.4010.16 K-40 3.2610.40 2.1410.28 1.9810.30 0.95i0.29 Mn-54 <0.023- <0.015 <0.018 <0.012 Fe-59 <0.020 <0.038 <0.043 <0.038 Co-58 <0.024 <0.011 <0.019 <0.017 Co-60 <0.011 <0.019 <0.020 <0.016 Zn-65 <0.062 <0.052 <0.023 <0.056 Nb-95 <0.033 <0.010 <0.026 <0.016 Zr-95 <0.017 <0.023- <0.036 <0.029 Cs-134 <0.024 <0.017 <0.019 <0.016 Cs-137 0.08510.033 0.03010.014 <0.025 <0.015 Ba-140a <0.080 <0.051 <0.058 <0.039 La-140a <0.029 <0.013 <0.015 <0.008 t Ce-144 <0.12 <0.048 <0.11 <0.034 Location CL-19 CL 105 Date Collected 04-21-94 04-22-94
- Be-7 0.70i0.21 0.6710.27 K-40 2.7310.32 2.96i0.42 Mn-54 <0.017 <0.014 Fe-59 <0.042 <0.046 Co-58 <0.010 <0.023 i Co 60 <0.017 <0.024
- Zn-65 <0.054 <0.024 Nb-95 <0.024 <0.032 Zr-95 <0.040 <0.052 Cs-134 <0.019 <0.026 Cs-137 <0.022 0.065i0.028 Ba-140s <0.033 <0.065 La-140a <0.012 <0.014 Ce-144 <0.069 <0.082 a LLD at time of counting.
i ! 174 I
TABLE E-34 (Cont'd) location _ CL-7B CL-7C CL-9 Date Colleded Ob-24-M 06-24-M %24-M Be-7 0.65i0.27 0.57to.30 0.41to.13 , K-40 2.25i0.30 1.1510.33 1 3210.14
, Mn-54 <0.024 <0.025 <0.010 Fe-59 <0.029 <0.027 <0.023 Co-58 <0.017 <0.028 <0.014 , Co-60 <0.017 <0.024 <0.012 Zn-65 <0.074 <0.078 <0.027
. Nb-95 <0.041 <0.040 <0.022 Zr-95 <0.042 <0.050 <0.029 4 Cs-134 <0.024 <0.025 <0.015 Cs-137 0.03710.022 <0.020 0.02610.010 Ba-M0a <0.076 <0.083 <0.024 La-140a <0.016 <0.010 <0.006 Ce-144 <0.092 <0.078 <0.067 i 4 ) Location CL-10 CL 3 Date Collected % 24-M 06-24-M .
- Be-7 0.59io.29 1.33i0.31 i K-40 1.5310.36 4.76 0.41 Mn-54 <0.022 <0.019 Fe-59 <0.044 <0.037 Co-58 <0.020 <0.020 Co40 <0.024 <0.027 )
- Zn45 <0.020 <0.076 Nb-95 <0.042 <0.019 ,
Zr-95 <0.052 <0.051 Cs-134 <0.025 <0.023 Cs137 <0.026 0.06910.025 ' <0.068 <0.064 Ba-140a l 4 La-140a <0.015 <0.010 Ce-144 <0.15 <0.12 a LLD at time of counting. 4 1 4 1 175 i
f TABLE E-34 (Cont'd) Location CL-7B CL-7C - CL-9 l Date Colleded 08-22-94 08-2R-94 08-22-94 I Be-7 0.35i0.16 0.45f0.18 0.%f0.03 K-40 0.9210.18 0.9110.23 2.89 0.48 Mn-54 <0.011 <0.016 <0.027 Fe-59 <0.011 <0.016 <0.040 Co-58 <0.011 <0.012 <0.020 Co-60 <0.012 <0.007 <0.035 Zn-65 <0.047 <0.048 <0.078 Nb-95 <0.021 <0.018 <0.033 Zr-95 <0.024 <0.016 <0.052 Cs-134 <0.015 <0.015 <0.026 Cs-137 <0.016 <0.021 <0.031 Ba-140a <0.048 <0.034 <0.044 La-140' <0.007 <0.012 <0.011 Ce-144 <0.059 <0.064 <0.14 Location CL-10 CL-19 Date Collected 08-22-94 08-22-94 Be-7 0.10io.06 0.8410.39 K-40 0.2510.14 2.5210.60 Mn-54 <0.008 <0.029 Fe-59 <0.015 <0.037 Co-58 <0.008 <0.017 Co40 <0.009 <0.034 Zn-65 <0.014 <0.010 Nb-95 <0.010 <0.028 l Zr-95 <0.014 <0.063 Cs134 <0.005 <0.038 Cs-137 <0.008 <0.035 Ba-140a <0.020 <0.098 La-140a <0.004 <0.024 Ce-144 <0.026 <0.11 a LLD at time of counting. 176
