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Home My WebLink About20070812 Ver 1_Badin Lake PCB Capping_20110629lJ? Pce 617-qll ) I-OL6 r4 c-Dow? V3 vAi io to -a?rz 5 aoeo? C)q2m uf Ave_ 7n t-- V 6 ?41te_ Y\z nPIGn? collect-- 6-44b+"l-9 ?-¢?mecPi?1d" ?j(?J2s ?rless? ? EPP u^^rf ?,? 7-Sqfl- " `? l?o?ll y?ri' z3? v aci 5)1?? 4qc?w BPE o?-- S YVJ 013 (? l (lo 12 ( 2 l ?l ?uj m Key _ nr r 4?M- t 1 7V o vvv.?. u+? h 35?+dA,p 1s; t)5 1#3-4-wlvjd? C-11-1 ?? 'tom 1???, ??s?, ,?u,,r ?-t? ?v?+?(S? ? rANA in ?? ?-"O? -kd- r*vt? No"tk-&Jp? , 7 s 25-4- ,vY. Car?s ?- 4?? ?w°?a ? cQ.o?uTnr?3 sue' u? 149U' S. olpn ts?r cj-As(qo-D+ Gvr2 a?oa? V V C2?r ?q ((Ojce- PeAk- rip?? ? Ill ?{,tcAc2? r?i,?G?.-, I I <L djffc?k Sued ? ?????? w?a? Csu?? v1l prYwtariu? Ccx a?Jc?'? Ca.,??,) ",O-Q P Tvl?+f 7b l?J? I? ?lJ?oc?C a- ?u? ?/??p-?•?C04-10- 1? "Mwe. dam 0YP '???' ?C?p?wzf 'MA A Lt y,&. I_ pCl-eC+ Ovrvnb? ?J Uv? ('h ,? ?Y? 4[ ..J U? " U F_ Qc e-vr) ?^eM rcio V?oss?ble La.A-J?mWIIA ? 485?sa.1- aojw,??Vle_ na4HD (\We7k- ?,4, 5wi- m?--, ?d.ocA. CVrou.? Alk-f- ,l 40J- U? A-CPlv\? ?.?C?IZ ,cessr'or ?Qnn. ane 60tl"- q1„a?? s IC"? ?ej mod. c6 I,- \Ox-p- V V DAVID GLASER, PH.D. ANCHOR 305 West Grand Avenue kt, Suite 300 OEAc_.c?v ? Montvale, NJ 07645 dglaser@anchorgea.com T 201.930.9890 F 201.930.9805 C 201.988.2656 JOHN R. VERDUIN III, P.E. Principal Engineer - ANCHOR 720 Olive Way 0EA c,w Suite 1900 Seattle, WA 98101 T 206.287.9130 F 206.287.9131 jverduin@anchorqea.com Defining Environmental Solutions www.bheenvironmental.com TIMOTHY P. GESSNER, PE, MBA Vice President Engineering & Site Assesment Direct 513.326.1518 ENVIRONMENTAL Mobile 513.312.7469 Fax 513.326.1550 tgessner@bheenvironmental.com BHE Environmental, Inc. 513.326.1500 11733 Chesterdale Road Cincinnati, Ohio 45246 N N N 3 ? ? I ?I II m F w m:.. I d XU. m ? a a o ? ?IH r U ' > i o a c 9 Ca S I Lm d, ?: , rc d H a a Z r 8 a °f LL, , H v a C E • q LL U 0 d' co?'...; N Hi i Z a . C W C LL 2 W u = L0; Z 9 2 N F AM ' 00 a i a € 3 • L) s a J S IL N a N N N N a A N n n 6 04 u . 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S S C 23 tS LL z t5 i b ui m '?° ?' m E• v u 'E Q d E € _' a 5 v O U Ca9 'Q Y r 01 j? a s d? woo .0 W e m Q °¢ a g' m a a° Q O m Q uj a U Z x a c°? c°) U w !0 K Q a IL V c U 'v N J mW H iQ Q ? I I 1.., .,..? ..? ,' a0 ' 01 0, o N N 1" in C4 ...N .IN I I,.?.... N M O Lin fI0 t0 .. ii- co N N ?M .. 0 ..,.t0 Ifs m 01 O N M j a Q O IN M f 1H Ito Its A y I r ? '? ? I Ito II 0 N lO ,M M M ?M ? M M ;M '.M M V O e Y • Docket # 00 -SF- X55 IN RE: NORTH CAROLINA DEPARTMENT OF ENVIRONMENT ...AND NATURAL RESOURCES .: . DIVISION OF WASTE MANAGEMENT SUPERFUND SECTION ALCOA NARROWS POWERHOUSE BADIN, NORTH CAROLINA MONTGOMERY COUNTY- NONCD0001081 ADMINISTRATIVE AGREEMENT FOR STATE-DIRECTED REMEDIAL ACTION PURSUANT TO N.C.G.S.130A-310.9(b) DOCKET NUMBER 08-SF- j6y The following constitutes the agreement of the parties hereto. Alcoa Power Generating, Inc. (APGI) concurs with the -conclusions of law contained herein solely for purposes of this Administrative Agreement (Agreement). I. JURISDICTION This Agreement is entered into under. authority vested in the Secretary of the North Carolina .Department of Environment and Natural Resources (Department) by North . Carolina's Inactive. Hazardous Sites Response Act of 1987 (the Act), which donstitutes Part 3, Article 9 of Chapter 130A of the North Carolina General Statutes (N.C.G.S.): N.C.G.S. 130A-310 et seq. This authority has been delegated to the Chief of the Superfund Section of the North Carolina Division of Waste Management (Chief). II. STATEMENT OF PURPOSE This Agreement is entered. into for the purppse of addressing the hazardous substance or waste disposal site (the Site) def ned in Section, TII. A. 'of this Agreement. In entering into this Agreement, the obj ective of the Division of Waste Management (Division) and APGI is for APGI to implement a voluntary. remedial action-program approved by the Division involving: implementation of the approved Remedial Action Plan. III. STIPULATIONS OF FACT A. For purposes of N.C.G.S. 130A-310(3) and this Agreement, the "Site" is defined as the cove area and powerhouse associated with the Narrows dam, which are owned or utilized by APGI; the "Site" is located in Montgomery. County, North Carolina, just off of Pine Street in or near the Town of Badin, North Carolina. alo?ce'?' -* o-, - 6-P - 25.5. B: APGI conducted remedial investigations at the Site from 2001 through 2006. C. Soil.sampling at the Site has revealed the presence of PCBs and lead. IV. CONCLUSIONS OF LAW A. The substances identified in Sections III. C. above are hazardous substances as defined in the Comprehensive. Environmental Response, Compensation- and Liability Act/Superfund - Amendments and Reauthorization Act, 42 U.S.C. Section 9601 et seq., and are thus such substances for purposes of the Act pursuant to N.C.G.S. 130A-310(2). B. The Site is an inactive hazardous substance or waste disposal site for. purposes of the Act pursuant to N.C.G.S. 130A-310(3). C.: APGI is an owner, operator, or other responsible party, in relation to the Site within the meaning of N.C.G.S. 130A-310.9, pursuant to N.C.G.S. 130A-310(4), -310(5), -310(9), and -310.7. D. Under N.C.G.S. 130A-310.9(b), the Secretary, and by delegation, the Chief, is authorized. to enter into agreements with owners, operators, or other responsible parties for implementation of voluntary remedial action programs as to inactive hazardous substance or waste disposal sites in accordance with 'remedial action plans approved by the, Department. V. - WORK TO BE PERFORMED . All work performed pursuant to plans approved under this Agreement, the approved Remedial Action Plan for remediation of contaminated media at the Site, and the provisions of the current Inactive Hazardous Sites 'Program Guidelines for Assessment and Cleanup ("Guidelines") as are explicitly noted to be applicable' by the terms of either the Agreement or the Remedial Action Plan. "k APGI has submitted to the Division a draft Remedial Action Plan for review, a copy of which is attached and incorporated by reference (the "Draft Remedial Action Plan"). B. The Division has tentatively determined that the Draft Remedial Action Plan is suitable for public notice in accordance with G.S. 130A-310.9(b) and G.S 130A-310.4(6)(2). 'C.- APGI shall provide to the Division the number of additional copies of the proposed Remedial Action Plan determined by the Division to be required for distribution to the local health director, register -of deeds, and each public library in the county where the Site is located, if requested by the Docket # 21 -3F_ 255 Division. The Division shall also mail notice of the Remedial Action Plan to those who have requested notice that such plans have been developed, as provided in N.C.G.S. 130A-310.4(c)(2). The Division will receive and consider comments in accordance with the terms of that notice, and will not approve the Remedial Action Plan until at least thirty (30) days after public notice is provided. D. Within thirty (30) days of receiving "notice from the Division of any deficiency in the Remedial Action Plan, APGI shall submit to the Division information or material sufficient to correct such deficiency. E. On the basis of the foregoing and the applicable standards, the Division r will either approve or disapprove the Draft Remedial Action Plan and, if approved, describe in writing any changes required as a condition of approval (the "Approved Remedial Action