ML12226A070
ML12226A070 | |
Person / Time | |
---|---|
Site: | University of Illinois |
Issue date: | 06/28/2012 |
From: | Harpenau E M Oak Ridge Institute for Science & Education |
To: | Hickman J B NRC/FSME/DWMEP/DURLD/MDB |
References | |
DCN 5173-SR-01-0, RFTA No.12-006 | |
Download: ML12226A070 (60) | |
Text
MN OAK RIDGE VWMUTfE FOR SCENCE A EDUCATION Mamad by GRAU I. the U.S. DOwommp t of En.y June 28, 2012 Mr. John Hickman U.S. Nuclear Regulatory Commission Materials Decommissioning Branch Division of Waste Management and Environmental Protection Mail Stop T8F5 Rockville, MD 20852
SUBJECT:
FINAL REPORT-INDEPENDENT CONFIRMATORY SURVEY OF THE NUCLEAR RESEARCH LABORATORY AT THE UNIVERSITY OF ILLINOIS, URBANA-CHAMPAIGN, ILLINOIS; (DOCKET NO. 50-151;RFTA NO.12-006)DCN 5173-SR-01-0
Dear Mr. Hickman:
Oak Ridge Associated Universities (ORAU), under the Oak Ridge Institute for Science and Education (ORISE) contract, is pleased to provide the enclosed final report. The report details the confirmatory survey activities-performed during the week of May 7, 2012-for the Nuclear Research Laboratory at the University of Illinois located in Urbana-Champaign, Illinois.
Comments on the draft report submitted on June 26 have been incorporated.
You may contact me via my information below or Erika Bailey at 865.576.6659 if you require additional information.
Sincerely, Evan M. Harpenau Health Physicist/Assistant Project Manager Independent Environmental Assessment and Verification EMH:fr Enclosure cc: File/5173 electronic distribution:
J. Tapp, NRC EI. Bailey, ORAU W. Slawinski, NRC T. Vitkus, ORALU M. LaFranzo, NRC S. Roberts, ORAU Voice: 865.24L8793 Fax: 865.241.3497 E-mail:
P.O. Box 117 1 Oak Hidge. FN 3-17831 1 v-,,,wv).oriSe.0raL1.q1V INDEPENDENT CONFIRMATORY SURVEY OF THE NUCLEAR RESEARCH LABORATORY AT THE UNIVERSITY OF ILLINOIS URBANA-CHAMPAIGN, ILLINOIS E. M. Harpenau Prepared for the U.S. Nuclear Regulatory Commission Final Report Approved for public release; further dissemination unlimited, I The Oak Ridge Institute for Science and Education (ORISE) is a U.S. Department of Energy institute focusing on scientific initiatives to research health risks from occupational hazards, assess environmental cleanup, respond to radiation medical emergencies, support national security and emergency preparedness, and educate the next generation of scientists.
ORISE is managed by Oak Ridge Associated Universities.
NOTICES The opinions expressed herein do not necessarily reflect the opinions of the sponsoring institutions of Oak Ridge Associated Universities.
This report was prepared as an account of work sponsored by the United States Government.
Neither the United States Government nor the U.S. Department of Energy, nor any of their employees, makes any warranty, expressed or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe on privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, mark, manufacturer, or otherwise, does not necessarily constitute or imply its endorsement or recommendation, or favor by the U.S. Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the U.S. Government or any agency thereof.Universit., of Illinois 5173-SR-01-0 INDEPENDENT CONFIRMATORY SURVEY OF THE NUCLEAR RESEARCH LABORATORY AT THE UNIVERSITY OF ILLINOIS URBANA-CHAMPAIGN, ILLINOIS Prepared by E. M. Harpenau Oak Ridge Institute for Science and Education Oak Ridge, Tennessee 37831-0017 Prepared for the U.S. Nuclear Regulatory Commission FINAL REPORT ORISE JUNE 2012 Prepared by the Oak Ridge Institute for Science and Education, under interagency agreement (NRC FIN No. F1008) between the U.S. Nuclear Regulatory Commission and the U.S. Department of Energy. The Oak Ridge Institute for Science and Education performs complementary work under contract number DE-AC05-06OR23100 with the U.S. Department of Energy.University of flinois 5173-SR-01-0 N OAK UOtS "frTnmr FO Oa AND WOUCAlON M-npgd by ORAU or th. U.S. ODpwtmw, of &wW INDEPENDENT CONFIRMATORY SURVEY OF THE NUCLEAR RESEARCH LABORATORY AT THE UNIVERSITY OF ILLINOIS URBANA-CHAMPAIGN, ILLINOIS Prepared by: Reviewed by:<fýýýDate:
E. M. Harpenau',t'Assistant Project Manager v * , .A -.. ..Independent an.d Verification Date: 6P 2-Independent Assessment and Verification Reviewed by: Reviewed by: Approved for release by: IA&211 / 41ý4 , Date: t/2 e7/I, Ti'. P. Ivey, Lab/ora-7ry Group Manager Independent Environmental Assessment and Verification
/-2 /P. H. Bnton, Quality Assurance Specialist Independent Environmental Assessment and Verification6/ 1. Date: 6//;2 fj12 0/[Z E. N. Bailey, Survey Projects I'1iiager Independent Environmental Assessment and Verification FINAL REPORT June 2012 University of Illinois 517 3-SR-01-0 m DOR I S Eby W o th- UAL. DOpa -.nt o M.nor, CONTENTS FIG U RES .... .......................................................................................................................................................
TA BLE S ..........................................................................................................................................................
iii A CRO N Y M S ....................................................................................................................................................
iv 1. IN TRO D U CTIO N .......................................................................................................................................
1 2. SITE D E SCRIPTIO N .................................................................................................................................
2 3. O BJE CTIV ES ................................................................................................................................................
2 4. D O CU M EN T REV IEW .............................................................................................................................
2 5. A PPLICA BLE SITE G U ID ELIN ES ........................................................................................................
3 5.1 RELEASE CRITERIA FOR BUILDING SURFACES .....................................................................
3 5.2 RELEASE CRITERIA FOR VOLUMETRIC CONCRETE AND SOILS .........................................
4 6. SU RVE Y PRO CE D U RE S ..........................................................................................................................
5 6.1 REFERENCE SYSTEM .....................................................................................................................
5 6.2 SURFACE SCANS .............................................................................................................................
6 6.3 SURFACE A CTIVITY M EASUREM ENTS ...................................................................................
7 6.4 CONCRETE SAM PLING ..................................................................................................................
7 7. SAMPLE ANALYSIS AND DATA INTERPRETATION
............................................................
8 8. FIN D IN G S A N D RE SU LTS .....................................................................................................................
9 8.1 D OCUM ENT REVIEW .....................................................................................................................
9 8.2 SURFACE SCANS ...........................................................................................................................
10 8.3 SURFACE A CTIVITY M EASUREM ENTS .................................................................................
11 8.4 RAD IONUCLIDE CONCENTRATION IN CONCRETE ...........................................................
12 9. SU M M A RY ..................................................................................................................................................
13 10. RE FERE N CE S .........................................................................................................................................
15 University of Illinois i 5173-SR-01-0 N () / S Fi OK W40MUM O P M00 AMd EMM ATION M.n.opg. by OP"I f Iho. UAL Of E.M FIGURES Fig. 1. Confirmatory Sample Locations for the Bioshield and N16 Coolant Tunnel .........................
8 Fig. A-1. Alpha-plus-Beta data package for the Reactor Room ....................................................
A-1 Fig. A-2. Gamma data package for the Reactor Room .......................................................................
A-2 Fig. A-3. Alpha-plus-Beta data package for the Bioshield Exterior .....................................................
A-3 Fig. A-4. Gamma data package for the Bioshield Exterior ..................................................................
A-4 Fig. A-5. Alpha-plus-Beta data package for the Bioshield Interior .......................................................
A-5 Fig. A-6. Gamma data package for the Bioshield Interior ..............................................................
A-6 Fig. A-7. Alpha-plus-Beta data package for the Coolant Tunnel ..............................................
A-7 Fig. A-8. Gamma data package for the Coolant Tunnel .............................................................
A-8 Fig. A-9. Alpha-plus-Beta Data Package for the N16 TankVault
.............................................