l TABLE E-34 (corLt'dJ. d Location Cle7B CL-7C CL-9
- Date Collected 10-21-94 10 21-94 1021-94 Be-7 0.81i037 l 0.67i039 0.53iO32 K-40 2.18io.50 3.22io.54 3.5210.49 i Mn-54 <0.028 <0.036 <0.024 Fe-59 <0.010 - <0.094 <0.074 i Co-58 <0.014 <0.032 <0.021
, Co40 <0.029 <0.034 - <0.032 Zn45 <0.067 <0.11 <0.088' Nb-95 <0.068 <0.083 <0.029
- Zr-95 <0.074 <0.099 <0.11 1 Cs-134 <0.026 <0.045 <0.036 Cs-137 <0.036 0.07810.046 0.051i0.030 Ba-140a <0.075 <0.12 <0.093 La-140a <0.021 <0.031 <0.013 Ce-144 <0.21 <0.15 <0.098 location CL-10 CL-19 CL-105
- Date Collected 10-21-94 10-21-94 10-24-94 I
Be-7 0.42i0.24 1.4010.33 03210.21 K-40 236t0.42 3.26 0.35 3.41i0.33 Mn-54 <0.020 <0.019 <0.015 l Fe-59 <0.067 <0.061- <0.033 I Co-58 <0.028 <0.026 <0.012 - Co40 <0.025 <0.022 <0.016
- Zn45 <0.035 <0.070 <0.061 Nb-95 <0.029 <0.032 ' <0.029 Zr-95 ' <0.075 <0.039 <0.031
; Cs-134 <0.026 <0.020 <0.021 Cs-137 0.041i0.024 <0.024- 0.07710.025
! Ba-1408 <0.068 <0.061 <0.075 j La-140a <0.017 <0.014 <0.014 Ce-144 <0.084 <0.053 <0.13 a LLD at time of counting. i I 0 177
l TABLE E-35 SHORELINE SEDIMENT ACTIVITY - (DCi/a drv) location Cb78 CL-7C CL-10 Cbl9 Date Collected 04-21-94 04-21-94 04-21-94 04-21-94 Gross Alpha <3.% 4.68i2.89 6 3413.25 <3.58 l Gross Beta 4.1112.05 10.66i2.46 15.18i2.69 6.71i2.25 Sr-90 <0.009 <0.011 <0.007 <0.007 Be-7 0.11i0.08 <0.066 <0.073 031io.08 K-40 8.63i0.27 11.471022 16.04iO38 8.42f0.25 Mn-54 <0.009 <0.006 <0.009 <0.006 Fe-59 <0.021 <0.012 <0.024 <0.013 Co-58 <0.008 <0.006 <0.008 <0.012 Co40 <0.012 <0.008 <0.015 <0.006 Zn-65 <0.033 <0.029 <0.044 <0.028 Nb-95 <0.007 <0.011 <0.008 .<0.008 Zr-95 <0.010 <0.015 <0.010 <0.014 Cs-134 <0.005 <0.013 <0.009 <0.014 Cs-137 <0.008 <0.008 0.01610.009 <0.008 Ba-140a <o,019 <0.022 <0.029 <0.018 .,
~
La-140a <0.006 <0.006 <0.003 <0.002 Ce-144 <0.065 <0.053 <0.056 <0.036 Ac-228 0.16i0.04 0.28i0.03 0.65t0.06 0.16i0.03 Bi-212 0.24i0.15 037i0.07- 0.7310.16 <0.106 Bi-214 0.1510.02 0.17f0.02 036i0.03 0.1210.01 Pb-212 0.16to.02 03210.01 0 5810.02 0.1810.01 Pb-214 0.17*0.03 0.1810.02 0.4310.03 0.1610.02 Ra-226 0.4710.13 0.7110.11 1.04f0.16 0 3710.11-TI-208 0.05io.01 0.10io.01 0.2010.02 0.048i0.009 a LLD at time of counting. i l l 178