Plan") and, if disapproved, the reasons for the disapproval and any changes that would be required as a condition of approval. F. If the Approved Remedial Action Plan is acceptable to APGI, it shall provide a signed and notarized certification by an APGI corporate official in charge of a principal business function (the "APGI Corporate Official") accepting the Approved Remedial Action Plan for APGI and including a statement that:. "I certify that, to the best of my knowledge, after thorough investigation, the information contained in or accompanying this cerfification is true, accurate, and complete." G. APGI shall begin implementation of the Remedial Action Plan no sooner than receiving written approval from the Division and the submittal to the " Division of the certification by the APGI Corporate Official noted in the previous paragraph. Subject to conditions beyond its control, as discussed in VII below, APGI would anticipate initiating the Approved Remedial Action Plan within ninety (90) days thereafter. H. This APGI Corporate Official may also provide to the Division a statement delegating to one or more designated employees of APGI the responsibility of investigating and submitting all remaining documents and certifications required of APGI' under the Agreement or the Approved Remedial Action Plan, and the Division will thereafter accept..any such document or certification from the. designated employee(s), so long as the delegation by the APGI Corporate Official remains in effect. I. Fox any documents prepared and/or submitted to the Division on behalf of APGI under this Agreement or the Approved Remedial Action Plan shall comply with the following: 1. They shall' include a signed and notarized certification by the 3 Docket # 1 -SF-._ consultant responsible for the day to day remedial activities stating: "I certify that, to the best of my knowledge, after thorough investigation, the information contained in or accompanying this certification is true, accurate, and complete." 2. If this document includes any work that would constitute the "practice 'of engineering" -as defined by N.C.G.S: 89C,_ the signature and seal of a professional engineer must be included. If this document includes any work that would constitute the "public practice of geology" as defined, by N.C.G.S. 89E, the signature and seal of a licensed geologist is required. J. APGI shall provide to the Division: 1.. `Weekly written or telephone progress reports each Thursday during the soil and waste remedial action under the Approved Remedial Action Plan, if the work is less than one (1) month in total duration; 2: Quarterly reports during: (a) any soil and waste remedial action greater than one (1) month in duration, and (b) any necessary post- remedial maintenance; 3. A final report with data documenting complete implementation of the Approved Remedial Action Plan, upon completion of the work contemplated under that plan. Note 1: The quarter reports or final report (as appropriate) should. include,, without limitation,- completed. drawing. of the cover (if applicable); tabulated laboratory data;. the location and depth of samples collected; a description of all field and.laboratory quality control/quality assurance procedures; and legible and complete copies of all records of periodic system inspections, laboratory reports, waste manifests and chain of custody documentation generated during the reporting period. Quarterly reports shall be provided by the tenth day after each quarter concludes, with the first quarter commencing on the date of written approval. of .the Remedial Action Plan. by the Division. The final report shall be provided within one (1) , month following complete implementation of the- approved Remedial Action Plan. Note 2: Each progress report and the final report shall contain the certifications specified in Sections V.H. and V.I. of this Agreement. K. Within thirty (30) days of receiving written notice from the Division of any deficiency in the reports required by paragraph V.J. or in the implementation of the Approved Remedial Action Plan, APGI shall .4 Docket # _C `b -SF_ 25? submit to the Division information or material sufficient to demonstrate correction of such deficiencies. L. APGI's completion of the work required under the Approved Remedial Action Plan and the submittal of all reports reflecting that work, as outline hereinabove, shall constitute compliance with this Agreement and the Guidelines. M. Any requests for modifications of the approved Remedial Action Plan proposed by APGI or APGI's consultants must be submitted in writing to the Division, and may not be incorporated or implemented unless and until approved in writing by the Division. VI. SAMPLING; ACCESS, AND 'DATA/DOCUMENT AVAILABILITY A'. lhe'Di'vision`or its representatives may take split or duplicate samples of any saihples collected by APGI pursuant to this Agreement. APGI shall notify the' Division not less than ten (10). days in advance of any field activity. This notification may be given verbally in the field by APGI -to the Division. B. The Division or its representatives may conduct any field activity it deems appropriate in relation- to the Site.. APGI may take split or duplicate samples of any samples collected by the Division during such field activity. C.` While -this - Agreement is in effect, Division personnel and their representatives may., in addition to exercising any related legal rights, enter the Site. 'Entry to the Site will lie subject to 411 approved health and safety': requirements, FERC requirements, and Homeland Security requirements. APGI will coordinate all required access. While present o"site , Division personnel' may; review the progress of activities required by this Agreement; conduct"such tests as the Division deems necessary; verify the data submitted to the Division by APGI; inspect and copy any and' all records, files) photographs, operating logs, contracts, sampling and monitoring data, and other documents relating in any way to this Agreement; and otherwise assess APGI's compliance with this Agreement. D. Uriless a confidentiality claim covering- information provided under this Agreement is made pursuant to law and adequately substantiated when the information i"s submitted, such information may be made available to the public by the Division without further notice to APGI. APGI agrees that under no' circumstances shall analytical data generated pursuant to this Agreement be considered confidential. S Docket # 01 -SF- E. APGI waives any objections to the admissibility into evidence (but not objections as to the weight) of the results of any analyses of sampling conducted by or for APGI at the Site or of other data gathered pursuant to this Agreement. F. If APGI is unable by reasonable efforts to gain access to other property as necessary pursuant to this Agreement, the Division shall assist APGI. in obtaining access. VII. DELAY IN PERFORMANCE A. The Division recognizes that the implementation of the Approved Remedial Action Plan is subject to conditions and requirements not within the control of APGI, including some that are not present at the typical remediation site,. especially the ;control exercised by the li.ederal Energy Regulatory Commission ("FERC") over the water levels and flo.ws in the Yadkin River and its reservoirs, including the, area. where much of the work under the Approved Remedial Action, Plan is.to be performed. Any times or schedules under this Agreement or the Approved