A-9 Fig. A-10. Gamma Data Package for the N16 Tank Vault ....................................................
A-10 Fig. A-11. Alpha-plus-Beta Data Package for the Decay Tank ...............................................
A-11 Fig. A-12. Gamma Data Package for the Decay Tank ...................................................................
A-12 Fig. A-13. Alpha-plus-Beta Data Package for the Mechanical Room ..........................................
A-13 Fig. A-14. Gamma Data Package for the Mechanical Room .....................................................
A-14 Fig. A-15. Alpha-plus-Beta Data Package for the Source Areas ..................................................
A-15 Fig. A-1 6. Gamma Data Package for the Source Areas ..............................................................
A-16 Fig. A-17. Gamma Data Package for the Main Level ................................................................
A-17 Fig. A-18. Gamma Data Package for the Mezzanine Level ...................................................
A-18 University of Illinois ii 5173-SR-01-0 N C) R S E OAK F)OOU WIST1WVB FDM 90WOSUADUOID Mhkgod by DNAM 1w. tho U.S. DopnA-t rotf ffovg TABLES Table 1. Release Criteria for Building Surface and Material Contamination
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4 Table 2. DCGLs for Primary Radionuclides of Concern in Soil ..........................................................
5 Table 3. NRL Survey Units and Associated Classifications
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6 Table 4. Surface Activity M easurem ent Sum m ary ..............................................................................
11 Table B-1. Surface Activity Results for the Nuclear Research Laboratory
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B-1 Table B-2. Radionuclide Concentration in Concrete ................................................................................
B-3 Table B-3. Alpha Spectroscopy Results of Volumetric Concrete Samples .........................................
B-4 Table B-4. Inter-lab Comparison of Hard-to-Detect Sample Analysis ...........................................
B-5 Table B-5. Inter-lab Comparison of Gamma Spectroscopy Sample Analysis .................
B-6 University of Illinois iii 5173-SR-01-0 PD I a -b* PAU W iEi AI M&Dew Uof E ACRONYMS cpm DCGL DP dpm/100cm 2 ES FSS FSSP GAB LOPRA LVI MARSSIM MDC MDCR MeV NAD Nal NRC NRL ORAU ORISE pCi/g Q ROC SU TRIGA University counts per minute derived concentration guideline level decommissioning plan disintegrations per minute per 100 square centimeters EnergySolutions final status survey final status survey plan gross alpha and gross beta Low Power Reactor Assembly LVI Environmental Services, Inc.Multi-Agency Radiation Survey and Site Investigation Manual minimum detectable concentration minimum detectable count rate million electron volts no analytical data reported sodium iodide U.S. Nuclear Regulatory Commission Nuclear Research Laboratory Oak Ridge Associated Universities Oak Ridge Institute for Science and Education picocuries per gram quantile radionuclide of concern survey unit Teaching Research Isotope General Atomic University of Illinois is iv University of Elino 5173-SR-01
-0 N ()RI S !Li OA S TWT FPO SOMMEQ AND ION MI.-.gmd by AU r Mo UOw L .& P .pm..t of US INDEPENDENT CONFIRMATORY SURVEY OF THE NUCLEAR RESEARCH LABORATORY AT THE UNIVERSITY OF ILLINOIS URBANA-CHAMPAIGN, ILLINOIS 1. INTRODUCTION The University of Illinois (University)
Nuclear Research Laboratory (NRL) contained an Advanced Teaching Research Isotope General Atomic (TRIGA) Mark II swimming pool-type reactor designed by the General Atomic Division of General Dynamics Corporation.
Construction of the NRL began in the summer of 1959; construction was completed the following summer and the reactor achieved initial criticality on August 16, 1960. The NRL was operated under U.S. Nuclear Regulatory Commission (NRC) license R-1 15 and was operational until its permanent shutdown on August 6, 1998. A subcritical assembly, known as the Low Power Reactor Assembly (LOPRA), was added to the Bulk Shielding Tank on the south side of the reactor in 1971. The LOPRA used TRIGA fuel, and operated under its own NRC license (No. R-1 17) until 1995 when the LOPRA license was transferred to license R-115. NRC license R-117 was then terminated, and all reactor operations were conducted under license R-1 15 until reactor shutdown (ES 2006).The historical site assessment and initial site characterization activities were conducted in 2005 by Scientech, LLC to assess and detail the radiological status of the NRL facility.
The characterization activities determined that many reactor components and systems-including the soil under the building and some sub-surface structural components-were either radiologically activated, contaminated, or had a potential to contain residual contamination.
EnergySolutions (ES) prepared a facility decommissioning plan (DP) that detailed the methodology that would be used to achieve the unrestricted release of the NRL facility (ES 2006). The steps to achieve unrestricted release included: additional characterization surveys of the building and reactor process components, removal of activated/contaminated materials, and surveys for release of the remaining reactor components and building materials.
The material release program is intended to demonstrate that building materials/debris that will result from facility demolition do not have detectable radioactivity levels due to site operations.
Final status surveys (FSS) will be conducted on the remaining structural components and soils after demolition of the NRL.University of Illinois 1 5173-SR-01-0 N ()RISI-t !CM MO NA"M FM SOmN"M AND 8DCTON MPnagwd by0OADAJ .rth*LL&0Dw.bnwn
- o w At NRC's request, Oak Ridge Associated Universities (ORAU), operating under the Oak Ridge Institute for Science and Education (ORISE) contract, conducted in-process surveys/inspections and confirmatory survey activities of the NRL.2. SITE DESCRIPTION The University is approximately 110 miles southwest of Lake Michigan and 35 miles from the Illinois-Indiana border. The campus is centered on the dividing line for the adjoining cities of Urbana and Champaign.
The approximate 5,000 square foot NRL facility is located just south of the Engineering Sciences Building on the University's campus between Green and Springfield Streets.The NRL facility is divided into three levels: the lower level (reactor room), mezzanine level (offices, former control room, and restrooms), and storage level (located above the mezzanine with one office) (ES 2006).3. OBJECTIVES The objectives of the confirmatory activities were to provide independent contractor field data reviews, evaluate the licensee's survey process, and generate independent radiological data for use by the NRC in evaluating the adequacy and accuracy of the licensee's release survey results.4. DOCUMENT REVIEW Prior to on-site activities, ORAU staff reviewed the licensee's DP, final status survey plan (FSSP), guidance for pre-demolition surveys, and survey data sheets (ES 2006, ES 2007, and LVI 2012a and 2012b). The DP was specifically reviewed for historical information, as well as to identify the radionuclides of concern (ROCs) and the applicable release criteria.
The purpose of these reviews was to ensure that the regulatory requirements for release of the building materials were being met by the licensee and to develop the ORAU confirmatory survey plan. ORAU also reviewed Guidance for Pre-Demolition Surveys of Nuclear Research Laboratogy Building, University of Illinois Urbana-Champaign (LVI 2012a) to gather information detailing the criteria used for survey unit (SU) breakdown.
The licensee provided the survey data sheets to explain how their instrumentation detection capabilities were calculated.
ORAU was to ensure that the release survey activities within the NRL facility were adequate and appropriate, taking into account any supporting documentation and applicable University of Illinois 2 S1 71-SR-01 -0 N COR1 S it OAK RIDGE INTT9 O CSO N DCTO AMMod by ORAU for tIho ULM DepawbnoM o0 Vnorg'Multi-Agency Radiation Sun,ey and Site Investigation AMianiua/ (A/LAIRSSIM) guidance (NRC 2000). The University's FSSP was reviewed for information pertaining to derived concentration guideline levels (DCGLs) in soil in the event of soils becoming exposed during structural remediation.
Final status surveys will only be implemented to address the building footprint and immediate surrounding areas that remain after demolition (ES 2007).During the site visit, ORAU was provided two additional documents detailing the sampling guidance for concrete floor samples and guidance for release of the bioshield (LVI 2012c and 2012d).5. APPLICABLE SITE GUIDELINES The primary ROCs for the NRL are beta-gamma emitters-fission and activation products-resulting from reactor operation.
