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Home My WebLink About20140957 Ver 2_Resource Report 2_201509010 Mandc ATLANTIC COAST PIPELINE, LLC Coast ATLANTIC COAST PIPELINE Pipdne Docket Nos. CP15- -000 CP15- -000 CP15- -000 and DOMINION TRANSMISSION, INC. SUPPLY HEADER PROJECT ;W"Dominiow Docket No. CP15- -000 Resource Report 2 Water Use and Quality Final Prepared by Amk �W'j an ERM Group company September 2015 Resource Report 2 Water Use and Quality Summary of Required Federal Energy Regulatory Commission Report Information Minimum Filing Requirements: Report Section Reference I . Identify all perennial surface waterbodies crossed by the proposed project and their water quality Sections 2.2.2 and 2.2 5, classification. (§ 380.12(d)(1)) Appendix 2A • Identify by milepost Section 2.2.6, Table 2.2 6-1 • Indicate if potable water intakes are within 3 miles downstream of the crossing 2. Identify all waterbody crossings that may have contaminated waters or sediments. (§ 380.12(d)(1)) Section 2.2 4; Appendix 213 • Identify by milepost. • Include offshore sediments. Not applicable 3 Identify watershed areas, designated surface water protection areas, and sensitive waterbodies crossed Sections 2 2.1, 2.2.5, and 2.2.8; by the proposed project. (§ 380.12(d)(1)) Tables 2.2. 1 - 1, Appendix 2C 0 Identify by milepost. Appendix 2F 4. Provide a table (based on NWI maps if delineations have not been done) identifying all wetlands, by Tables 2 3.4-1, 2 3 4-2 and 2.3 4 - milepost and length, crossed by the proposed project (including abandoned pipeline), and the total 3; Appendix 2H acreage and acreage of each wetland type that would be affected by construction. (§ 380.12(d)(1&4)) Sections 2.2. 10 and 2.3.5 5. Discuss construction and restoration methods proposed for crossing wetlands, and compare them to Sections 1.5.2.2, 2.3 5, and 2.3.6 staff s Wetland and Waterbody Construction and Mitigation Procedures. (§ 3 80.12(d)(2)) 6. Describe the proposed waterbody construction, impact mitigation, and restoration methods to be used to Sections 1 5 2.1, 2 2.9, and 2.2. 10 cross surface waters and compare to the staff s WetIand and Waterbody Construction and Mitigation Procedures (§ 380.12(d)(2)) Not applicable Although the Procedures do not apply offshore, the first part of this requirement does apply. Be sure to include effects of sedimentation, etc. This information is needed on a mile -by -mile basis and will require completion of geophysical and other surveys before filing. (See also Resource Report 3.) 7. Provide original National Wetlands Inventory (NWI) maps or the appropriate state wetland maps, if Appendix 2G NWI maps are not available, that show all proposed facilities and include nulepost locations for proposed pipeline routes. (§ 380.12(d)(4)) 8. Identify all U.S. Environmental Protection Agency (EPA) — or state -designated aquifers crossed. (§ Sections 2 12, 2.1.2, 2.1.4 and 380.12(d)(9)) 2.1.4; Tables 2.1.1-1, 2 1.3-1, Identify the location of known public and private groundwater supply wells or springs within 150 2.1.3-2, 2.1.3-3, and 2 14-1; feet of construction. Figure 2.1 Additional Information: Report Section Reference Identify proposed mitigation for impacts on groundwater resources Section 2.1.6 Discuss the potential for blasting to affect water wells, springs, and wetlands, and associated initigation. Sections 2.16, 2.2.10, and 2 3 5 Identify all sources of hydrostatic test water, the quantity of water required, methods for withdrawal, and Section 2.2.6, Table 2.2 6-1 treatment of discharge, and any waste products generated If underground storage of natural gas is proposed, identify how water produced from the storage field will be Not applicable disposed. If salt caverns are proposed for storage of natunrI gas, identify the source locations, the quantity required, the Not applicable method and rate of water withdrawal, and disposal methods. For each waterbody greater than 100 feet wide, provide site-specific construction, mitigation, and restoration Section 2.2.2, Table 2.2 2-2; plans. Appendix 2F Indicate mitigation measures to be undertaken to ensure that public or private water supplies are returned to Section 2.1.6 their former capacity in the event of damage resulting from construction. Describe typical staging area requirements at waterbody and wetland crossings. Sections 2.2. 10 and 2.3.5 If wetlands would be filled or permanently lost, describe proposed measures to compensate for permanent Section 2.3.6 wetland losses If forested wetlands would be affected, describe proposed measures to restore forested wetlands following Section 2.3.6 construction Describe techniques to be used to mmunize turbidity and sedimentation impacts associated with offshore Not applicable trenching, if any. 2-i Resource Report 2 Water Use and Quality TABLE OF CONTENTS 2.0 RESOURCE REPORT 2 — WATER USE AND QUALITY ..................................... 