Remedial Action Plan shall be extended for reasons determined by the Division to constitute good cause. B. Good cause may include, but is not. limited to, regional power generating requirements for; the nearby electric generating, facility (including any orders, requirements, or similar.actions by FERC), maintenance of the electric generating facility or its machinery, extraordinary weather, natural disasters and national emergencies. Provided however, that during removal of contaminated material; under the Approved Remedial Action Plan; 'any precipitation shortly before or during the scheduled times for the work (or actually occurring during or before the work) constitutes good cause for delay. At a minimum, good cause does not include normal inclement weather, not -during times of contaminated material removal, failure by APGI to satisfy, its. obligations under this. Agreement (whether evidenced by a notice of.deficiency or not), acts or omissions of APGI's contractors or representatives not otherwise constituting good cause, and failure by APGI, or its contractors or representatives to make complete and timely application for any required approval or permit. C. As 'sooh as APGI is aware of the potential for delay, it shall submit to the Division written documentation of the reasons for the delay and the efforts made by APGI to avoid the delay, as well as a time by which such work can be completed. D. The Division shall review the documentation and shall promptly approve thelew schedule if good cause is shown. 6 Docket # Q_ -SF-- 2;?' E. The burden of, demonstrating good cause -for delay, and that the delay proposed is warranted, is APGI's. VIII. ADDITIONAL PROVISIONS A. All documents submitted to the Division shall be delivered to: Cheryl Marks Inactive Hazardous Sites Branch North Carolina Superfund Section 401 Oberlin Road - Suite 150 Raleigh, NC 27605-1350 The Division will direct all correspondence related to this Agreement to: Robert Prezbindowski APGI ' 2300 North Wright Road Alcoa; Tennessee 37701-31-41 B. This Agreement shall be binding upon, and inure to the benefit of, APGI, its agents, successors : and assigns. The signatory for APGI to this Agreement certifies that he/she is authorized to.execute and legally bind APGI as to this Agreement. C. APGI shall provide a copy of the Approved Remedial Action Plan to each contractor or other person or 'entity retained. to perform any work under this Agreement, and shall also advise them that the Approved Remedial Action Plan is being implemented pursuant to this' Agreement, within seven (7) days after the effective date of this Agreement or the date of retaining their services; whichever is later. AP GI shall condition'any such contracts upon satisfactory compliance with the Approved Remedial Action.. Plan. Notwithstanding the terms of any contract, .A.PGI is responsible for implementation of the. Approved Remedial Action Plan and ' compliance with this Agreement and for ensuring that such contractors or other persons or entities comply with the Approved Remedial Action Plan and this Agreement. D. This :Agreement notwithstanding, the Division retains all its authority regarding inactive hazardous substance or waste disposal sites in relation to the Site. E. All actions required pursuant to this Agreement shall be in accordance with applicable local, state and federal laws and regulations, unless an exemption regarding particular state or local laws or regulations is 7 Docker # 0'S -SF- 255 specifically provided in this Agreement now or later. F. APGI agrees to indemnify and save and hold harmless the State of North Carolina, and its agencies, departments, officials, agents, employees, contractors and representatives, from any and all claims or causes of action arising. from or on account of acts or omissions of APGI or its officers, employees, receivers, trustees, agents, or assigns in carrying out actions required pursuant to this Agreement. Neither the State of North Carolina nor any agency or. representative thereof shall be held to be a party to any contract involving APGI relating to the Site excluding, however, this Agreement. G.. APGI shall preserve, for at least six (6) years after termination of this Agreement, all records and documents in its possession or in the possession' of its divisions, employees, agents, accountants, contractors or attorneys which relate in any way to this Agreement.. After this six (6)- year period, APGI shall notify the Division at least thirty (30) days prior to the destruction of any such records and documents. APGI shall comply with any written 'request by, the Division, prior to the day set for destruction, to continue to preserve such records and documents or to provide them to the Division. APGI may assert any available right to keep particular records and documents, other than analytical data, confidential. H. This 'Agreement may not be modified without the written consent of the . parties. I. Except for obligations under Section VIII. F. and G. above, this Agreement shall terminate when APGI receives written notice from the Division that all activities required pursuant to this Agreement have been corhpleted to the Division's satisfaction. J. This is a voluntary agreement. If APGI elects to discontinue "implementation of work under this Agreement, APGI shall notify the Division in writing of such intent, and, except for obligations under Section VIII.F. and G. above, this Agreement shall be dissolved upon the Division's receipt of such written notice. If the Division determines that APGI is not complying with the terms of this- Agreement in a timely manner, the Division may, notify APGI -in writing of such determination, and the Agreement, except for obligations under Section VIII.F. and G. above, shall be dissolved upon APGI's receipt of such written notice. In either of these 'events, neither party may seek judicial review of the dissolution of this Agreement or, except for obligations under Section VIII.F. and G. , above, has any right, claim or action for breach of this Agreement.* In either of these events, the Division shall retain all its applicable enforcement rights against APGI, and APGI shall retain all applicable defenses. Docket # _ d -SF-. 2s The effective date of this Agreement shall be the date on which it is executed by the Secretary or his Authorized Agent. Date Executed: CJ2%? 45-1 By: ack- Butler, PE Superfund Section Chief . Division of Waste Management North Carolina Department of Environment and Natural Resources By: William M. Bunker Vice President Alcoa Power Generating Inc. 9 BHE, ENVIRONMENTAL May 26, 2011 BADIN LAKE SEDIMENT SAMPLING WORK PLAN BADIN, NORTH CAROLINA Prepared for: ALCO,i Alcoa, Inc. Prepared by: B I L LT, BHE Environmental, Inc. 11733 Chesterdale Road Cincinnati, OH 45246-3405 Phone: 513.326.1500 www.bheenvironmental.com Notice: This report has been prepared by BHE Environmental, Inc., solely for the benefit of its client in accordance with an approved scope of work. BHE assumes no liability for the unauthorized use of this report or the information contained in it by a third party. Copyright 0 2011 BHE Environmental, Inc. TABLE OF CONTENTS 1.0 INTRODUCTION .................................................................................... 1 1.1 PROJECT OBJECTIVES ......................................................................... 1 2.0 SEDIMENT SAMPLING ............................................................................. 