Alpha contamination was not identified during characterization nor decommissioning activities (LVI 2012a). During remediation of the reactor, additional concrete samples (cores) were collected from the area around the NRL tank wall and floor. These samples indicated that the only ROCs were europium-1 52 (Eu-152), cobalt-60 (Co-60), and tritium (H-3)(ES 2006). In addition to these ROCs, Table 2-4 in the DP, which was derived from NUREG-1640, identified iron-55 (Fe-55) and nickel-63 (Ni-63) as other potential concrete rubble contaminants.
Fe-55 was identified during the site characterization and was considered a possible soil contaminant.
Furthermore, carbon-14 (C-14) is mentioned as a primary ROC for soil in Table 2-3 of the DP. Like H-3, Fe-55, and Ni-63, C-14 is considered a hard-to-detect ROC associated with the operation of a TRIGA reactor.5.1 RELEASE CRITERIA FOR BUILDING SURFACES The radioactivity values presented in Table 1 were used to evaluate materials to be released for reuse, recycle, or disposal as clean waste. The release criterion approved for use at the NRL states that the materials will be free of detectable surface contamination in accordance with guidance provided by the NRC in IE Circular 81-07. This circular is specific to removal from radiologically restricted areas of items (tools and equipment) and materials (e.g., scrap material, paper products, and trash) that could potentially be contaminated.
The radioactivity limits shown in the Circular and provided in Table 1 represent the upper bound on the required detection capability of the survey procedures and instrumentation used. The licensee used standard survey instrumentation and smear samples to University of Illinois 3 5173-SR-01-0 N OA W4lflurF POH -M AND NIIATION M.n.b.gPd b O rAU UAL a.wb* of In9y survey the NRL materials.
A liquid scintillation counter with a minimum detectable concentration (MDC) of 1,000 dpm was used to determine activity on tritium smears (LVI 2012a). Furthermore, the licensee used an additional standard for volumetric radioactivity limits. These limits are provided in Table 1 as well. The total and removable surface activity data and volumetric sample data were compared with the respective limits.Net beta-gamma activity (dpm/ 100cm 2)5,000 15,000 1,000 Net alpha activity 100 300 20 (dpm/100cm2)
EI Crtei ..../Tritium 1.1 E-03 9.1 E+ 02 Leachate-indus trial Iron-55 1.5E-05 6.7E+04 Processing concrete Cobalt-60 2.0E+00 5.0E-01 Road building Nickel-63 1.5E-05 6.7E+04 Processing concrete Europium-152 8.8E-01 1.1E+00 Road building 5.2 RELEASE CRITERIA FOR VOLUMETRIC CONCRETE AND SOILS The concrete floor of the reactor room and remaining concrete bioshield were sampled for volumetric contamination levels prior to initiating pre-demolition surveys to ensure that volumetric contamination, if present, was less than the criteria provided in Table 2-4 of the NRL DP. The criteria in the NRL DP correspond to the values listed under "Recycling and Disposal of Concrete Rubble" and reproduced in Table 1.Determination of soil compliance will be demonstrated after the NRL demolition in accordance with the approved FSSP (LVI 2012a). The NRC default screening DCGLs and U.S. Environmental Protection Agency Memorandum of Understanding consultation triggers will be utilized for soil University of Illinois 4 5173-SR-01-0
() i I S Fl release (ES 2006). Though soil samples were not collected during remediation and release survey activities, radionuclide-specific screening levels are listed in Table 2.Cobalt-60 3.8 Europium-I 52 6.9 Tritium (H-3) 110 Carbon-14 12 Iron-55 10,000 Nickel-63 2,100 Cesium-137 11 Europium-154 8.0 6. SURVEY PROCEDURES At NRC's request, the ORAU survey team visited the University during the time period of May 8 through 10, 2012 to perform in-process and confirmatory survey activities.
The in-process and confirmatory survey activities included evaluation of the licensee's implementation of the methodologies as written in their guidance documents, visual inspections, surface scans, surface activity measurements, and sample collection.
The confirmatory survey activities were conducted in accordance with the approved project-specific plan and the ORAU Survey Procedures and Quality Program Manuals (ORAU 2012a, 2012b, and 201 la). Questions and concerns were brought to the immediate attention of the NRC and are also noted in the Findings and Results section of this report.6.1 REFERENCE SYSTEM Measurements and sampling locations were referenced to prominent site features and documented in the field logbook. Table 3 details the SU breakdown for the NRL during the survey for release phase.University of Illinois 5 5173-SR-01
-0 N ,C) U10I SI t_OAR PfUM VM .OM4 AND SUDA"OW M..wwgpd by ORAI for,* M& tL Wý Ow o f.'t Sul Lower Level Floor Including pit and tunnel surfaces; loading area floor 2 SU2 Bioshield Exterior surface of bioshield 2 SU3 Reactor Room Walls Flooring to ceiling (excluding mezzanine level 3 walls); heater/air units; pipes and ducts SU4 Reactor Room Ceiling Ceiling and horizontal surfaces (including 3 overhead mezzanine);
ventilation ducts; lights SU5 Mezzanine Level Floor and wall surfaces; ventilation system 3 components; furniture/
fixtures SU6 Main Level Floor and wall surfaces; ventilation system 3 components; furniture/fixtures; ceiling SU7 Roof Roof surface; ventilation components 3 SU8 Exterior Walls All exterior walls; cooling tower 3 SU9 Paved Areas Asphalt and concrete walkways 3 6.2 SURFACE SCANS Gamma scans were performed using sodium iodide (Nal) scintillation detectors coupled to ratemeter-scalers with audible indicators.
Alpha-plus-beta surface scans were performed using hand-held gas proportional detectors coupled to ratemeter-scalers with audible indicators.
Both Nal and gas proportional detector/instrument combinations were connected to hand-held electronic data collectors equipped with real-time data-logging software to record instrument response during scans.Confirmatory scan coverage during the confirmatory survey was based on the SU MARSSIM classifications presented in Table 3. Low-density scans were performed on the accessible surfaces in SUs 5 and 6. SUs 1 and 3 initially received medium-density scans of the floor and lower walls. The scans were increased to high density where elevated activity was detected.
High-density scans of all accessible areas were also performed in SU 2. Though the licensee's pre-demolition release survey approach did not designate any class 1 SUs, ORAU performed high-density scans of the class 2 SUs where significant remediation had been performed or when elevated activity was observed during initial confirmatory scans. Confirmatory surveys were planned for SUs 4, 7, 8, and 9. However, due University of Illinois 6 5173-SR-01-0
() !R / S i-K-obj OR Owemu 0~- MW UC.AI- .0 to the amount of investigative surveys performed in SUs 1, 2, 3, 5, and 6, ORAU was unable to survey the remaining four SUs before the end of the site visit.6.3 SURFACE ACTIVITY MEASUREMENTS Based on alpha-plus-beta scan results, direct surface measurements for total and removable alpha-plus-beta activity were performed at 39 judgmentally selected locations within the NRL. The locations were selected based on the elevated radiation levels identified by the ORAU survey team.In addition to alpha-plus-beta, alpha-only measurements were collected at 37 of the judgmental locations.
Direct measurements were performed by using hand-held gas proportional detectors coupled to ratemeter-scalers.
Due to the approved release criterion for beta-gamma contamination, ORAU collected material-specific background measurements within the large mechanical room where radiation levels were indicative of typical operating background for the gas proportional detectors.
Smear samples for gross alpha and gross beta (GAB) activity levels, and H-3/C-14 were collected primarily from non-remediated surfaces at the direct measurement locations.
The decision to collect either a GAB or H-3/C-14 smear was also based on material surface characteristics and/or correlation to reactor processes.
6.4 CONCRETE SAMPLING ORAU collected four concrete samples during confirmatory survey activities; three within the bioshield and one in the N16 coolant tunnel (Fig. 1). Samples were obtained from these areas due to increased activity measurements or at the request of the NRC. An additional five volumetric concrete samples collected and previously analyzed by the licensee were selected by the NRC and provided to ORAU for an inter-lab comparison.
University of Illinois 7 5173-SR-01-0 N C()RII SF1 aa O -wM PW -CM AN r0OTN im..~.gd by CPAM for he U.S Dtp..*.b.w of 3....g 5173M0001 5173M0002 5173M0008 5173M0009 Fig. 1. Confirmatory Sample Locations for the Bioshield and N16 Coolant Tunnel 7. SAMPLE ANALYSIS AND DATA INTERPRETATION Samples and data collected were returned to the ORAU/ORISE facility in Oak Ridge, Tennessee for analysis and interpretation.