l 1 i i TABLE E-35 (Cont'd) ,4
- Location CL-88 Cle89 CL-93 CL-105 Date Collected 04-21-M 04-21-M 04-22-M 04-22-M Gross Alpha <3.34 8.23f3.60 <4.41 9.74f4.00 Gross Beta ,
7.65i2.30 14.6112.54 12.86i1.78 21.19i2.94 Sr-90 <0.009 <0.007 <0.007 - <0.007 Be-7 <0.029 <0.080 1.2210.14 <0.11 K-40 9.6210.26 12.74i0.31 7.8020.30- 15.95*0.40 Mn-54 <0.007 <0.009 <0.013 <0.013 Fe-59 <0.021 <0.019 <0.024 <0.023 Co 58 <0.005 <0.013 <0.005 <0.009-Co40 <0.010 <0.014 <0.018 <0.016 Zn45 <0.032 <0.041 <0.067 <0.054 Nb-95 <0.007 <0.016 <0.012 <0.013 Zr-95 <0.014 <0.008 ' <0.027 <0.027 Cs-134 <0.014 <0.020 <0.011 <0.008 Cs-137 <0.006 0.047i0.011 0.038to.013 <0.012 Ba-140a <0.023 <0.013 <0.035 <0.045 La-140a <0.002 <0.003 <0.012 <0.007 Ce 144 <0.031 <0.059 <0.088 <0.070 Ac-228 0.1410.03 0.4210.04 0.42i0.05 0.8910.06 Bi-212 <0.11 0.43i0.09 0.59to.18 0.88i0.20 Bi-214 0.1110.01 0.32i0.02 0.45i0.03 - 0.49i0.04 Pb-212 0.14*0.01 0.44to.02 0.40io.04' O.85i0.04 Pb-214 0.1210.02 0.3610.03 0.5410.04 0.5910.04 Ra-226 0.33*0.11 0.8210.14 1.90io.21 1.33i0.21 TI-208 0.047f0.011 0.13t0.01 0.13io.02 02910.02 a LLD at time of counting. 179
1 1 I TABLE E-35 (Cont'd) Location CL-7B CL-7C CL-10 CL-19 l DateCollected 10-21-94 10-21-94 10-21-94 10 21-94 Gross Alpha <3.70 <1.81 <3.68 <3.23 Gross Beta 7.5612.25 6.4611.09 10.5712.51 5.56f2.08 l Sr-90 <0.007 <0.012 <0.008 <0.007 Be-7 <0.074 -<0.080 <0.065 <0.19 K-40 8.6510.19- 9.3410.20 9.4410.29 9.23i0.43 Mn-54 <0.006 <0.009 <0.008 <0.016 Fe-59 <0.009 <0.030 <0.014 <0.030 Co-58 <0.006 <0.005 <0.013 <0.020 Co60 <0.007 <0.010 <0.011 <0.015 Zn45 <0.026 <0.035 <0.035 <0.061 Nb-95 <0.012 <0.017 <0.018 <0.028 Zr-95 <0.014 <0.016 <0.036 <0.025 Cs-134 <0.012 <0.014 <0.016 <0.026 , Cs-137 <0.006 <0.008 <0.011 <0.021 Ba-140a <0.015 <0.013 <0.025 <0.028 La-140a <0.002 <0.003 <0.007 <0.015 Ce-144 <0.053 <0.037 <0.031 <0.071 Ac-228 0.14f0.03 0.15i0.02 0.2010.04 0.2910.08 Bi-212 0.1310.05 0.1710.09 0.28i0.11 <0.24 Bi-214 0.1210.01 0.09010.013 0.13i0.02 0.13io.03 Pb-212 0.12i0.01 0.082f0.011 0.18i0.02 0.1810.03 Pb-214 0.1510.02 0.1210.02 0.15f0.02 ' O.14i0.04 Ra-226 01410.09 0.20io.11 0.2310.13 <0.39 i TI-208 0.05110.008 0.053io.008 0.056io.011 0.07310.021 a LLD at time of counting. 180