1 2.1 SAMPLING LOCATION SELECTION ............................................................ 1 2.2 FIELD & LABORATORY METHODS ............................................................ 4 2.2.1 Sampling Method .......................................................................... 4 2.2.2 Sample Identification .................................................................... 5 2.2.3 Analytical Methodology .................................................................. 5 2.2.4 Quality Assurance/ Quality Control (QA/QC) .......................................... 6 2.2.5 Derived Waste Management ............................................................. 7 3.0 REPORTING AND SCHEDULE ..................................................................... 8 BHE Environmental, Inc. ii PN: 0990.223 APPENDICES Appendix A. PCB Concentration Isopleths of Impacted Sediments Evaluated During WCC and RETEC Sediment Sampling Events Appendix B. USEPA Standard Operating Procedures (SOP) #2016 - Sediment Sampling BHE Environmental, Inc. iii 1.0 INTRODUCTION Alcoa is currently exploring remedial options for the polychlorinated biphenyl (PCB) impacted sediments located within Badin Lake near the Badin Works Outfalls 11 /12 and 2. Previous PCB sediment sampling investigations have been completed by WCC (1997), and ESI (2008), and ENTRIX (2009). In total, those investigations collected PCB sediment samples in the Outfall 11 /12 and 2 areas (9 samples in the Outfall 11 /12 area and 6 samples in the Boat Landing area). Results from their investigations indicate total PCB impacts to be between 0.04 and 5.40 mg/kg in the Outfall 11/12 area and between 0.11 and 4.32 mg/kg in the Outfall 2 area. The results from the investigations and modeled PCB concentration contours are illustrated on the figure in Appendix A - PCB Concentration Isopleths of Impacted Sediments Evaluated During WCC and RETEC Sediment Sampling Events. 1.1 PROJECT OBJECTIVES Alcoa is addressing PCB-impacted sediments to support a remedial feasibility study. The possible remedial actions may include removal (i.e. dredging) or capping (i.e. AquaBlok, sand/gravel, etc.). Previous sediment sampling investigations conducted by WCC, ESI and ENTRIX in the Outfall 11/12 and 2 areas do not adequately delineate the extents of PCB impacts. This investigation and the selection of the sediment sampling locations are designed to supplement the previous investigations and more accurately delineate the targeted areas. Additionally, sediment samples will be analyzed for geotechnical properties (i.e. bearing capacity, consolidation, soft sediment thickness, etc.). The geotechnical data will be used to further evaluate the feasibility of the remedial options currently under consideration. 2.0 SEDIMENT SAMPLING As indicated above, the goal of the proposed sediment sampling event is twofold. Firstly, it is to supplement previous Badin Lake sediment sampling efforts. Secondly, it is to evaluate the geotechnical properties of the sediments to support engineering of remedial measures. PCB analysis will be conducted by a North Carolina certified laboratory. Sampling locations and procedures are outlined in the following sections. 2.1 SAMPLING LOCATION SELECTION Composite sediment samples will be collected from six locations within and around the northerly targeted area and from five locations within and around the southerly targeted area (a total of eleven sample locations). Please refer to Figure 1 for the proposed sampling locations. Included in the figure are the PCB sediment samples collected by WCC, ESI and ENTRIX. As discussed previously, the proposed sampling locations have been selected to fill in data gaps in previous sediment sampling work. BHE Environmental, Inc. BHE Environmental, Inc. BHE Environmental, Inc. 2.2 FIELD £t LABORATORY METHODS 2.2.1 Sampling Method Samples will be collected from an anchored boat. The primary sediment sample collection device for both chemical and geotechnical sample collection will be a Wildco core-sampler. The samples will be collected following procedures outlined in USEPA Standard Operating Procedures (SOP) #2016, provided in Appendix B. The core sampler consists of a two-foot stainless steel barrel with a stainless steel cutting shoe equipped with an eggshell sample retention device (the retention device will allow the sediment to enter through the cutting shoe, but will prevent the sample from falling out during sampler retrieval). An acetate liner will be used inside the core sampler barrel and a new liner will be used at each sample location. A flap check valve is located at the top of the core barrel. The valve opens as the core barrel is advanced into the sediment column and closes as the barrel is removed, which forms a vacuum within the core barrel that helps to retain the sample. The core sampler will be advanced into the sediment while the boat is anchored over the sample location. The core sampler will be fitted with extensions, as needed, in order to reach the necessary depth over deeper sediments. The corer is then tamped with a messenger (larger diameter pipe) or a slide hammer to advance the sampler further into the sediment, if needed. Alternatively, a Wildco Ponar "clamshell" sampler may also be used to collect "disturbed" samples for geotechnical consolidation and permeability testing. After the core sampler is retrieved to the surface, the water above the sediment will be decanted and the cutting shoe (nosecone) and eggshell retainer will be removed. The acetate liner will be extracted from the barrel and any water remaining water will be decanted while taking care not to lose the fine surface sediment layer. Multiple cores may be collected at each location to ensure sufficient sample volume. The sediment will be extracted by gravity onto a horizontal collection tray covered by aluminum foil. The top five centimeters of each core from the sample location will be collected into a stainless steel pan with a stainless steel spoon and homogenized. The homogenized sample will then be placed into an eight-ounce sample jar, labeled and preserved on ice. Any geotechnical samples collected in acetate liners will not be removed from the liners in the field, but will be capped, labeled and shipped to the geotechnical laboratory for analyses. Each sediment sampling location will be documented and recorded using a global positioning system (GPS) device capable of sub-meter accuracy. All equipment used to collect and prepare samples for analysis will be decontaminated in accordance with QA/QC procedures as detailed in Section 3.3.4. The lake bed will be probed to attempt to determine the thickness and distribution of very soft sediments. A narrow probe will be extended from the boat to the top of the soft sediment layer and a depth indicating marker will be placed on the probe to indicate the depth at which the top of the soft sediment was encountered. The probe will then be driven through the soft sediment by hand until reaching the interface between the soft sediment and hard sediment. A second depth indicating marker will then be placed on the probe. The probe will then be retrieved and the distance between the two indicating markers will be measured and recorded as the thickness of the soft sediment. Approximately 31 locations will be probed in this manner along multiple transects in the target investigation areas. The thickness measurement transects are presented on Figure 2. Among these locations, a minimum of six sediment samples will be collected for geotechnical testing for consolidation BHE Environmental, Inc. 4 and permeability and to attempt shear strength testing, as well as for Atterberg Limits, sieve and hydrometer analyses for particle size distribution. 