All sample analyses were performed in accordance with the ORAU/ORISE Laboratory Procedures Manual (ORISE 2012). The concrete samples collected were analyzed by solid-state gamma spectroscopy for gamma-emitting ROCs. Fe-55 and Ni-63 concentrations were determined by radiochemical separation and then counted via liquid scintillation.
Samples 5173M0008 and 5173M0009 were also analyzed by alpha spectroscopy at NRC's request. Smears for GAB were analyzed with a gas flow proportional counter. Smears for H-3 and C-14 were analyzed via a liquid scintillation counter. Analytical results for the volumetric University of Illinois 8 5173-SR-01-0 N () t I S I-OAKl gADO We"r P0K *COUP AND GOATI0W klensd by OMWA o U.. " L De.P."-* t W.M samples are reported in units of picocuries per gram (pCi/g) and smear results in pCi/sample.
The data generated were compared with the approved NRC screening values as presented in Table 2.Appendices C and D provide further details on the survey and laboratory instrumentation and procedures used.8. FINDINGS AND RESULTS The results for each of the in-process and confirmatory survey activities are discussed in the following subsections.
8.1 DOCUMENT REVIEW Reviews of the documents provided prior to the site visit revealed multiple items of concern. First, the licensee divided the NRL facility into nine SUs with different MARSSIM classifications (LVI 2012a). However, none of the SUs were designated as Class 1 areas, even with extensive remediation performed on the bioshield, coolant tunnel piping, and N16 tanks. Section 4.4 of MARSSIM designates that Class 1 areas are those that have (or had prior to remediation) a potential for radioactive or known contamination above site release criteria.
This includes site areas subject to remedial actions, locations where leaks or spills have occurred, waste storage sites, and areas with contaminants in discrete solid pieces of material with high specific activity (NRC 2000).The next item of concern was the reference inputs on the licensee's survey data sheets. ORAU noticed that the scan MDC for total direct beta-gamma measurements in a completed survey data sheet exceeded 5,000 disintegrations per minute per 100 square centimeters (dpm/100 cm 2)(LVI 2012b). This resulted in conflicts between the licensee's two guidance documents.
The pre-demolition document said portable survey instruments would be capable of detecting total beta-gamma contamination at the release limit and set the minimum detectable count rate (MDCR)at approximately 7 5% of the release criteria (representative of approximately 3,750 dpm/100 cm 2 beta-gamma), which the licensee committed to (LVI 2012a). Conversely, the licensee stated that the measureable limit criteria for the bioshield equated to approximately 2,500 dpm/IOOcm 2 (beta/gamma) for concrete surface surveys, which is the limit set in the bioshield guidance document (LVI 2012d).University of Illinois 9 5173-SR-01-0 N C-1 R, I S Vi.CANJ POD= WtmU PM SMUM ,AND MurDTn-by OR&U kw t UA Depory..-
of Eoww Further review of the same completed survey data sheet revealed an uncharacteristically high number of negative beta-gamma surface activity results. This suggests that the reference background data inputs used may not have been appropriate for this SU. This sheet also included the application of the instrument efficiency for technetium-99 (Tc-99) to surface activity calculations even though C-14, a radionuclide with a lower detection efficiency, was one of the ROCs. This conflicts directly with calibration requirements of both Circular 81-07 and MARSSIM. Using the Tc-99 instrument efficiency versus the more restrictive C-14 efficiency could result in an overestimation of the instrument's detection capability; this would lead to an underestimation of surface activity.
To mitigate the possibility of underestimating surface activity, ORAU instrumentation was calibrated to the C-14 efficiency using a 0.4mg/cm 2 face on the gas proportional detectors.
8.2 SURFACE SCANS The gross count rates for alpha-plus-beta and gamma radiation surface scan data for each SU were prepared for report presentation using quantile (Q) plots. The Q-plots are presented in Appendix A.They are a graphical technique for determining if there is a common distribution in data sets. The advantage of the Q-plot is that population distributional aspects can be evaluated simultaneously.
The detectable aspects include:* Shifts in scale* Changes in symmetry (skewness of the data)" The presence of outliers Q-plots were generated by uploading the scan data files into the U.S. Environmental Protection Agency's ProUCL software.
In the Q-plots provided in Appendix A, the Y-axis represents observed count rates in counts per minute (cpm). The X-axis represents the data quantiles about the mean value. A normal distribution that is not skewed by outliers will appear as a straight line with the slope of the line subject to the degree of variability among the data population (i.e., a background radiation population).
Values less than the mean are represented in the negative quantiles, and values greater than the mean are represented in the positive quantiles.
The presence of more than one population--e.g., background radiation population and contamination-would display on a Q-plot as a step function.
Small areas of localized contamination will appear on the Q-plot as outlier points in the upper right quadrant.Ujniversity of Illinois1057-RI0 10 5173-SR-01-0 N (_ý) UZ S g7ýSNOnUM PW l SOO AND MOi& CATION km..eg" by ORM forth UAL. Dop..*b., of Un.ýg The ORAU survey team detected residual radioactivity in SUs 1, 2, 3, 5, and 6 while performing surface scans with hand-held gas proportional and Nal detectors.
Instrument response for alpha-plus-beta and gamma scans ranged from approximately 60 to 3,600 gross cpm and 2,800 to 24,000 cpm, respectively, over all SUs addressed during confirmatory surveys. The N16 Tank Vault had the highest alpha-plus-beta instrument response for walls due to the detection of localized contamination on the south wall and on the remaining pipe flanges leading into the coolant tunnel.The highest average instrument response for the floors occurred in the Sealed Source Cage. All other areas of elevated surface activity identified during confirmatory surveys were bounded, quantified, and reported to the onsite NRC inspector.
The Q-plots clearly show those SUs where contamination was detected during surface scans.8.3 SURFACE ACTIVITY MEASUREMENTS Total surface activity and removable activity levels for the 39 judgmentally determined measurement/sample locations are presented in Table B-1. Table 4 presents a summary of remaining activity levels.Total Alpha (dpm/ 100cm 2)37-14 to 820 Total Beta (dpm/100cm
- 2) 38 -1,200 to 15,000 Removable Alpha (dpm/100cm
- 2) 13 -1 to 6 Removable Beta (dpm/100cm
- 2) 13 0 to 184 Removable Tritium (pCi/sample) 21 -5.5 to 773.0 Removable Carbon-14 (pCi/sample) 21 -1.6 to 207.0 ORAU identified 31 pre-remediation locations above the conservative static measurement MDC of 690 dpm/100cm 2 for the alpha-plus-beta gas proportional detectors, 7 of which were above 5,000 dpm/100cm 2.Spot remediation was performed by the licensee, resulting in 29 locations still above the alpha-plus-beta MDC, and 4 still above 5,000 dpm/100cm 2 at the conclusion of the confirmatory survey. Material-specific backgrounds were used to correct gross counts prior to calculating the alpha-plus-beta surface activity.
Total remaining confirmatory survey alpha-plus-beta surface activity levels ranged from approximately 1,200 to 15,000 dpm/100 cm 2.University of Illinois 11 5173-SR-01-0 N ORI S E OA SUDOS~l 0I1fl~rflUatt F , O Manago by OPAJJ Sm Ow U.&. bopbnont of enmWg The highest reported surface activity of approximately 15,000 dpm/100 cm 2 was identified on the floor of the source cage. The second highest reported surface activity of approximately 10,000 dpm/100 cm 2 was observed on a conduit pipe on the exterior wall of the bioshield.
Additional surveys of this conduit did not reveal any alpha or gamma contamination.
The licensee committed to sealing the conduit and disposing of it in the proper waste stream when the remaining bioshield components were demolished.
The third highest activity (approximately 9,300 dpm/100 cm 2) was located on the south wall of the reactor room. Remediation was being performed on the third location, but the ORAU team departed the site before remediation of it or other locations could be confirmed.