2-1 2.1 GROUNDWATER RESOURCES ...................................................................... 2-4 2.1.1 Principal Aquifers .................................................................................... 2-4 2.1.2 Designated Sole or Principal Source Aquifers ......................................... 2-9 2.1.3 Water Supply Wells ................................................................................. 2-9 2.1.4 Springs ................................................................................................... 2-14 2.1.5 Contaminated Groundwater ................................................................... 2-14 2.1.6 Groundwater Construction Related Impacts and Mitigation ................. 2-17 2.1.7 Facility Operations ................................................................................. 2-21 2.2 SURFACE WATER RESOURCES .................................................................. 2-22 2.2.1 Existing Watersheds ............................................................................... 2-22 2.2.2 Waterbodies Crossed ............................................................................. 2-22 2.2.3 Surface Water Standards and Classifications ........................................ 2-25 2.2.4 Contaminated Waters or Sediments ....................................................... 2-29 2.2.5 Public Surface Water Intakes and Surface Water Protection Areas ...... 2-29 2.2.6 Horizontal Directional Drill Mud Water Use ........................................ 2-32 2.2.7 Hydrostatic Test Water and Fugitive Dust Control Water ..................... 2-32 2.2.8 Sensitive Surface Waters ....................................................................... 2-34 2.2.9 Waterbody Construction Procedures ..................................................... 2-36 2.2.10 Waterbody Construction -Related Impacts and Mitigation .................... 2-36 2.2.11 Facility Operations ................................................................................. 2-41 2.3 WETLANDS ...................................................................................................... 2-42 2.3.1 Wetland Types ....................................................................................... 2-43 2.3.2 Existing Wetland Resources .................................................................. 2-43 2.3.3 Wetland Reserve Program ..................................................................... 2-44 2.3.4 Wetland Crossings ................................................................................. 2-45 2.3.5 Wetland Crossing Methods .................................................................... 2-49 2.3.6 Wetland Impacts and Mitigation ............................................................ 2-51 2.3.7 Compensatory Mitigation ...................................................................... 2-56 2.4 REFERENCES .................................................................................................. 2-57 2 -ii Resource Report 2 Water Use and Quality LIST OF TABLES Table 2. 1. 1 -1 Aquifers Crossed by the Atlantic Coast Pipeline and Supply Header Project ..... 2-6 Table 2.1.3 -1 Public Water Supply Wells Within 150 Feet of the Atlantic Coast Pipeline and SupplyHeader Project ....................................................................................... 2-10 Table 2.1.3-2 Private Water Wells Within 150 Feet of the Atlantic Coast Pipeline and Supply HeaderProject .................................................................................................... 2-12 Table 2.1.3-3 Wellhead Protection Areas Crossed by the Atlantic Coast Pipeline and Supply HeaderProject .................................................................................................... 2-13 Table 2.1.4-1 Springs Located Within 150 Feet of the Atlantic Coast Pipeline and Supply HeaderProject .................................................................................................... 2-14 Table 2.1.5-1 Contaminated Sites, Landfills, and Leaking Underground Storage Tanks Near the Atlantic Coast Pipeline and Supply Header Project .......................................... 2-16 Table 2.2.1 -1 Watersheds Crossed by the Atlantic Coast Pipeline and Supply Header Project2-23 Table 2.2.2-1 Waterbodies Affected by the Atlantic Coast Pipeline and Supply Header Project2-24 Table 2.2.2-2 Major Waterbodies Crossed by the Atlantic Coast Pipeline and Supply Header Project................................................................................................................ 