2.2.2 Sample Identification The following sample identification system will be used for sediment samples collected during the sediment sampling program: ABK-SL-M-QCO Where : SL = Sample Location M = Matrix (SED) 0 = Field Sample Number QC = QC Designation : F (Field Sample) D (Field Duplicate) MS/MSD = Matrix Spike/Matrix Spike B = Equipment Blank Sediment samples will be shipped on wet ice under chain of custody via overnight carrier to TestAmerica in Savannah, Georgia. 2.2.3 Analytical Methodology Sediment samples collected during field activities will be analyzed for the constituents of interest listed in Table 2-1. All chemical analyses will be performed by TestAmerica in Savannah, Georgia. A summary of analytes and methods is presented in Table 2-1. Table 2-1. Summary of Analytes and Methods Constituent Analyte Analytical Group Method Aroclor 1242 Aroclor 1248 PCBs Aroclor 1254 Aroclor 1260 8082 Moisture Content Total Organic Total Organic Carbon Lloyd Kahn Carbon Geotechnical samples collected during field activities will be tested by Terracon in Cincinnati, Ohio per the parameters listed in Table 2-2. BHE Environmental, Inc. Table 2-2. Summary of Geotec hnical Tests Sample Type Tests Test Method Undisturbed Core Samples UU Triaxial Compression ASTM D3080-04 Consolidation testing and Disturbed Consolidation and Permeability permeability calculation per Grab Samples specifications in USACE document EM-111-2-5027 Moisture content and Atterberg ASTM D4318-10 Limits 2.2.4 Quality Assurance/Quality Control (QA/QC) Three types of QA/QC samples will be collected. QA/QC samples will be collected only for samples undergoing chemical analysis. • Field/Equipment Blanks A blank prepared in the field using water provided by TestAmerica in Savannah, Georgia. The water is poured over/through sampling equipment which has been previously decontaminated. The blank water is then collected into sample bottles and analyzed for the chemicals of interest. The purpose of this blank is to ensure that field conditions and/or equipment are not introducing chemicals to the samples. • Field Duplicates A duplicate sample prepared in the field and sent to the laboratory for analysis. The results will provide some indication of the homogeneity of the sample medium and the precision of the field sampling and laboratory sample analysis. Accurate field notes will ensure that each duplicate can be matched to its corresponding investigatory sample. Matrix Spike/Matrix Spike Duplicates (MS/MSDs) A `MS' is a subsample of an investigatory sample to which the laboratory adds a spike containing analytes at known concentrations prior to extraction /analysis of the sample to assess the effect of sample matrix on the extraction and analysis methodology. The MSD is another subsample from the original investigatory sample (subsampling performed at the laboratory) which is similarly spiked. Typically one QA/QC sample is collected per 20 field samples. For this survey one of each QA/QC sample will be collected: one field duplicate, one MS/MSD pair, and one equipment blank. 2.2.4.1 Decontamination Procedure Field QA/QC procedures include decontamination of process equipment and materials. Sampling equipment will be cleaned on-site prior to use for collecting samples for chemical analysis. The decontamination process includes the following: • Wash and scrub with low phosphate detergent; BHE Environmental, Inc. • Tap water rinse; • Deionized water rinse; • An isopropanol rinse; • Deionized water rinse; • Air dry; and • Wrap in aluminum foil. 2.2.4.2 Sample Chains of Custody Procedures to ensure the custody and integrity of the samples begin at the time of sampling and continue through transport, sample receipt, preparation, analysis and storage, data generation and reporting and sample disposal. Field personnel shall maintain Chain of Custody records for all field and field QC samples. All sample containers will be sealed in a manner that will prevent or detect tampering if it occurs. The Chain of Custody for each sample cooler will be placed in a sealable plastic bag and taped to the inside of the sample cooler lid prior to transporting the samples to the laboratory. The following minimum information concerning the sample shall be documented on the laboratory Chain of Custody form: • Unique sample identification; • Sample type; • Place, date, and time of sample collection; • Number of containers/ analytical fractions per sample; • Designation of MS/MSD; • Analyses required; • PCB sample preparation method desired; • Custody transfer signatures and dates and times of sample transfer from the field to transporters and to the laboratory or laboratories; and • Tracking number. 2.2.4.3 Sample Shipping All sample coolers will be sealed in a way that will prevent tampering or provide direct evidence in the event of tampering. A signed and dated custody seal will be placed on each cooler and will then be sealed with packing tape. Address labels and shipping documentation wilt be affixed to all coolers prior to shipment. Samples for the sampling event are not expected to be classified as hazardous. Samples will be shipped on wet ice. All ice will be double bagged and also enclosed in the cooler liner to provide three layers of safety against leakage. 2.2.5 Derived Waste Management Decontamination water and all solid waste (i.e., nitrite gloves, aluminum foil, plastic sheeting.) will be handled and disposed in accordance with the Alcoa Badin Works procedures. BHE Environmental, Inc. Excess sediment at each of the respective sampling locations will be returned to the lake in the vicinity in which it was collected. 3.0 REPORTING AND SCHEDULE The sediment sampling event will be initiated within 14 days of receiving approval of the Work Plan. The analytical data will be available within 15 days following the completion of the field activities and receiving validated data packages from both TestAmerica and Terracon. BHE Environmental, Inc. APPENDIX A PCB Concentration Isopleths of Impacted Sediments Evaluated During WCC and RETEC Sediment Sampling Events APPENDIX B USEPA Standard Operating Procedures (SOP) #2016 - Sediment Sampling SOP#: 2016 SEDIMENT SAMPLING DATE: 11/17/94 REV. #: 0.0 1.0 SCOPE AND APPLICATION This standard operating procedure (SOP) is applicable to the collection of representative sediment samples. Analysis of sediment may be biological, chemical, or physical in nature and may be used to determine the following: toxicity; biological availability and effects of contaminants; benthic biota; extent and magnitude of contamination; contaminant migration pathways and source; fate of contaminants; grain size distribution. The methodologies discussed in this SOP are applicable to the sampling of sediment in both flowing and standing water. They are generic in nature and may be modified in whole or part to meet the handling and analytical requirements of the contaminants of concern, as well as the constraints presented by site conditions and equipment limitations. However, if modifications occur, they should be documented in a site or personal logbook and discussed in reports summarizing field activities and analytical results. For the purposes of this procedure, sediments are those mineral and organic materials