The fourth and final location above 5,000 dpm/1OOcm2 was on the north wall of the decay tank with a surface activity of approximately 6,200 dpm/100 cm2.Alpha surface activity measurements were collected at several elevated activity locations identified during the alpha-plus-beta scans to ensure that the licensee's decision not to collect alpha measurements was justified.
Elevated alpha surface activity measurements were observed primarily in the concrete-lined coolant tunnel. Smears and a volumetric sample were collected from the coolant tunnel to determine if the observed alpha surface activity was due to contamination or radon gas buildup. Review of the analytical results indicated that the observed activity was due to radon in the tunnel.Laboratory analysis of the 13 smears collected in association with direct surface activity measurements identified a maximum gross beta contamination of 180 dpm/100 cm 2 on the conduit pipe of the bioshield.
All remaining GAB removable activity results ranged from -1 to 6 dpm/100 cm 2 and 0 to 9 dpm/100 cm 2 , respectively.
Removable activity for the hard-to-detect radionuclides across all SUs ranged from -6 to 770 pCi/sample for H-3, and -2 to 210 pCi/sample for C-14. The removable activity levels were below the release criteria.
The surface activity results are summarized in Table 4.8.4 RADIONUCLIDE CONCENTRATION IN CONCRETE Additional concerns were identified in the radiological analysis of the four confirmatory concrete samples collected from the bioshield and coolant tunnel. Review of the analytical results revealed concentrations of Co-60 in excess of the 0.5 pCi/g release limit for all samples, and two samples had concentrations in excess of the 1.1 pCi/g Eu-152 release limit (Table B-2).University of Illinois 12 5173-SR-01-0 N ()C UZI I WMK -POP SMA= AN 8LOAO I-bjV OAU Ow ow U.& B.P*....A of 0 W.At NRC's request, ORAU Samples 5173M0008 and 5173M0009 were also analyzed via alpha spectroscopy (Table B-3). Alpha spectroscopy results did not identify any concentrations of the ROCs above the respective release limits.The NRC also selected five of the licensee's split concrete samples and provided them to ORAU for an inter-lab comparison.
A full inter-lab comparison could not be performed on the samples provided due to insufficient reporting of the licensee's analytical results. Only a percentage of the licensee's samples were analyzed for the hard-to-detect ROCs, and a different percentage received gamma spectroscopy analysis.
The licensee's results were then reported as detects with known concentrations and errors, less than MDC (<MDC), or no analytical data reported (NAD). Before reporting the inter-lab comparison results, ORAU did observe that the licensee did not include C-14, cesium-137 (Cs-137), or Eu-154 as ROCs for the recycling and disposal of concrete rubble per NUREG-1640.
However, C-14, Cs-137, and Eu-154 were added to the initial ROC list in Table 3 which lists the primary ROCs in soils. Analytical results for each of the ROCs listed in Tables 2 and 3 have been included in the ORAU columns, even if the corresponding analysis had not been requested by the licensee (Tables B-4 and B-5).ORAU is of the opinion that the ROC list associated with the release of underlying soil should be consistent with the ROC list associated with the release criteria for the recycle and disposal of building rubble. This opinion was reached on the basis that the source of contamination would originate from within the building, and then would have to migrate through the construction materials in order to impact the soil.9.
SUMMARY
At NRC's request, ORAU conducted confirmatory survey activities within the NRL at the University during the week of May 7, 2012. The survey activities included visual inspections/
assessments, surface activity measurements, and volumetric concrete sampling activities.
During the course of the confirmatory activities, ORAU noted several issues with the survey-for-release activities performed at the University.
Issues included inconsistencies with: survey unit classifications were not designated according to MARSSIM guidance; survey instrument calibrations were not representative of the ROCs; calculations for instrumentation detection University of Illinois 13 5173-SR-01-0 N C)RIS E OAK ROIDD ROT"UTS FOR SCIENCE AND EDIJOATlON M-God by ORAUA 1w V. LLM D~p-b,-on Wf Eno-capabilities did not align with the release criteria discussed in the licensee's survey guidance documents; total surface activity measurements were in excess of the release criteria; and Co-60 and Eu-1 52 concentrations in the confirmatory concrete samples were above their respective guidelines.
Based on the significant programmatic issues identified, ORAU cannot independently conclude that the NRL satisfied the requirements and limits for release of materials without radiological restrictions.
University of Illinois 14 5173-SR-01-0 N C) 1<- I S t-OAK IM 0O~flU PMK SnOMS AM NDUA"0 Mm"Wegd hp OPAU ft O.. M& D~wt-A of. E 1 ww 10. REFERENCES ES 2006. Decommissioning Plan, Nuclear Research Laboratory Universio7 of Illinois at Champaign-Urbana.
Energy Solutions.
New Milford, Connecticut.
March 2.ES 2007. Final Status Survey Plan (FSSP) for the Nuclear Research Laboratoy Universiy of Illinois.Energy Solutions.
New Milford, Connecticut.
August 17.LVI 2012a. Guidance for Pre-Demolition Survges of Nuclear Research Laboratory Building, University of Illinois Urbana-Chamaign.
LVI Environmental Services, Inc. Shawnee, Oklahoma.LVI 2012b. BCS Bioshield 050112. Microsoft Excel Spreadsheet.
LVI Environmental Services, Inc.Shawnee, Oklahoma.
May 1.LVI 2012c. Guidance for Sampling Concrete FloorSuifaces.
LVI Environmental Services, Inc. Shawnee, Oklahoma.LVI 2012d. Guidance for Release ofBioshield.
LVI Environmental Services, Inc. Shawnee, Oklahoma.April 9.NRC 2000. Multi-Ageney Radiation Survey and Site Investigation Manual (MARSSIM).
NUREG-1 575;Revision 1. U.S. Nuclear Regulatory Commission.
Washington, DC. August.ORAU 2011 a. Quality Program Manualfor the Independent Environmental Assessment and Verification Program. Oak Ridge Associated Universities.
Oak Ridge, Tennessee.
December 1.ORAU 201 lb. ORAU/ORISE Radiation Protection Manual. Oak Ridge Associated Universities.
Oak Ridge, Tennessee.
December 3.ORAU 2012a. Project-Specific Plan for the Independent Confirmatory Survey Activities Associated with the Universfty of Illinois Nuclear Research Laboratogy, Urbana-Champaign, Illinois.
Oak Ridge Associated Universities.
Oak Ridge, Tennessee.
May 7.ORAU 2012b. Survey Procedures Manualfor the Independent EnvironmentalAssessment and Verification Program. Oak Ridge Associated Universities.
Oak Ridge, Tennessee.
June 1.ORAU 2012c. ORAU/ORISE Health and Safety Manual. Oak Ridge Associated Universities.
Oak Ridge, Tennessee.
May 18.ORISE 2012. Laboratory Procedures Manualfor the Independent EnvironmentalAssessment and Verification Program. Oak Ridge Institute for Science and Education, managed by Oak Ridge Associated Universities.
Oak Ridge, Tennessee.
April 25.University of Illinois 15 5173-SR-01-0 APPENDIX A SURVEY UNIT SUMMARIES Floor 2,705 453 3,127 1,001 900 405 XYV,1ll (OA I 1 A;7 9Q)9 979 li Th"WWcNQUuWN WWMNOnnO*RS.dWRomV~b.