2-25 Table 2.2.2-3 Waterbodies Crossed by the Atlantic Coast Pipeline on Federal Lands ............ 2-25 Table 2.2.5-1 Surface Water Intake Facilities Within 3.0 Miles Downstream of and Water Protection or Assessment Watersheds Crossed by the Atlantic Coast Pipeline and SupplyHeader Project ....................................................................................... 2-31 Table 2.2.5-2 Water Source Watersheds Crossed by the Atlantic Coast Pipeline in North Carolina.............................................................................................................. 2-32 Table 2.2.6-1 Water Requirements for Horizontal Directional Drills for the Atlantic Coast Pipeline.............................................................................................................. 2-33 Table 2.2.7-1 Water Requirements for Hydrostatic Testing for the Atlantic Coast Pipeline and SupplyHeader Project ....................................................................................... 2-35 Table 2.3.2-1 Wetland and Waterbody Survey Status ............................................................. 2-44 Table 2.3.4-1 Summary of Wetland Types Affected by Construction and Operation of the Atlantic Coast Pipeline and Supply Header Project .......................................... 2-46 Table 2.3.4-2 Summary of Wetland Types Affected by Construction and Operation of the Atlantic Coast Pipeline on Federal Lands .......................................................... 2-48 Table 2.3.4-3 Summary of Wetlands Affected by Aboveground Facilities for the Atlantic Coast Pipeline.............................................................................................................. 2-48 Table 2.3.4-4 Summary of Wetlands Affected by Access Road Construction for the Atlantic Coast Pipeline and Supply Header Project ........................................................ 2-50 2 -iii Resource Report 2 11 Water Use and Quality LIST OF FIGURES Figure 2. 1. 1 -1 Principal Aquifers ................................................................................................ 2-5 LIST OF APPENDICES Appendix 2A Waterbodies Crossed and Crossing Methods for the Atlantic Coast Pipeline and Supply Header Project Appendix 2B hnpaired Waterbodies Crossed by the Atlantic Coast Pipeline and Supply Header Project Appendix 2C Sensitive Waterbodies Crossed by the Atlantic Coast Pipeline and Supply Header Project Appendix 2D Wetland and Waterbody Delineation Reports — Atlantic Coast Pipeline Appendix 2E Wetland and Waterbody Delineation Reports — Supply Header Project Appendix 2F Site -Specific Drawings for Major Waterbodies Crossed by the Atlantic Coast Pipeline Appendix 2G National Wetland Inventory Maps — Atlantic Coast Pipeline and Supply Header Project Appendix 2H Wetlands Crossed and Crossing Methods for the Atlantic Coast Pipeline and Supply Header Project 2 -iv �t Resource Report 2 Water Use and Quality, 2-v LIST OF ACRONYMS AND ABBREVIATIONS ACEP Agricultural Conservation Easement Program ACP Atlantic Coastline Pipeline ACRES Assessment, Cleanup, and Redevelopment Exchange System ACSA Augusta County Service Authority AGL AGL Resources, Inc. Atlantic Atlantic Coast Pipeline, LLC ATWS Additional Temporary Workspace CERCLIS Comprehensive Environmental Response, Compensation, and Liability Information System Certificate Certificate of Public Convenience and Necessity CFR Code of Federal Regulations Commission Federal Energy Regulatory Commission CSR Code of State Regulation CWF Cold Water Fisheries Dominion Dominion Resources, Inc. DTI Dominion Transmission, Inc. Duke Energy Duke Energy Corporation E2E estuarine intertidal emergent EPA U.S. Environmental Protection Agency ER Environmental Report FERC Federal Energy Regulatory Commission FOIA Freedom of Information Act FWS U.S. Fish and Wildlife Service GDS-NWR Great Dismal Swamp National Wildlife Refuge GIS geographic information system gpd gallons per day HDD horizontal directional drill HQ high quality waters HUC hydrological unit code LUST leaking underground storage tank M&R metering and regulating MMDth/d million dekatherms feet per day MP milepost MSW municipal solid waste NCAC North Carolina Administrative Code NCDENR-DWR North Carolina Department of Envirom-nent and Natural Resources Division of Water Resources NGL natural gas liquids NHD National Hydrography Dataset NPDES National Pollutant Discharge Elimination System NRCS National Resources Conservation Service NRI Nationwide Rivers Inventory NWI National Wetlands Inventory PAB palustrine aquatic bed PADEP Pennsylvania Department of Environmental Protection 2-v Resource Report 2 Water Use and Quality PEM PFO palustrine emergent