situated beneath an aqueous layer. The aqueous layer may be either static, as in lakes, ponds, and impoundments; or flowing, as in rivers and streams. Mention of trade names or commercial products does not constitute U. S. EPA endorsement or recommendation for use. 2.0 METHOD SUMMARY Sediment samples may be collected using a variety of methods and equipment, depending on the depth of the aqueous layer, the portion of the sediment profile required (surface vs. subsurface), the type of sample required (disturbed vs. undisturbed), contaminants present, and sediment type. Sediment is collected from beneath an aqueous layer either directly, using a hand held device such as a shovel, trowel, or auger; or indirectly, using a remotely activated device such as an Ekman or Ponar dredge. Following collection, sediment is transferred from the sampling device to a sample container of appropriate size and construction for the analyses requested. If composite sampling techniques are employed, multiple grabs are placed into a container constructed of inert material, homogenized, and transferred to sample containers appropriate for the analyses requested. The homogenization procedure should not be used if sample analysis includes volatile organics; in this case, sediment, or multiple grabs of sediment, should be transferred directly from the sample collection device or homogenization container to the sample container. 3.0 SAMPLE PRESERVATION, CONTAINERS, HANDLING AND STORAGE Chemical preservation of solids is generally not recommended. Cooling to 4°C is usually the best approach, supplemented by the appropriate holding time for the analyses requested. Wide mouth glass containers with Teflon lined caps are utilized for sediment samples. The sample volume is a function of the analytical requirements and will be specified in the Work Plan. If analysis of sediment from a discrete depth or location is desired, sediment is transferred directly from the sampling device to a labeled sample container(s) of appropriate size and construction for the analyses requested. Transfer is accomplished with a stainless steel or plastic lab spoon or equivalent. 4. If composite sampling techniques or multiple grabs are employed, equal portions of sediment from each location are deposited into a stainless steel, plastic, or other appropriate composition (e.g., Teflon) containers. The sediment is homogenized thoroughly to obtain a composite representative of the area sampled. The composite sediment sample is transferred to a labeled container(s) of appropriate size and construction for the analyses requested. Transfer of sediment is accomplished with a stainless steel or plastic lab spoon or equivalent. Samples for volatile organic analysis must be transferred directly from the sample collection device or pooled from multiple areas in the homogenization container prior to mixing. This is done to minimize loss of contaminant due to volatilization during homogenization. All sampling devices should be decontaminated, then wrapped in aluminum foil. The sampling device should remain in this wrapping until it is needed. Each sampling device should be used for only one sample. Disposable sampling devices for sediment are generally impractical due to cost and the large number of sediment samples which may be required. Sampling devices should be cleaned in the field using the decontamination procedure described in the Sampling Equipment Decontamination SOP. 4.0 INTERFERENCES AND POTENTIAL PROBLEMS Substrate particle size and organic matter content are a direct consequence of the flow characteristics of a waterbody. Contaminants are more likely to be concentrated in sediments typified by fine particle size and a high organic matter content. This type of sediment is most likely to be collected from depositional zones. In contrast, coarse sediments with low organic matter content do not typically concentrate pollutants and are generally found in erosional zones. The selection of a sampling location can, therefore, greatly influence the analytical results and should be justified and specified in the Work Plan. 5.0 EQUIPMENT/APPARATUS Equipment needed for collection of sediment samples may include: C Maps/plot plan C Safety equipment C Compass C Tape measure C Survey stakes, flags, or buoys and anchors C Camera and film C Stainless steel, plastic, or other appropriate composition bucket C 4-oz., 8-oz., and one-quart wide mouth jars w/Teflon lined lids C Ziploc plastic bags C Logbook C Sample jar labels C Chain of Custody records, field data sheets C Cooler(s) C Ice C Decontamination supplies/equipment C Spade or shovel C Spatula C Scoop C Trowel C Bucket auger C Tube auger C Extension rods C "T" handle C Sediment coring device (tube, drive head, eggshell check value, nosecone, acetate tube, extension rods, "T" handle) C Ponar dredge C Ekman dredge C Nylon rope or steel cable C Messenger device 6.0 REAGENTS Reagents are not used for preservation of sediment samples. Decontamination solutions are specified in the Sampling Equipment Decontamination SOP. 2 7.0 PROCEDURES 7.1 Preparation 1. Determine the objective(s) and extent of the sampling effort. The sampling methods to be employed, and the types and amounts of equipment and supplies required will be a function of site characteristics and objectives of the study. 2. Obtain the necessary sampling and monitoring equipment. 3. Prepare schedules, and coordinate with staff, client, and regulatory agencies, if appropriate. 4. Decontaminate or preclean equipment, and ensure that it is in working order. 5. Perform a general site survey prior to site entry in accordance with the site specific Health and Safety Plan. 6. Use stakes, flagging, or buoys to identify and mark all sampling locations. Specific site factors including flow regime, basin morphometry, sediment characteristics, depth of overlying aqueous layer, contaminant source, and extent and nature of contamination should be considered when selecting sample locations. If required, the proposed locations may be adjusted based on site access, property boundaries, and surface obstructions. 7.2 Sample Collection Selection of a sampling device is most often contingent upon: (1) the depth of water at the sampling location, and (2) the physical characteristics of the sediment to be sampled. The following procedures may be utilized: 7.2.1 Sampling Surface Sediment with a Trowel or Scoop from Beneath a Shallow Aqueous Layer For the purpose of this method, surface sediment is considered to range from 0 to six inches in depth and a shallow aqueous layer is considered to range from 0 to 12 inches in depth. Collection of surface sediment from beneath a shallow aqueous layer can be accomplished with tools such as spades, shovels, trowels, and scoops. Although this method can be used to collect both unconsolidated/consolidate d sediment, it is limited somewhat by the depth and movement of the aqueous layer. Deep and rapidly flowing water render this method less accurate than others discussed below. However, representative samples can be collected with this procedure in shallow sluggish water provided care is demonstrated by the sample team member. A stainless steel or plastic sampling implement will suffice in most applications. Care should be exercised to avoid the use of devices plated with chrome or other materials; plating is particularly common with garden trowels. The following procedure will be used to collect sediment with a scoop, shovel, or trowel: Using a decontaminated sampling implement, remove the desired thickness and volume of sediment from the sampling area. Transfer the sample into an appropriate sample or homogenization container. Ensure that non-dedicated containers have been adequately decontaminated. Surface water should be decanted from the sample or homogenization container prior to sealing or transfer; care should be taken to retain the fine sediment fraction during this procedure. 