AW..eg.Fig. A-1. Alpha-plus-Beta data package for the Reactor Room University of Illinois A-1 5173-SR-01-0 Floor 1,506 4,265 23,864 6,524 6,317 1204 Walls 1,154 4,811 10,355 6,642 6,357 1031 Theorftlc Quarnbe (Stenrd Naffra Fig. A-2. Gamma data package for the Reactor Room University of Illinois A-2 5173-SR-01-0 bltlohleld Lxterlor lop 0/3 ILl (LZ I 3u .54- / /BioShield Exterior Walls 3,163 56 1,361 257 247 97 Thimwofel uw* (bndwdMNouma Fig. A-3. Alpha-plus-Beta data package for the Bioshield Exterior University of Illinois A-3 5173-SR-01-0 I BinhiplrA F.tprinr 518 4.183 7.(58 5.573 5.564 383 1 ThFig. A muwtacae orthled BNoms E Fig. A-4. Gamma data package for the Bioshield Exterior University of Illinois A-4 5173-SR-01-0 Upper Walls 515 103 470 256 245 68 Lower Walls 3,123 51 1,273 324 313 103 hOMO m -IN --M~dNVm Fig. A-5. Alpha-plus-Beta data package for the Bioshield Interior University of Illinois A-5 5173-SR-01-0 I All Surfaces 859 5.340 21A08 8.058-'00),)():: I ThaoroftD pacag foW hi no Fig. A-6. Gamma data package for the Bioshield Interior University of Illinois A-6 5173-SR-01-0 SAllSurfaces 1,856 118 928 422 408 126 1 7 --- -u-- " W.Fig. A-7. Alpha-plus-Beta data package for the Coolant Tunnel University of Illinois A-7 5173-SR-01-0 I AUl Surfaces 444 4.109 8.391 6A422 6.693 904 1 Fig. A-8. Gamma data package for the Coolant Tunnel University of Illinois A-8 5173-SR-01-0 nloor 2I 111/ 35. zzb ZZO 6VO Walls 2,103 79 3,622 310 270 284 Ceiling 376 76 458 231 225 65/a Thwc.ItWQuuds.
MStudwd NOMMul Fig. A-9. Alpha-plus-Beta Data Package for the N16 TankVault University of Illinois A-9 5173-SR-01-0 Floor 274 4,436 6,287 5,085 5,024 358 Walls 830 3,430 6,306 4,691 4,701 480 Ceiling 101 2,842 4,968 3,616 3,547 421 Theaubfel uanblow Umndu~d Norn*l M 6 Tu* Wb-s. OýFig. A-10. Gamma Data Package for the N16 Tank Vault University of Illinois A-10 5173-SR-01
-0 Floor 226 200 677 392 386 88 Walls 702 104 1,235 372 349 135 V*DSc.To*
VAN- Abhm+d.Fig. A-11. Alpha-plus-Beta Data Package for the Decay Tank University of Illinois A-1 1 5173-SR-01-0 I All Surfaces 392 5,613 8,576 6,894 6,851 461 1 ThFiti A1 GQummiaD ta (Standard Norma y Fig. A-12. Gamma Data Package for the Decay Tank University of Illinois A-12 5173-SR-01-0 Floor 368 530 1,269 891 885 130 Walls 1,733 61 502 250 247 65 1bworeftl um. lee stwUidwd NormaO#MeOWdc.I="ft-A-*
Fig. A-13. Alpha-plus-Beta Data Package for the Mechanical Room University of Illinois A-13 5173-SR-01-0 Floor 162 4,501 6,557 5,591 5,639 379.3 Walls 297 4,742 6,946 5,761 5,766 357.1 Small Mech.Room 194 4207 7232 5767 5873 All Surfaces 696 TheomredlQuantile (Stwidard Normalj 0-Vwcwof~~s-
ýA S-8 mww~ ftm, AU &,sc.- Go,,, Fig. A-14. Gamma Data Package for the Mechanical Room University of Illinois A-14 5173-SR-01-0 Walls 958 100 620 281 276 77 ThwrooWQuwu
(*kdmrd Normnu Fig. A-15. Alpha-plus-Beta Data Package for the Source Areas University of Illinois A-15ýS1 73-SR-01 -0 NE Well 53 3,536 6,655 4,531 4,102 926 NW Well 67 3,620 6,657 4,429 4,247 605 SE Well 78 3,821 7,021 4,568 4,407 704 SW Well 83 3,946 6,122 4,435 4,349 364 Lower Level 135 5,484 7,954 6,610 6,598 511 Cage Thowedcal OuwMes (Sterodwd Not K" S- wd -Qý*L.-U.*CWA1&O*OW-Gý Fig. A-16. Gamma Data Package for the Source Areas University of Illinois A-16 5173-SR-01-0 I", -, R , MIR- w-Floor 265 5,437 8,701 7,175 7,228 721 Walls 214 6,259 9,728 8,151 8,273 776 Th"reftid MWIM" OWndwd NWM*Q*Main L&M Waft -0ýFig. A-17. Gamma Data Package for the Main Level University of Illinois A-17 5173-SR-01-0 (immila Scall Summary for INIezzalline IC-\7cl Floor 239 4,603 6,863 5,700 5,633 474 Walls 292 4687 7428 5825 5793 473 fwomt OuminSbndw
-Fig. A-18. Gamma Data Package for the Mezzanine Level University of Illinois A-1 8 5173-SR-01-0 APPENDIX B TABLES 03 0 5173R0001 Reactor Room-Floor 14 3,300 n/a n/a n/a n/a 5173R0002 Reactor Room-Floor 7 3,700 n/a n/a n/a n/a 5173R0003 Reactor Room-Floor 7 4,200 n/a n/a n/a n/a 5173R0004 Reactor Room-Floor 43 2,400 n/a n/a n/a n/a 5173R0005 Bioshield-Floor 14 4,000 310 -1 1 0.1 3.0 5173R0006 Bioshield-Floor 14 1,800 n/a n/a n/a n/a 5173R0007 Bioshield-Wall 7 9,800 2,100 -1 8 261.0 207.0 5173R0008 Bioshield-Wall 0 1,800 n/a n/a n/a n/a 5173R0009 Bioshield-Wall
-7 610 n/a n/a n/a n/a 5173R0010 Bioshield-Wall 0 1,200 n/a n/a n/a n/a 5173R001 1 Bioshield-WalU 36 1,300 n/a n/a n/a n/a 5173R0012 Bioshield-Wall 7 540 n/a n/a n/a n/a 5173R0013 Bioshield-Wall 14 1,400 n/a n/a n/a n/a 5173R0014 Bioshield-Wall 0 1,400 770 n/a n/a n/a n/a 5173R0015 Bioshield-Wall 0 1,700 n/a n/a n/a n/a 5173R0016 Bioshield-Wall 7 4,000 -150 -1 2 10.7 15.0 Conduit 5173R0017 Bioshield-Wall n/a 10,000 6 184 773.0 187.0 5173R0018 Tunnel-Wall 950 640 3,400 2,200 4 9 1.2 1.3 5173R0019 Tunnel-Wall 640 560 3,300 1,900 4 9 -1.3 1.5 5173R0020 Tunnel-Wall 760 820 2,700 1,800 4 1 4.2 8.7 5173R0021 Tunnel-Wall 65 120 2,700 280 -1 6 -3.3 -0.8 5173R0022 Tunnel-Wall 760 520 2,000 1,000 6 0 11.3 9.1 C (b C C 5173R0023 Tunnel-Ceiling 700 330 640 1,300 n/a n/a 3.8 12.4 5173R0024 Tunnel-Ceiling 820 460 1,600 2,000 n/a n/a 5.1 14.7 5173R0025 Tunnel-Ceiling 120 -820 n/a n/a -5.4 3.6 5173R0026 Tunnel-Ceiling 43 -1,200 n/a n/a -3.0 3.0 5173R0027 Tunnel-Ceiling 58 580 n/a n/a -5.5 2.5 5173R0028 Decay Tank-Wall 36 6,200 -1 3 -4.1 2.1 5173R0029 Reactor Room-Wall 0 9,300 n/a n/a n/a n/a 5173R0030 W. Beam Port-Wall 22 3,000 n/a n/a n/a n/a 5173R0031 NE Beam Port-Wal]
-7 3,600 n/a n/a n/a n/a 5173R0032 E Beam Port-Wall 36 2,600 n/a n/a n/a n/a 5173R0033 N16 Pipe Flange -14 6,400 730 1 4 4.0 4.1 N16 Tank Room-5173R0034 WNal 280 100 24,000 -540 -1 1 -2.8 -0.3 5173R0035 N16 Tank Room- 220 530 n/a n/a -2.5 1.5 Ceiling N16 Tank Room-5173R0036 Floor 43 870 n/a n/a -2.5 -1.6 N16 Tank Room-5173R0037 Nage Trnc n/a n/a n/a n/a 0.4 1.8 Drainage TrenchI 5173R0038 Source Cage-Floor 22 15,000 -1 4 -3.8 2.0 5173R0039 Reactor Room-Floor
-14 3,600 n/a n/a n/a n/a-1'7" (0 5173M0001a 6.96 0 0.45b 0.32 +/- 0.20 3.52 +/- 0.26 0.04 +/- 0.09 11.06 +/- 3.02 0.85 +/- 0.66 35.3 +/- 3.8 1.5 +/- 1.9 5173M0002c 0.33 +/- 0.09 -0.11 +/- 0.25 3.18 +/- 0.23 0.09 +/- 0.07 -1.06 +/- 2.45 2.96 +/- 0.76 17.5 +/- 2.9 33.2 +/- 3.4 5173M0003d