wetland palustrine forested wetland Piedmont Piedmont Natural Gas Co., Inc. Plan Upland Erosion Control, Revegetation, and Maintenance Plan Procedures Wetland and Waterbody Construction and Mitigation Procedures Projects Atlantic Coast Pipeline and Supply Header Project PSS palustrine scrub -shrub wetland PUB palustrine unconsolidated bottom SHP Supply Header Project SPCC Plan Spill, Prevention, Control, and Countermeasures Plan SSURGO Soil Survey Geographic Database SWPO Source Water Protection Overlay USACE U.S. Army Corps of Engineers USDA U.S. Department of Agriculture USDOT U.S. Department of Transportation USFS U.S. Forest Service USGS U.S. Geological Survey VAC Virginia Administrative Code VDEQ Virginia Department of Environmental Quality VDH-ODW Virginia Department of Health — Office of Drinking Water VEGIS VDEQ's Environmental geographic information system VLIS Virginia's Legislative Information System WPA wellhead protection area WVCSR West Virginia Code of State Regulations WVDEP West Virginia Department of Environmental Protection WVDHHR West Virginia Department of Health and Human Resources ZCC Zone of Peripheral Concern ZPC Zone of Critical Concern 2 -vi ATLANTIC COAST PIPELINE – Docket Nos. CP15- — -000, CP15---000, CP15---000 U SUPPLY HEADER PROJECT – Docket No. CP15---000 2.0 RESOURCE REPORT 2 – WATER USE AND QUALITY Atlantic Coast Pipeline Atlantic Coast Pipeline, LLC (Atlantic) is a company formed by four major U.S. energy companies – Dominion Resources, Inc. (Dominion; NYSE: D), Duke Energy Corporation (Duke Energy; NYSE: DUK), Piedmont Natural Gas Co., Inc. (Piedmont; NYSE: PNY), and AGL Resources, Inc. (AGL; NYSE: GAS). 1 The company was created to develop, own, and operate the proposed Atlantic Coast Pipeline (ACP or Project), an approximately 564.1 -mile-long, interstate natural gas transmission pipeline system designed to meet growing energy needs in Virginia and North Carolina (see Figure 1. 1. 1 - 1 in Resource Report 1). The ACP will be capable of delivering up to 1.5 million dekatherms per day (MMDth/d) of natural gas that will be used to generate electricity, heat homes, and run local businesses. The pipeline Project will facilitate cleaner air, increase the reliability and security of natural gas supplies, and provide a significant economic boost in West Virginia, Virginia, and North Carolina. More information is provided at the company's website at www.dom.com/ac-oipeline. Atlantic has contracted with Dominion Transmission, Inc. (DTI), a subsidiary of Dominion, to permit, build, and operate the ACP on 2 behalf of Atlantic. Atlantic is seeking authorization from the Federal Energy Regulatory Commission (FERC or Commission) under Section 7(c) of the Natural Gas Act to construct, own, operate, and maintain the following proposed facilities for the ACP system: 3 Mainline Pipeline Facilities: AP -1: approximately 300.1 miles of underground 42 -inch outside diameter natural gas transmission pipeline in Harrison, Lewis, Upshur, Randolph, and Pocahontas Counties, West Virginia; Highland, Augusta, Nelson, Buckingham, Cumberland, Prince Edward, Nottoway, Dinwiddie, Brunswick, and Greensville Counties, Virginia; and Northampton County, North Carolina. AP -2: approximately 183.0 miles of underground 36 -inch outside diameter natural gas transmission pipeline in Northampton, Halifax, Nash, Wilson, Johnston, Sampson, Cumberland, and Robeson Counties, North Carolina. On August 24, 2015, Southern Company and AGL Resources announced that the boards of directors of both companies have approved a definitive merger agreement. Pursuant to the agreement, AGL Resources will become a new wholly owned subsidiary of Southern Company. The companies expert to complete the transaction in the second half of 2016. 2 As described in this report, DTI actions associated with the ACP are on behalf of Atlantic. 3 Atlantic is also requesting a Blanket Certificate of Public Convenience and Necessity pursuant to Part 284, Subpart G, of the Commission's regulations authorizing open -access transportation of natural gas for others with pre -granted abandonment authority, and a Blanket Certificate of Public Convenience and Necessity pursuant to Part 157, Subpart F, of the Commission's regulations authorizing certain facility construction and operation, certain certificate amendments and abandonments 2-1 Resource Report 2 Water Use and Quality Lateral Pipeline Facilities: AP -3: approximately 79.3 miles of underground 20 -inch outside diameter natural gas lateral pipeline in Northampton County, North Carolina; and Greensville and Southampton Counties and the Cities of Suffolk and Chesapeake, Virginia. AP -4: approximately 0.6 mile of underground 16 -inch outside diameter natural gas lateral pipeline in Brunswick County, Virginia. AP -5: approximately 1. 