7.2.2 Sampling Surface Sediment with a Bucket Auger or Tube Auger from Beneath a Shallow Aqueous Layer For the purpose of this method, surface sediment is considered to range from 0 to six inches in depth and a shallow aqueous layer is considered to range from 0 to 24 inches in depth. Collection of surface sediment from beneath a shallow aqueous layer can be accomplished with a system consisting of bucket auger or tube auger, a series of extensions, and a "T" handle (Figure 1, Appendix A). The use of additional extensions in conjunction with a bucket auger can increase the depth of water from which sediment can be collected from 24 inches to 10 feet or more. However, sample handling and manipulation increases in difficulty with increasing depth of water. The bucket auger or tube auger is driven into the sediment and used to extract a core. The various depths represented by the core are homogenized or a subsample of the core is taken from the appropriate depth. The following procedure will be used to collect sediment samples with a bucket auger or tube auger: 1. An acetate core may be inserted into the bucket auger or tube auger prior to sampling if characteristics of the sediments or waterbody warrant. By using this technique, an intact core can be extracted. 2. Attach the auger head to the required length of extensions, then attach the "T" handle to the upper extension. 3. Clear the area to be sampled of any surface debris. 4. Insert the bucket auger or tube auger into the sediment at a 0° to 2(P angle from vertical. This orientation minimizes spillage of the sample from the sampler upon extraction from the sediment and water. 5. Rotate the auger to cut a core of sediment. 6. Slowly withdraw the auger; if using a tube auger, make sure that the slot is facing upward. 7. Transfer the sample or a specified aliquot of sample into an appropriate sample or homogenization container. Ensure that non- dedicated containers have been adequately decontaminated. 7.2.3 Sampling Deep Sediment with a Bucket Auger or Tube Auger from Beneath a Shallow Aqueous Layer For the purpose of this method, deep sediment is considered to range from six to greater than 18 inches in depth and a shallow aqueous layer is considered to range from 0 to 24 inches. Collection of deep sediment from beneath a shallow aqueous layer can be accomplished with a system consisting of a bucket auger, a tube auger, a series of extensions and a "T" handle. The use of additional extensions can increase the depth of water from which sediment can be collected from 24 inches to five feet or more. However, water clarity must be high enough to permit the sampler to directly observe the sampling operation. In addition, sample handling and manipulation increases in difficulty with increasing depth of water. The bucket auger is used to bore a hole to the upper range of the desired sampling depth and then withdrawn. The tube auger is then lowered down the borehole, and driven into the sediment to the lower range of the desired sampling depth. The tube is then withdrawn and the sample recovered from the tube. This method can be used to collect firmly consolidated sediments, but is somewhat limited by the depth of the aqueous layer, and the integrity of the initial borehole. The following procedure will be used to collect deep sediment samples with a bucket auger and a tube auger: 1. Attach the bucket auger bit to the required lengths of extensions, then attach the "T" handle to the upper extension. 2. Clear the area to be sampled of any surface debris. 3. Begin angering, periodically removing any accumulated sediment (i.e., cuttings) from the auger bucket. Cuttings should be disposed of far enough from the sampling area to minimize cross contamination of various depths. 4. After reaching the upper range of the desired depth, slowly and carefully remove bucket auger from the boring. 5. Attach the tube auger bit to the required lengths of extensions, then attach the "T" handle to the upper extension. 6. Carefully lower tube auger down borehole using care to avoid making contact with the borehole sides and, thus, cross contaminating the sample. Gradually force tube auger into sediment to the lower range of the desired sampling depth. Hammering of the tube auger to facilitate coring should be avoided as the vibrations may cause the boring walls 4 to collapse. 7. Remove tube auger from the borehole, again taking care to avoid making contact with the borehole sides and, thus, cross contaminating the sample. 8. Discard the top of core (approximately 1 inch); as this represents material collected by the tube auger before penetration to the layer of concern. Transfer sample into an appropriate sample or homogenization container. Ensure that non-dedicated containers have been adequately decontaminated. 7.2.4 Sampling Surface Sediment with an Ekman or Ponar Dredge from Beneath a Shallow or Deep Aqueous Layer For the purpose of this method, surface sediment is considered to range from 0 to six inches in depth. Collection of surface sediment can be accomplished with a system consisting of a remotely activated device (dredge) and a deployment system. This technique consists of lowering a sampling device (dredge) to the surface of the sediment by use of a rope, cable, or extended handle. The mechanism is activated, and the device entraps sediment in spring loaded or lever operated jaws. An Ekman dredge is a lightweight sediment sampling device with spring activated jaws. It is used to collect moderately consolidated, fine textured sediment. The following procedure will be used for collecting sediment with an Ekman dredge (Figure 2, Appendix A): Attach a sturdy nylon rope or stainless steel cable through the hole on the top of the bracket, or secure the extension handle to the bracket with machine bolts. 2. Attach springs to both sides of the jaws. Fix the jaws so that they are in open position by placing trip cables over the release studs. Ensure that the hinged doors on the dredge top are free to open. Lower the sampler to a point 4 to 6 inches above the sediment surface. 4. Drop the sampler to the sediment. 5. Trigger the jaw release mechanism by lowering a messenger down the line, or by depressing the button on the upper end of the extension handle. 6. Raise the sampler and slowly decant any free liquid through the top of the sampler. Care should be taken to retain the fine sediment fraction during this procedure. 7. Open the dredge jaws and transfer the sample into a stainless steel, plastic or other appropriate composition (e.g., Teflon) container. Ensure that non-dedicated containers have been adequately decontaminated. If necessary, continue to collect additional sediment grabs until sufficient material has been secured to fulfill analytical requirements. Thoroughly homogenize and then transfer sediment to sample containers appropriate for the analyses requested. Samples for volatile organic analysis must be collected directly from the bucket before homogenization to minimize volatilization of contaminants. A Ponar dredge is a heavyweight sediment sampling device with weighted jaws that are lever or spring activated. It is used to collect consolidated fine to coarse textured sediment. The following procedure will be used for collecting sediment with a Ponar dredge (Figure 3, Appendix A): 1. Attach a sturdy nylon rope or steel cable to the ring provided on top of the dredge. 