-0.02 +/- 0.07 0.03 +/- 0.04 -0.01 +/- 0.05 0.01 +/- 0.03 -3.32 +/- 2.34 0.72 +/- 0.65 0.1 +/- 2.5 0.7 +/- 1.8 5173M0004e
-0.10 +/- 0.10 -0.10 +/- 0.21 0.02 +/- 0.06 0.00 +/- 0.05 -4.13 +/- 2.36 1.05 +/- 0.67 0.5 +/- 2.5 -0.4 +/- 1.7 5173M0005f
-0.03 +/- 0.07 -0.11 + 0.12 0.00 +/- 0.04 -0.01 +/- 0.03 0.39 +/- 2.51 1.46 +/- 0.68 0.2 + 2.6 0.2 +/- 1.8 5173MOO06g 0.07 +/- 0.11 0.07 +/- 0.18 0.05 +/- 0.06 0.04 +/- 0.04 -3.42 +/- 2.39 1.15 +/- 0.67 2.1 +/- 2.6 -0.1 +/- 1.8 5173M0007h
-0.02 +/- 0.05 -0.01 + 0.06 0.01 +/- 0.03 0.01 +/- 0.02 -2.91 +/- 2.38 0.79 +/- 0.66 0.9 + 2.6 0.3 +/- 1.8 5173M0008i 7.82 +/- 0.46 0.28 +/- 0.18 2.57 +/- 0.18 0.11 +/- 0.04 10.76 +/- 2.99 0.79 +/- 0.65 128.6 +/- 7.2 8.2 +/- 2.0 5173MOO09j 0.07 +/- 0.07 -0.17 +/- 0.25 0.54 +/- 0.07 0.00 +/- 0.05 2.96 +/- 2.6 1.43 +/- 0.69 4.3 +/- 2.7 1.7 +/- 1.8'Sample collected from south floor inside the bioshield bUncertainties are reported at the 95% confidence interval cSample collected from west floor/wall interface inside the bioshield dORAU/ORISE Laboratory analysis of licensee sample SS-RRF-006 (2)cORAU/ORISE Laboratory analysis of licensee sample SS-RRF-013 (2)fORAU/ORISE Laboratory analysis of licensee sample SS-LAF-001 (2)gORAU/ORISE Laboratory analysis of licensee sample UI-NTF2-2 (2)hORAU/ORISE Laboratory analysis of licensee sample SS-BCT-NW (2)iSample collected from west beam port of the bioshield iSample collected from the N16 coolant tunnel upper wall under the bioshield U--
5173M0008 0.00 +/- 0.02a 0.01 +/- 0.02 0.01 +/- 0.01 0.51 +/- 0.07 0.33 +/- 0.05 0.29 +/- 0.06 0.01 +/- 0.01 0.31 +/- 0.06 C E" 5173M0009 0.00 +/- 0.02 0.02 +/- 0.03 0.01 +/- 0.01 0.29 +/- 0.05 0.23 +/- 0.05 0.36 +/- 0.07 0.02 +/- 0.01 0.41 +/- 0.07 alUncertainties are reported at the 9 5% confidence interval.rJ) 2.0 5173M0003 SS-RRF-006 5173M0004 SS-RRF-013 5173M0005 SS-LAF-001 5173M0006 UI-NPF-2-2 5173M0007 SS-BCT-NW 0.1 +/- 2.5a 0.5 +/- 2.5 0.2 +/- 2.6 2.1 +/- 2.6 0.9 + 2.6<MDC (2.73)b<MDC (2.57)<MDC (2.00)<MDC (2.52)<MDC (2.26)-3.3 +/- 2.3-4.1 +/- 2.4 0.4 +/- 2.5-3.4 +/- 2.4-2.9 _ 2.4<MDC (32.7)<MDC (24.6)NADC NAD NAD 0.72 +/- 0.65 <MDC (0.45)1.05 +/- 0.67 1.46 + 0.68 1.15 +/- 0.67 0.79 +/- 0.66<MDC (0.46)NAD NAD NAD'Uncertainties are reported at the 95% confidence interval.bParenthetical value represents the minimum detectable concentration of the respective contaminant in each sample.cNAD=No analytical data was provided in the licensee's analysis report.ILI 2.0 0 5;5173M0003 SS-RRF-006 5173M0004 SS-RRF-013 5173M0005 SS-LAF-001 5173M0006 UI-NPF-2-2 5173M0007 SS-BCT-NW-0.01 +/- 0.05b NAD, 0.01 +/- 0.03 NAD-0.02 +/- 0.07 NAD 0.02 +/- 0.06 0.00 +/- 0.04 0.05 +/- 0.06 0.01 + 0.03 NAD<MDC (0.04)c<MDC (0.08)<MDC (0.05)0.00d +/- 0.05-0.01 +/- 0.03 0.04 +/- 0.04 0.01 + 0.02 NAD<MDC (0.04)<MDC (0.07)<MDC (0.05)-0.10 +/- 0.10-0.03 +/- 0.07 0.07 +/- 0.11-0.02 + 0.05 NAD<MDC (0.09)<MDC (0.19)<MDC (0.11)'Laboratory analysis was not requested by the licensee.bUncertainties are reported at the 95% confidence interval.cNAD=No analytical data was provided in the licensee's analysis report.dZero values for sample results are due to rounding.eParenthetical value represents the minimum detectable concentration of the respective contaminant in each sample.U,'-I3 APPENDIX C MAJOR INSTRUMENTATION The display of a specific product is not to be construed as an endorsement of the product or its manufacturer by the author or his employer.C.1 SCANNING AND MEASUREMENT INSTRUMENT/DETECTOR COMBINATIONS C.1.1 GAMMA Ludlum Nal Scintillation Detector Model 44-10, Crystal: 5.1 cm x 5.1 cm (Ludlum Measurements, Inc., Sweetwater, TX)coupled to: Ludlum Ratemeter-scaler Model 2221 (Ludlum Measurements, Inc., Sweetwater, TX)C.1.2 ALPHA PLUS BETA Ludlum Gas Proportional Detector Model 43-68, Physical area: 126 cm'(Ludlum Measurements, Inc., Sweetwater, TX)Coupled to: Ludlum Ratemeter-scaler Model 2221 (Ludlum Measurements, Inc., Sweetwater, TX)Coupled to GeoXH Receiver and Data Logger (Trimble Navigation Limited, Sunnyvale, CA)Ludlum Pancake Probe Model 44-9, Physical area: 126 cm2 (Ludlum Measurements, Inc., Sweetwater, TX)Coupled to: Ludlum Ratemeter-scaler Model 2221 (Ludlum Measurements, Inc., Sweetwater, TX)C.2 LABORATORY ANALYTICAL INSTRUMENTATION High-Purity, Extended Range Intrinsic Detector CANBERRA/Tennelec Model No: ERVDS30-25195, two units: 26.3% and 27.70/% efficiencies (Canberra, Meriden, CT)Used in conjunction with: Lead Shield Model G-I 1 (Nuclear Lead, Oak Ridge, TN) and Multichannel Analyzer Canberra's Apex Gamma Software Dell Workstation (Canberra, Meriden, CT)University of Illinois C-1 5173-SR-01-0 High-Purity, Extended Range Intrinsic Detector Model No. GMX-45200-5, 45% efficiency (AMETEK/ORTEC, Oak Ridge, TN)used in conjunction with: Lead Shield Model SPG-1 6-K8 (Nuclear Data)Multichannel Analyzer Canberra's Apex Gamma Software Dell Workstation (Canberra, Meriden, CT)High-Purity Germanium Detector Model GMX-30-P4, 30% Eff.(EG&G, Oak Ridge, TN)Used in conjunction with: Lead Shield Model G-16 (Gamma Products, Palos Hills, IL) and Multichannel Analyzer Canberra's Apex Gamma Software Dell Workstation (Canberra, Meriden, CT)Alpha Spectrometry System Tennelec Model 256 (Canberra, Meriden, CT)Used in conjunction with: Ion Implanted Detectors and Multichannel Analyzer Canberra Apex Alpha Software Dell Workstation (Canberra, Meriden,CT)
Alpha Spectrometry System Canberra Model 7401VR (Canberra, Meriden, CT)Used in conjunction with: Ion Implanted Detectors and Multichannel Analyzer Canberra Apex Alpha Software Dell Workstation (Canberra, Meriden, CT)Low-Background Gas Proportional Counter Model LB-5100-W (Tennelec/Caberra, Meriden, CT)Low-Background Gas Proportional Counter Model LB-5100-W University of Illinois C-2 5173-SR-0"1-0 (Tennelec/Canberra, Meriden, CT)Tri-Carb Liquid Scintillation Analyzer Model 3100 (Packard Instrument Co., Meriden, CT)Tri-Carb Liquid Scintillation Analyzer Model 3100 (Packard Instrument Co., Meriden, CT)University of Illinois C-3 5173-SR-01-0 APPENDIX D SURVEY AND ANALYTICAL PROCEDURES D.1 PROJECT HEALTH AND SAFETY The proposed survey and sampling procedures were evaluated to ensure that any hazards inherent to the procedures themselves were addressed in current job hazard analyses.