1 miles of underground 16 -inch outside diameter natural gas lateral pipeline in Greensville County, Virginia. Compressor Station Facilities: Compressor Station 1 (Marts Compressor Station): a new, natural gas-fired compressor station approximately at milepost 4 (MP) 7.6 of the AP -1 mainline in Lewis County, West Virginia. Compressor Station 2 (Buckingham Compressor Station): a new, natural gas- fired compressor station approximately at MP 191.5 of the AP - 1 mainline in Buckingham County, Virginia. Compressor Station 3 (Northampton Compressor Station): a new natural gas- fired compressor station approximately at MP 3 00.1 of the AP- 1 mainline and MP 0.0 of the AP -2 mainline and 0.0 of the AP -3 lateral in Northampton County, North Carolina. Other Aboveground Facilities: Nine new metering and regulating (M&R) stations at receipt and/or delivery points along the new pipelines (including one at Compressor Station I and one at Compressor Station 2). Thirty valve sites at select points along the new pipelines at intervals specified by U.S. Department of Transportation (USDOT) regulations at Title 49 Code of Federal Regulations (CFR) Part 192. Eight sets of pig launcher and/or receiver sites at I I points along the new pipelines (including launcher/receiver sites at Compressor Stations 2 and 3). As required by 18 CFR 380.12, Atlantic is submitting this Environmental Report (ER) in support of its Application to the Commission for a Certificate of Public Convenience and Necessity (Certificate) to construct and operate the proposed ACP facilities. 4 The mileposts used in this report are based on three-dimensional changes in topography (elevation) along the proposed pipeline routes. Therefore, the straight-line distance between two mileposts depicted on two-dimensional maps and figures of the routes may be less than 5,280 feet. The n-ffleposts are reference points along the routes. 2-2 F -I J Resource Report 2 Water Use and Quality Supply Header Project DTI proposes to construct and operate approximately 37.5 miles of pipeline loop and modify existing compression facilities in Pennsylvania and West Virginia (see Figure 1. 1. 1 - I in Resource Report 1). This Project, referred to as the Supply Header Project (SHP), will enable DTI to provide firm transportation service of up to 1.5 MMDth/d to various customers, including Atlantic. Atlantic will be a Foundation Shipper in the SHP, and will utilize the SHP capacity to allow its shippers access to natural gas supplies from various DTI receipt points for further delivery to points along the ACP. By providing its customers access to an affordable and stable source of natural gas, the SHP also satisfies the same purpose and need as the ACP by increasing the reliability and security of natural gas supplies in Virginia and North Carolina. DTI is seeking authorization from the Commission under Section 7(c) of the Natural Gas Act to construct, own, operate, and maintain the following proposed facilities for the SHP: Pipeline Loops: TL -636: approximately 3.9 miles of underground 30 -inch outside diameter natural gas pipeline looping DTI's existing LN -25 pipeline in Westmoreland County, Pennsylvania. TL -635: approximately 33.6 miles of underground 30 -inch outside diameter natural gas pipeline looping DTI's existing TL -360 pipeline in Harrison, Doddridge, Tyler, and Wetzel Counties, West Virginia. Compressor Station Modifications: 0 JB Tonkin Compressor Station: modifications at DTI's existing JB Tonkin Compressor Station in Westmoreland County, Pennsylvania. 0 Crayne Compressor Station: modifications at DTI's existing Crayne Compressor Station in Greene County, Pennsylvania. 0 Burch Ridge Compressor Station: crossover piping at DTI's existing Burch Ridge Compressor Station in Marshall County, West Virginia. 0 Mockingbird Hill Compressor Station: modifications at or near DTI's existing Mockingbird Hill Compressor Station in Wetzel County, West Virginia. Other Aboveground Facilities: One new M&R station at a new delivery point within Atlantic's proposed Compressor Station 1 in Lewis County, West Virginia. Six valve sites at select points along the new pipeline loops at intervals specified by USDOT regulations at 49 CFR 192. Two sets of pig launcher and receiver sites at the ends of each of the new pipeline loops. 