l I l l TABLE E-35 (Cont'd) l Location CL-88 CL-89 CL-93 CL-105 Date Collected 10-21-94 10-21-94 10-21-94 10-24-94 Gross Alpha <3.20 6.06i3.02 6.68i4.54 <3.48 Gross Beta 11.65i2 56 13.78i2.64 10.84i331 7.76f2.18 Sr-90 <0.012 <0.007 <0.007 <0.009 Be-7 <0.098 <0.10 1.84fD.20 <0.20
. K-40 10.291031 11.55i031 6.291030 8.9010.42 Mn-54 <0.010 <0.012 <0.013 <0.017 Fe-59 <0.024 <0.015 <0.026 <0.051 Co-58 <0.014 <0.015 <0.010 <0.027 Co-60 <0.011 <0.011 <.0.016 <0.023 Zn45 <0.045 <0.044 <0.052 <0.064 Nb-95 <0.008 <0.022 <0.027 <0.027 Zr-95 <0.020 <0.026 <0.020 <0.026 Cs.134 <0.020 <0.021 <0.034 <0.031 Cs-137 <0.008 0.030i0.010 0.033i0.011 <0.018 Ba-140a <0.026 <0.017 <0.025 <0.054 La-1402 <0.004 <0.008 <0.006 <0.009 Ce-144 <0.054 <0.063 <0.053 <0.11 Ac-228 030io.04 03610.05 03810.06 03410.07 Bi-212 031i0.12 0.4210.13 0 3510.11 03210.16 Bi-214 0.2010.02 0.2410.02 0.5010.03 0.24i0.03 Pb-212 0.2910.02 03410.02 03910.03 0.2810.03 Pb-214 0.2210.02 0.2810.03 0.61f0.04 0.23i0.04 Ra-226 0.4710.12 0.5210.14 1.9110.21 0.54f0.19 TI-208 0.092io.014 0.1310.01 0.1210.02 0.09510.016 a LLD at time of counting.
l l l 181
I 1 i i
^
TABLE E-36 l 2-BOTTOM SEDIMENT ACTIVITY - (DCi/a drvi ) i I 4 i i ' location CL-7C Cle10 Cle13A CL-17 CL-19
- DateColleded 04-21-94 04-21-94 NI?- 04-21-94 04-21-94
]- j Gross Alpha 13.95i4.22 12.7814.01 - 658i358 11.63i3.94 i Gross Beta 25.0513.18 2431i2.93 - 16.18i2.73 22.29i2.84 j Sr-90 <0.008 <0.008 -
' <0.006 <0.014 j Be-7 0.52i0.18 1 3910.22 -- 0.4310.10 3.29to.18
! K-40 20.9710.48 19.26t0.44 -- 10.89fo.26 16.%io.42 I Mn-54 <0.016 <0.023 - <0.007 <0.013 . j- Fe-59 <0.031 <0.034 -
<0.021 <0.033'
! Co-58 <0.020 <0.020 -
<0.011 <0.015 l Co40 '<0.016 <0.017 -
' <0.006 <0.014 j Zn45 <0.074 <0.069 -
<0.033 <0.058 i- Nb-95 <0.032 <0.027 -
<0.007 <0.022
- Zr-95 <0.039 <0.037 -
<0.011 <0.025
- Cs-134 <0.033 <0.022 -
<0.017 <0.019 j Cs-137 0.2110.03 03810.02 -
0.040i0.012 0.1610.02
- Ba-1408 <0.034 <0.028- -
<0.022 <0.048
- La-140a <0.007 <0.018 -
<0.002 <0.017
- Ce-144 <0.13 <0.12 -
<0.053 <0.090 f Ac-228. 135i0.08 137io.07 -
0.4310.04 0.6810.06 ! Bi-212 1.2410.28 1.4310.22 - 0.4810.14 0.6510.18 l Bi-214 0.7310.04 0.87i0.04 - 0.2810.02 0.4510.03 - i Pb-212 1.4110.05 1.52i0.04 - 0.4510.02 0.6910.03 ) Pb-214 1.1110.06 0.96 0.05 - 031*0.02 0.5710.03 4 Ra-226 1.45i0.29 .3.0310.29 - 0.73i0.12 1.0310.21 l TI-208 0.43i0.03 0.44 0.03 - 0.1310.01 02410.02 i
- . aLLD ct time ci counting.