Prior to on-site activities, a pre-job integrated safety management checklist was completed and discussed with field personnel.
Additionally, upon arrival at the site, contractor representatives provided Oak Ridge Associated Universities (ORAU)with general safety information within the project area. The planned activities were thoroughly discussed with site personnel prior to implementation to identify hazards present.All survey and laboratory activities were conducted in accordance with ORAU health and safety and radiation protection procedures (ORAU 2012c and 2011 b).D.2 CALIBRATION AND QUALITY ASSURANCE Calibration of all field and laboratory instrumentation was based on standards/sources, traceable to National Institute of Standards and Technology (NIS'1).Analytical and field survey activities were conducted in accordance with procedures from the following documents of the Independent Environmental Assessment and Verification (IEAV)Program:* Survey Procedures Manual (ORAU 2012b)" Laboratory Procedures Manual (ORISE 2012)" Quality Program Manual (ORAU 2011a)The procedures contained in these manuals were developed to meet the requirements of U.S. Department of Energy (DOE) Order 414.1C and the U.S. Nuclear Regulatory Commission (NRC) Qualiy Assurance AMIanualfor the Q/jlce of Nuclear Material Safet and Sqfeguards and contain measures to assess processes during their performance.
Quality control procedures include:* Daily instrument background and check-source measurements to confirm that equipment operation is within acceptable statistical fluctuations University of Illinois D-1 5173-SR-01-0
- Participation in Mixed Analyte Performance Evaluation Program (MAPEP), NIST Radiochemistry Intercomparison Program (NRIP), and Intercomparison Testing Program (JTP) Laboratory Quality Assurance Programs* Training and certification of all individuals performing procedures" Periodic internal and external audits D.3 SURVEY PROCEDURES D.3.1 SURFACE SCANS Scans for elevated gamma radiation were performed by passing the detector slowly over the surface.The distance between the detector and surface was maintained at a minimum. Specific scan MDCs for the Nal detector was not determined as the instrument were used solely as a qualitative means to identify elevated gamma radiation levels in excess of background.
The identification of elevated radiation levels that could exceed the site criteria were determined based on an increase in the audible signal from the indicating instrument.
Beta scans were performed using small, hand-held gas proportional detectors with a 0.4 mg cm-window. Identification of elevated radiation levels was based on increases in the audible signal from the indicating instrument.
Beta surface scan minimum detectable concentrations (MDCs) were estimated using the approach described in NUREG-1 507. The scan MDC is a function of many variables, including the background level. Additional parameters selected for the calculation of scan MDCs included a two-second observation interval, a specified level of performance at the first scanning stage of 95% true positive and 25% false positive rate, which yields a d' value of 2.32 (NUREG-1507, Table 6.1), and a surveyor efficiency of 0.5. The beta total efficiency was 0.10 for C-14. The detector used had a background of 305 cpm for concrete.
The minimum detectable count rate (MDCR) and scan MDC was calculated as: Bi = (305)(2 s)(1 main/60 s) = 10 counts MDCR = (2.32)(10 counts)1 1 2[(60 s/min)/2s]
= 220 cpm MDCRs.eyor z 220/(0.5)I/2
= 311 cpm Scan MDC = (311)/[(.10)(1.26)]
= 2,468 dpm/100 cm 2 University of Illinois D-2 5173-SR-01-0 D.3.2 SURFACE ACTIVITY MEASUREMENTS Measurements of total beta surface activity levels were performed using hand-held gas proportional detectors coupled to portable ratemeter-scalers.
Count rates (cpm), which were integrated over one minute with the detector held in a static position, were converted to activity levels (dpm/100 cm 2) by dividing the count rate by the total static efficiency and correcting for the physical area of the detector.
ORAU collected material-specific backgrounds for each surface type encountered.
The respective material-specific background was then subtracted from the direct gross count when determining surface activity.
The apriori MDC for beta activity is given by: MDC = 3 + (4.65V')G Etot Where: B background F-tot = total efficiency G geometry correction factor (1.26)The apriori beta static MDC was approximately 688 dpm/100 cm 2 for C-14.D.3.3 REMOVABLE ACTIVITY MEASUREMENTS Removable gross alpha and gross beta activity levels were determined using numbered filter paper disks, 47 mm in diameter.
Moderate pressure was applied to the smear and approximately 100 cm 2 of the surface was wiped. Smears were placed in labeled envelops with the location and other pertinent information recorded.For tritium and C-14 determinations, a second smear was moistened with deionized water and an adjacent 100 cm 2 was wiped. The smear was then sealed in a labeled liquid scintillation vial with the location and pertinent information recorded.D.3.4 CONCRETE SAMPLING Approximately 0.5 kilogram of concrete was collected for samples 5173M0001, 5173M0002, and 5173M0008.
ORAU personnel were only able to collect approximately 0.2 kilograms for sample 5173M0009.
Each sample was placed in a plastic bag, sealed, and labeled in accordance with ORAU survey procedures.
University of Illinois D-3 5173-SR-01-0 D.4 RADIOLOGICAL ANALYSIS D.4.1 GAMMA SPECTROSCOPY Samples were dried, mixed, crushed, and/or homogenized as necessary, and a portion sealed in a 0.5-liter Marinelli beaker or other appropriate container.
The quantity placed in the beaker was chosen to reproduce the calibrated counting geometry.
Net material weights were determined and the samples counted using intrinsic germanium detectors coupled to a pulse height analyzer system.Background and Compton stripping, peak search, peak identification, and concentration calculations were performed using the computer capabilities inherent in the analyzer system. All total absorption peaks (TAP) associated with the ROCs were reviewed for consistency of activity.
TAPs used for determining the activities of ROCs and the typical associated MDCs for a one-hour count time are displayed in Table D-1.Eu-152 0.344 0.13 Eu-154 0.723 0.28 Co-60 0.661 0.06 Cs-1 37 1.173 0.08 Spectra were also reviewed for other identifiable TAPs.D.4.2 GROSS ALPHA/GROSS BETA ANALYSIS Smears were counted on a low-background gas proportional system for gross alpha and beta activity.The minimum detectable activities (MDA) of the procedure were 11 dpm and 14 dpm for alpha and beta, respectively.
D.4.3 TRITIUM ANALYSIS Analyses for tritium were performed by placing a smear or a representative portion of the samples into a scintillation cocktail and counting on a liquid scintillation analyzer.
Samples were then spiked with a known amount of the appropriate standard and recounted.
The MDA of the procedure was 16.8 pCi.D.4. DETECTION LIMITS Detection limits, referred to as minimum detectable concentrations (MDCs), were based on 95%University of Illinois D-4 5173-SR-01-0 confidence level via NUREG 1507 method. Because of variations in background levels, measurement efficiencies, and contributions from other radionuclides in samples, the detection limits differ from sample to sample and from instrument to instrument.
University of Illinois D-5 5173-SR-01-0