2-3 Resource Report 2 Water Use and Quality DTI is also requesting authorization from the FERC under Section 7(b) of the Natural Gas Act to abandon in place two existing gathering compressor units (Hasting Compressor Units I and 2) at its existing Hastings Compressor Station in Wetzel County, West Virginia. As required by 18 CFR 380.12, DTI is submitting this ER in support of its Application to the Commission for a Certificate to construct and operate the proposed SHP facilities. Scope of Resource Report 2 This Resource Report describes water quality and provides data sufficient to determine the expected impact of the ACP and SHP (collectively, the Projects) and the effectiveness of mitigative enhancement, or protective measures. Information provided in this Report is derived from field surveys, technical documents, publicly available data and maps, and consultation with Federal, State/Commonwealth, and local authorities. This Report also addresses comments received from the public during the FERC Pre -filing Process as well as comments received directly from the FERC and other Federal and State/Commonwealth agencies. 2.1 GROUNDWATER RESOURCES 2.1.1 Principal Aquifers A principal aquifer is defined as a regionally extensive aquifer or aquifer system with the potential to be used as a source of potable water (U.S. Geological Survey [USGS], 2014a). The principal aquifers crossed by the proposed ACP are the Pennsylvanian, Mississippian, Valley and Ridge, Piedmont and Blue Ridge Crystalline -rock, and Early Mesozoic Basin aquifers, as well as the Northern Atlantic Coastal Plain aquifer system (USGS, 2003). The proposed SHP crosses the Pennsylvanian principal aquifer (USGS, 2003). Figure 2. 1.1 -1 depicts the principal aquifers and aquifer systems crossed by the proposed Projects. Information on each aquifer is summarized in Table 2. 1. 1 - 1. Principal aquifers are often multi -layered and may extend underground beyond the areas where they are mapped. The mapped boundaries typically represent the extent of the principal aquifer nearest to the surface (USGS, 1997). For example, the Mississippian aquifer is exposed as narrow bands along western West Virginia, but it underlies most of the Pennsylvanian aquifer. Because construction of the Projects will generally occur within the upper 10 feet of the soil surface, only the shallowest principal aquifers crossed by the Projects are described below. In addition to principal aquifers, the ACP and SHP cross areas where minor surficial aquifers are associated with glacial outwash or unconsolidated alluvium in stream valleys (USGS, 1997). These localized surficial aquifers are a source of water for private wells across the region, with greater significance along the AP -3 lateral in the coastal plain of Virginia. The ACP also crosses areas mapped as "other rocks." These consist of areas underlain by crystalline rocks of minimal permeability. Areas mapped as other rocks are considered minor aquifers. Potential impacts on these minor aquifers are similar to the Principal Aquifers and addressed in Section 2.1.6. 2-4 Resource Report 2 At" f t 'J, TL -636 k, if i� TL -635 0 0 v- 50 % 100 0 AP -1 150 4 200 250 L AP -4 0 AP -3 0 0 300 0 AP -5' 0 50 Ar -2 100 20 40 Wes 7,Domin io-n- �!LF M�,�l,�,ti,D�F�DOWSRPPI–ArcGiSlI Water Use and Quality X r v ACP Mainline Atlantic Coast Pipeline and ACP Lateral Supply Header Project SHP Pipeline Loops Figure 2. 1.1 -1 Principal Aquifers F_ P :_P,1 i�,I-Aquffers ffwd, REVISED 81215t2015. SCALIF DRAWN BY THohn 2-5 PimipafAqLsfers C.01. H.Y.. q.(,, J— ,d BUt A,d9e Orbolat—a qUf,, E t M-- b— q.0— Ped—i I'd EN,,, F�dqe aystalne ma quiu, Sodh.w— C..VW PI.. qr. y.— Wd�.Aft., C..,1.1 MI. qst— S.6-1 .,0,, y - 01h. MOI VAy .,id R,dq. wl- 41 am -, "�N -- qd— VA', Pop , ACP Mainline Atlantic Coast Pipeline and ACP Lateral Supply Header Project SHP Pipeline Loops Figure 2. 1.1 -1 Principal Aquifers F_ P :_P,1 i�,I-Aquffers ffwd, REVISED 81215t2015. SCALIF DRAWN BY THohn 2-5 Resource Report 2 Water Use and Quality 40.6 to 44.9 58A to 59.6 616 to 69.4 83.9 to 183.0 Halifax, Nash, Wilson, and Johnston Counties TABLE2.1.1-1 Piedmont and Blue Ridge 3 to 300 15 to 30 3 8.5 to 40.6 Aquifers Crossed by the Atlantic Coast Pipeline and Supply Header Project 44 9 to 58.1 59.6 to 616 Range of Well Yield State or Commonwealth/Pipeline Segment/ AP -3 Depth to (gallons per County or City Mileposts Aquifer a Aquifer (feet) minute) ATLANTIC COAST PIPELINE West Virginia West Virginia TL -635 Wetzel, Tyler, Doddridge, and Harrison Counties AP -1 Pennsylvanian Sandstone 80 to 400 20 to 430 Harrison, Lewis, Upshur, and Randolph Counties 0 to 52 1 Pennsylvanian Sandstone 80 to 400 20 to 430 63.5 to 65.9 66.6 to 68.8 Randolph and Pocahontas Counties 52.1 to 53.8 Mississippian Sandstone and 50 to 200 20 to 180 616 to 63.5 Carbonate 65 9 to 66.6 68.8 to 710 Randolph and Pocahontas Counties 53 8 to 61.6 Otherrocks Unavailable b Variable 710 to 83.1 Virginia AP -1 Highland County 83 1 to 86.0 Otherrocks Unavailable b Variable Highland and Augusta Counties 86.0 to 151.6 Valley and Ridge