b ND- No deta:nrnple not available } i , I ! i' 1 1 l 1 i i j
- l 4
. 182 n
-t
TABLE E-36 (Cont'd)
- Location CL-89. CL-105
. Date Collected 04-21-94 04-22-94 Gross Alpha <4.79 6.76*3.28 Gross Beta 10.2312.42 18.50i2.74 Sr-90 <0.009 0.02110.007 Be-7 <0.077 0.97i0.15 K-40 9.08f0.30 17.25fn24 Mn-54 <0.010 <o.012 Fe-59 <D.020 <0.021 Co 58 <0.007 <0.009 Co40 <0.014 <0.013 -
Zn-65 <0.038 -<0.052. Nb-95 <0.008 <0.017
. Zr-95 <0.019 ' <0.025 Cs-134 <0.010 <0.016 Cs-137 0.01710.010 0.28t0.02 Ba-140' <0.017 <0.032 La-140a <0.005 <0.012 Ce-144 <0.051 <0.088 Ac-228 037i0.05 0.8010.05 Bi-212 0.44i0.18 0.60io.12 Bi-214 0.26 0.03 03610.03 Pb-212 0.32 0.02 0.86i0.03 Pb-214 0.29i0.02 0.54i0.04 Ra-226 0.73i0.16 0.89fD.19 TI-208 0.11i0.01 0.27f0.02 aLLD at time of counting.
183
a l TABLE E-36 (Cont'd_}. Location CL-7C CL-10 CL-13A CL-17 Date Collected 10-21-94 10-21-94 10-21-94 10-21-94 l l Gross Alpha 13.2214.27 <4.20 531i2.90 13.41i5.86 Gross Beta 28.58i3.25 <3.57 11.63i2.55 21.8414.17 1 i Sr-90 <0.012 <0.011 <0.008 <0.016 i Be-7 <0.44 <036 <0.18 032i0.14 . K-40 18.5710.94 17.0310.75 12.7210.40 1739i036 , Mn-54 <0.037 <0.030 <0.013 <0.012 Fe-59 <.0.087 <0.056 <0.039 <0.031 Co-58 <0.046 <0.045 <0.017 <0.018 Co-60 <0.042 <0.038 <0.016 <0.013 3 Zn-65 <0.17 <0.13 <0.067 <0.051 Nb-95 <0.061 <0.076 <0.031 <0.023 l Zr-95 <0.089 <0.056 <0.032 <0.028 Cs-134 <0.076 <0.068 <0.026 <0.026 .i Cs-137 0.1910.04 033i0.05 0.04010.018 0.08310.017 Ba-140a <0.13 <0.12 <0.052 <0.042 La-140a <0.031 <0.015 <0.012 <0.004 Ce-144 <0.20 <0.24 <0.055 <0.093 i Ac-228 1.4310.18 1.1710.14 0.41i0.07 0.7610.06 Bi-212 1.07iO39 1.2910.41 03410.14 0.72io.17 j Bi-214 0.7910.09 0.8310.07 0.2510.03 0.4810.03 Pb-212 1.1910.% 1.11i0. % 03610.02 0.6810.03
- Pb-214 0.9110.08 0.91i0.08 03210.04 0.6510.03
, Ra-226 1.8210.40 2.00io.40 0.55io.19 1.0710.18 TI-208 038i0.06 03810.04 0.1410.02 0.2610.02 aLLD at time of counting. l I i 4 l I l 184 , 1
o 4 i' J J. j TABLE E-36 (Cont'd) Location CL 19 C1,89 CL-105 j Date Collected 1021 10-21-94 10-24-94 I l {' Gross Alpha ~ <4.22 ' <4.09 11.05i3.90 Gross Beta 113412.40 9.2812.22 15.6712.64 i !l- Sr-90 <0.007. <0.009 <0.008 , Be-7 <0.12 <0.098 <0.38