2. Arrange the Ponar dredge with the jaws in the open position, setting the trip bar so the sampler remains open when lifted from the top. If the dredge is so equipped, place the spring loaded pin into the aligned holes in the trip bar. 3. Slowly lower the sampler to a point approximately two inches above the sediment. 4. Drop the sampler to the sediment. Slack on the line will release the trip bar or spring loaded pin; pull up sharply on the line closing the dredge. Raise the dredge to the surface and slowly decant any free liquid through the screens on top of the dredge. Care should be taken to retain the fine sediment fraction during this operation. Open the dredge and transfer the sediment to a stainless steel, plastic or other appropriate composition (e.g., Teflon) container. Ensure that non-dedicated containers have been adequately decontaminated. If necessary, continue to collect additional sediment until sufficient material has been secured to fulfill analytical requirements. Thoroughly homogenized and then transfer sediment to sample containers appropriate for the analyses requested. Samples for volatile organic analysis must be collected directly from the bucket before homogenization to minimize volatilization of contaminants. 7.2.5 Sampling Subsurface Sediment with a Coring Device from Beneath a Shallow Aqueous Layer For purposes of this method, subsurface sediment is considered to range from 6 to 24 inches in depth and a shallow aqueous layer is considered to range from 0 to 24 inches in depth. Collection of subsurface sediment from beneath a shallow aqueous layer can be accomplished with a system consisting of a tube sampler, acetate tube, eggshell check valve, nosecone, extensions, and "T" handle, or drivehead. The use of additional extensions can increase the depth of water from which sediment can be collected from 24 inches to 10 feet or more. This sampler may be used with either a drive hammer for firm sediment, or a "T" handle for soft sediment. However, sample handling and manipulation increases in difficulty with increasing depth of water. The following procedure describes the use of a sample coring device (Figure 4, Appendix A) used to collect subsurface sediments. Assemble the coring device by inserting the acetate core into the sampling tube. 2. Insert the "egg shell" check valve into the lower end of the sampling tube with the convex surface positioned inside the acetate core. 3. Screw the nosecone onto the lower end of the sampling tube, securing the acetate tube and eggshell check valve. 4. Screw the handle onto the upper end of the sampling tube and add extension rods as needed. 5. Place the sampler in a perpendicular position on the sediment to be sampled. 6. If the "T" handle is used, place downward pressure on the device until the desired depth is reached. After the desired depth is reached, rotate the sampler to shear off the core at the bottom. Slowly withdraw the sampler from the sediment and proceed to Step 15. 7. If the drive hammer is selected, insert the tapered handle (drive head) of the drive hammer through the drive head. 8. Drive the sampler into the sediment to the desired depth. 9. Record the length of the tube that penetrated the sample material, and the number of blows required to obtain this depth. 10. Remove the drive hammer and fit the keyhole-like opening on the flat side of the hammer onto the drive head. In this position, the hammer serves as a handle for the sampler. 11. Rotate the sampler to shear off the core at the bottom. 12. Lower the sampler handle (hammer) until it just clears the two ear-like protrusions on the drive head, and rotate about 90°. 13. Slowly withdraw the sampler from the sediment. If the drivehead was used, pull the hammer upwards and dislodge the sampler from the sediment. 6 14. Carefully remove the coring device from the water. 15. Unscrew the nosecone and remove the eggshell check valve. 16. Slide the acetate core out of the sampler tube. Decant surface water, using care to retain the fine sediment fraction. If head space is present in the upper end, a hacksaw may be used to shear the acetate tube off at the sediment surface. The acetate core may then be capped at both ends. Indicate on the acetate tube the appropriate orientation of the sediment core using a waterproof marker. The sample may be used in this fashion, or the contents transferred to a sample or homogenization container. 17. Open the acetate tube and transfer the sediment to a stainless steel, plastic or other appropriate composition (e.g., Teflon) container. Ensure that non-dedicated containers have been adequately decontaminated. If necessary, continue to collect additional sediment until sufficient material has been secured to fulfill analytical requirements. Thoroughly homogenize and then transfer sediment to sample containers appropriate for the analyses requested. Samples for volatile organic analysis must be collected directly from the bucket before homogenization to minimize volatilization of contaminants. 8.0 CALCULATIONS This section is not applicable to this SOP. 9.0 QUALITY ASSURANCE/ QUALITY CONTROL There are no specific quality assurance (QA) activities which apply to the implementation of these procedures. However, the following QA procedures apply: All data must be documented on field data sheets or within site logbooks. 2. All instrumentation must be operated in accordance with operating instructions as supplied by the manufacturer, unless otherwise specified in the work plan. Equipment checkout and calibration activities must occur prior to sampling/operation, and they must be documented. 10.0 DATA VALIDATION This section is not applicable to this SOP. 11.0 HEALTH AND SAFETY When working with potentially hazardous materials, follow U.S. EPA/OSHA and Corporate health and safety procedures. More specifically, when sampling sediment from waterbodies, physical hazards must be identified and adequate precautions must be taken to ensure the safety of the sampling team. The team member collecting the sample should not get too close to the edge of the waterbody, where bank failure may cause loss of balance. To prevent this, the person performing the sampling should be on a lifeline, and be wearing adequate protective equipment. If sampling from a vessel is determined to be necessary, appropriate protective measures must be implemented. 12.0 REFERENCES Mason, B.J., Preparation of Soil Sampling Protocol: Technique and Strategies. 1983 EPA-600/4-83-020. Barth, D.S. and B.J. Mason, Soil Sampling Quality Assurance User's Guide. 1984 EPA-600/4-84-043. U.S. EPA. Characterization of Hazardous Waste Sites - A Methods Manual: Volume II. Available Sampling Methods, Second Edition. 1984 EPA- 600/4-84-076. de Vera, E.R., B.P. Simmons, R.D. Stephen, and D.L. Storm. Samplers and Sampling Procedures for Hazardous Waste Streams. 1980 EPA-600/2-80-018. 7 APPENDIX A Figures FIGURE 1. Sampling Auger TUBE BUCKET AUGER AUGER APPENDIX A (Cont'd) Figures FIGURE 2. Ekman Dredge APPENDIX A (Cont'd) Figures FIGURE 3. Ponar Dredge 10 APPENDIX A (Cont'd) Figures FIGURE 4. Sample Coring Device 0 BRASS PLASTIC TUBE PLASTIC 9 11