Sandstone 50 to 400 Variable and Carbonate Augusta, Nelson, Buckingham, Cumberland, Prince 151.6 to 210.3 Piedmont and Blue Ridge 3 to 300 15 to 30 Edward, Nottoway, Dmwiddie, Brunswick, and 216 6 to 286 8 Crystalline -rock Greensville Counties Buckingham and Cumberland Counties 210.3 to 216.6 Early Mesozoic Basin 200 to 900 5 to 80 Sandstone Greensville County 286 8 to 300.1 Northern Atlantic Coastal 30 to 2100 At least 50 Plain Semiconsolidated Sand AP -3 Greensville and Southampton Counties, City of 12.1 to 78.1 Northern Atlantic Coastal 30 to 2100 At least 50 Suffolk, and City of Chesapeake Plain Semiconsohdated Sand AP -4 Brunswick County 0.0 to 0.6 Piedmont and Blue Ridge 3 to 300 15 to 30 Crystalline -rock AP -5 Greensville County 0 0 to 1.1 Piedmont and Blue Ridge 3 to 300 15 to 30 Crystalline -rock North Carolina AP -2 Northampton, Halifax, Nash, Wilson, Johnston, 0 0 to 31.5 Northern Atlantic Coastal 30 to 2100 At least 50 Sampson, Cumberland, and Robeson Counties 34.3 to 38 5 Plain Serniconsolidated Sand 40.6 to 44.9 58A to 59.6 616 to 69.4 83.9 to 183.0 Halifax, Nash, Wilson, and Johnston Counties 31.5 to 34.3 Piedmont and Blue Ridge 3 to 300 15 to 30 3 8.5 to 40.6 Crystalline -rock 44 9 to 58.1 59.6 to 616 69.4 to 83.9 AP -3 Northampton County 0.0 to 12 1 Northern Atlantic Coastal 30 to 2100 At least 50 Plain Serniconsolidated Sand SUPPLY HEADER PROJECT West Virginia TL -635 Wetzel, Tyler, Doddridge, and Harrison Counties 0.0 to 33.6 Pennsylvanian Sandstone 80 to 400 20 to 430 2-6 Resource Report 2 Water Use and Quality TABLE 2. 1. 1 -1 (cont'd) Aquifers Crossed by the Atlantic Coast Pipeline and Supply Header Project State or Commonwealth/Pipeline Segment/ County or City Mileposts Aquifer Pennsylvania TL,636 Westmoreland County 0 to 3.9 Pennsylvanian Sandstone Range of Well Yield Depth to (gallons per Aquifer (feet) minute) 80 to 400 20 to 430 a Figure 2. 1. 1 -1 differentiates carbonate and sandstone components, identified in the legend, associated with the geographically expansive Mississippian and Valley and Ridge Aquifers, which are combined to align with the resource report text and table. b Unavailable — reliable depth to aquifer data is unavailable in the Groundwater Atlas of the United States and other publicly available publications. Sources. Kozar and Brown, 1995, LeGrand, 1988; Swistock, 2007 2.1.1.1 Pennsylvanian and Early Mesozoic Basin Aquifers The Pennsylvanian and Early Mesozoic Basin aquifers consist of layers of consolidated sedimentary rock, of which sandstone formations are the primary water -producing units (USGS, 1997a). Sandstone retains only a small part of the intergranular pore space present before the rock was consolidated, and compaction and cementation have greatly reduced the primary pore space in the rock (USGS, 1999). Secondary openings in the rock, such as joints and fractures, along with bedding planes, contain and transmit most of the groundwater in the formation (USGS, 1999). The hydraulic conductivity of sandstone aquifers is low to moderate, but because they extend over large areas, these aquifers can provide large amounts of water (USGS, 1999). As of 2005, water withdrawals from Early Mesozoic basins aquifers were 131 million gallons per day (gpd), including 41.9 million gpd in Pennsylvania and 2.1 million gpd in Virginia (Maupin and Barber, 2005). Water withdrawals from Pennsylvanian aquifers were 132 million gpd, including 43.6 million gpd in Pennsylvania and 18.3 million gpd in West Virginia (Maupin and Barber, 2005). 2.1.1.2 Mississippian and Valley and Ridge Aquifers Mississippian aquifers mostly consist of water yielding carbonate rocks. They are considered principle aquifers in many regions of the United States, but in the ACP Project area, they are limited in geographic extent and only yield water in localized areas (USGS, 1997a). Valley and Ridge aquifers mostly consist of folded sandstone, shale, and limestone. In Virginia, these rock formations also contain coal and minor amounts of dolomite and conglomerate. In some cases, the rocks have been metamorphosed into quartzite, slate, and marble. Carbonate rocks are the most productive rock units in the Valley and Ridge aquifers (USGS, 1997b), and they are the water producing rock units of the Mississippian aquifers (USGS, 1997a). As of 2005, water withdrawals from sandstone and carbonate rocks in Mississippian aquifers were 286 million gpd, including 0.9 million gpd in West Virginia and 0.1 million gpd in Virginia (Maupin and Barber, 2005). Water withdrawals from the Valley and Ridge aquifers were 95 million gpd, including 34.2 million gpd in Virginia (Maupin and Barber, 2005). 