- . K-40 11.44t030 - 10.85t0.24 - 21.52i0.91 l' Mn-54 <0.010 <0.008 <0.034 ,I l Fe-59 d.030 <0.023 -<0.057 l Co-58 <0.007 <0.012 <0.049-
~ Co 60 <0.016 <0.008 <0.042 1- Zn-65 <0.038 - <0.033 <0.16 ! - Nb-95 L<0.021 <0.016 <0.069 ; ). Zr -<0.021 <0.020 . <0.087 f Cs-134 <0.016 <0.017 <0.072 I j' Cs 137. <0.014 0.020i0.009 035i0.05 : Ba-140a <0.037 <0.026 <0.096 , I La-140a <0.007 <0.005- <0.045-j Ce-144 <0.083 <0.062 <0.24 { Ac-228 0.27i0.06 03710.03 1.41i0.16 ). Bi-212 036 0.19 0.4110.11 ~ 1.5010.48 j Bi-214 0.15i0.02- 0.26t0.02 0.8310.07 1 Pb-212 0.2230.02 033i0.02 1.36i0.07 ;
- Pb-214 . 0.1710.03 . 03110.02 0.9410.10 i i Ra-226 037i0.16 0.5110.12 2.29fo.48 i TI-208' O.086i0.016 0.1310.01 0.4710.05 l
l aLLD at time of countin8-1 i t i i s i
- 185 i !
l
TABLE E-37 SOIL ACTIVITY - (DCi/o drvi location CL-1 CL-2 CL-3 CL-4
. Date Collected 10-27-94 10-28-94 10-28-94 10-28-94 .
Gross Alpha 82712.89 9.8212.91 9.4812.90 11.89f4.04 Gross Beta 22.17i234 23.40123 9 20.05i228 25.00i3.04 Be-7 <0.23 <0.15 <0.18 <0.29 - K-40 17.65io.48 17.77i0.46 17.19t0.42 16.91t0.54 Mn-54 <0.018 <0.017 <0.016 <0.022 Fe-59 <0.%5 <0.031 <0.047 <0.065 , Co-58 <0.019 <0.026 <0.023 <0.035 { Co-60 <0.018 <0.020 <0.014- <0.012 I Zn-65 <0.074 <0.084 <0.071 <0.097 I Nb-95 <0.056 <0.062 <0.037 <0.056 Zr-95 <0.047 <0,095 <0.039 <0.043 Cs 134 <0.038 <0.040 <0.035 <0.049 Cs-137 02010.02 0.2710.02 0.21to.02 0 3710.04 Ba-1408 <0.078 <0.053 <0.039 <0.069 La-140a <0.018 <0.010 <0.019 <0.026 Cc-144 <0.12 <0.%3 <0.094 <0.23 l Ac-228 12610.09 1.1510.09 1.10i0.07 1.18i0.10 Bi-212 1.2210.16 1.0610.25 1.2210.23 1.0710.23 Bi-214 0.9110.04 0.6210.04 0.9410.03 0.84i0.05 Pb-212 12710.04 1.2010.04 1.0510.03 1.0710.05 I Pb-214 1.0110.06 1.0810.05 0.9910.04 1.04i0.07 l Ra-226 2.4610.31 23310.27 1.% i0.22 1.95i0.34 TI-208 0.42f0.03 0.40 0.03 03710.02 03910.03 a LLD at time of counting l 186 u__- _ __-_____- _- -____- ____ - - _ - _ _ ___-
l TABLE E-37 (Cont'd) Location CL-6 CL-7 CL-8 CL-11 Date Colleded 10-28-94 10-28 94 10-28 94 10 28 94 Gross Alpha 6.5811.83 12.84fl.85 8.79 11.60 9.9411.78 Gross Beta 21.0611.71 22.8411.50 19.24i136 203711.43 Be-7 <0.14 <0.28 <0.21 <0.20 K-40 18.4010.24 22.0710.50 16.84io.40 16.1810.43 Mn-54 <0.010 <0.028 <0.014 <0.018 Fe-59 <0.026 <0.045 <0.044 <0.049 Co-58 <0.011 <0.036 <0.020 <0.026 Co40 <0.010 <0.025 <0.016 <0.021 Zn-65 <0.047 <0.089 <0.063 <0.078 Nb-95 <0.027 <0.058 <0.045 <0.062 Zr-95 <0.024 <0.%8 <0.040 <0.046 Cs-134 <0.023 <0.037 <0.034 <0.042 Cs-137 <0.012 0.037i0.016 0.2710.02 0.4410.03 Ba-140a <0.031 <0.064 <0.051 <0.053 La-140a <0.011 <0.022 <0.017 <0.019 Ce-144 <0.084 <0.11 <0.10 <0.12 Ac-228 0.7010.04 12410.09 1.0810.059 13510.08 Bi-212 0.6710.10 1.0210.16 1.2110.22 1.42 0.26 Bi-214 0.4810.04 0.7310.04 0.76i0.03 0.8810.04 Pb-212 0.6810.02 1.1610.04 1.0810.03 133 0.04 Pb-214 0.59i0.02 0.8810.06 0.8710.04 0.97i0.05 Ra-226 1.0610.11 2.1210.32 1.7910.21 2.2410.25 TI-208 024t0.01 038i0.03 03510.02 0.4610.02 a LLD at time of counting 187
TABLE E-37 (Cont'd) location CL-15 CL-16A CL-94 pate Collected 10-28-94 10-27-94 10-28-94 Gross Alpha 8.4611.52 10.5011.78 12.92i2.20 Gross Beta 19.4311.36 23.5811.49 22.79i1.73 i Be 7 <0.21 <0.22 <0.29 K-40 18.07i0.44 21.8110.50 16.9510.65 Mn-54 <0.016 <0.017 <0.024 Fe-59 <0.058 <0.038 <0.034 I Co-58 <0.018 <0.028 <0.044 Co-60 <0.015 <0.017 <0.026 Zn-65 <0.070 <0.083 <0.11 Nb-95 <0.050 <0.048 <0.060 Zr 95 <0.080 <0.051 <0.022 Cs-134 <0.032 <0.037 <0.034 Cs-137 0.1110.02 <0.018 <0.027 Ba-1403 <0.057 <0.037 <0.043 La-1401 <0.014 <0.019 <0.016 Ce-144 <0.11 <0.12 <0.19 Ac-228 0.8410.07 1.0810.09 1.0910.10 Bi .212 0.7610.22 1.05f0.23 1.2010.25 Bi-214 0.5810.03 0.6710.04 0.91io.08 Pb-212 0.8810.03 1.0010.04 1.2310.06 Pb-214 0.7110.04 0.9310.05 1.07io.06 Ra-226 1.5210.23 1.5510.23 2.4810.36 TI-208 0.3010.02 0.3610.03 0.3910.04 a LLD at time of counting 188
i
'i l
I I I I i l i l FOR MOREINFORMATION, CALL OR WRITE The Radiation Protection Department t'. " "ll;;' S" " ILLINOIS aieten. =i#ei e'7" (217) 935-8881 POWER ____ _ _ _ _ _ _ _ - _ _}}