2-7 Resource Report 2 Water Use and Quality Most carbonate rocks originate as sedimentary deposits in marine environments (USGS, 1999b). Compaction, cementation, and dolomitization processes can substantially reduce the porosity and permeability of these deposits as they lithify (USGS, 1999b). The dissolution of carbonate rock by circulating, slightly acidic groundwater, however, can create solution openings ranging in size from small tubes to caverns that may be tens of meters wide and hundreds to thousands of meters long (USGS, 1999). Where saturated, carbonate rocks with well-connected networks of solution openings yield large amounts of water to wells that penetrate the openings, although the undissolved rock between the large openings may be almost impermeable (USGS, 1999b). The dissolution of carbonate rock can result in the formation of sinkholes and other karst features (USGS, 1999b). Karst terrain is discussed in more detail in Section 6.4.4 of Resource Report 6. 2.1.1.3 Piedmont and Blue Ridge Crystalline -rock Aquifers The Piedmont and Blue Ridge aquifers mostly consist of crystalline rocks (i.e., metamorphic and igneous rocks), but they also include some carbonate rocks (USGS, 1997c). Major bedrock units crossed by the ACP in the Piedmont Province include Proterozoic -aged gneiss, Tertiary -aged gravel, and Permian to Proterozoic -aged granite. Major bedrock units crossed by the ACP in the Blue Ridge Province include Cambrian -aged sedimentary dolostone (dolomite) and Proterozoic -aged granitic gneiss. Carbonate rocks provide the largest well yields in the Piedmont and Blue Ridge aquifers (USGS, 1997c). A description of carbonate rock aquifers is provided above (see Mississippian and Valley and Ridge Aquifers). Igneous and metamorphic rocks are only permeable where they are fractured, and they generally yield only small amounts of water to wells. Because these rocks extend over large areas, however, significant volumes of water are available from these formations. As of 2005, water withdrawals from the Piedmont and Blue Ridge carbonate -rock aquifers were 29.9 million gpd (Maupin and Barber, 2005). Water withdrawals from the Piedmont and Blue Ridge crystalline -rock aquifers were 146 million gpd, including 14.5 million gpd in Virginia and 62.6 million gpd in North Carolina (Maupin and Barber, 2005). 2.1.1.4 North Atlantic Coastal Plain Aquifer System The Northern Atlantic Coastal Plain aquifer system mostly consists of semi -consolidated sand aquifers separated by clay confining units. Major geologic units crossed by the proposed ACP facilities in the Coastal Plain Province include Cretaceous to Quaternary -aged sedimentary deposits (e.g., clay or mud, sand, gravel, and alluvium) and Cretaceous -aged sandstone. Unconsolidated sands compose the surficial aquifer, which is the uppermost water -yielding part of the system. These surficial aquifers are susceptible to human activities due to the shallow depth to the aquifer in some areas (USGS, 1997d). Additionally, sediments in Coastal Plain aquifers are thin near their contact with rocks of the Piedmont Province, and in places do not yield as much water as the underlying igneous and metamorphic rocks associated with Piedmont I aquifers (USGS, 1997). The Northern Atlantic Coastal Plain aquifer system also includes a productive carbonate rock (limestone) aquifer. A description of carbonate rock aquifers is provided above (see Mississippian and Valley and Ridge Aquifers). W Resource Report 2 Water Use and Quality As of 2015, water withdrawals from the Northern Atlantic Coastal Plain aquifer system were 1,040 million gpd, including 90.8 million gpd in Virginia and 142 million gpd in North Carolina (Maupin and Barber, 2005). The limestone aquifer is most productive in North Carolina, where yields reached 125 million gpd in 1985 (USGS, 1997d). 2.1.2 Designated Sole or Principal Source Aquifers The U.S. Environmental Protection Agency (EPA) "defines a sole or principal source aquifer as an aquifer that supplies at least 50 percent of the drinking water consumed in the area overlying the aquifer. These areas may have no alternative drinking water source(s) that could physically, legally and economically supply all those who depend on the aquifer for drinking water" (EPA, 2008). For convenience, the EPA refers to all designated sole or principal source aquifers as "sole source aquifers" (EPA, 2008). There are currently no EPA -designated sole source aquifers in West Virginia (EPA, 2008). The West Virginia Department of Envirom-nental Protection (WVDEP) and West Virginia Department of Health and Human Resources (WVDHHR) do not designate sole source aquifers on a State level (Paucer, 2015; Shaver 2015). There are currently no EPA -designated sole source aquifers in North Carolina (EPA, 2008). The North Carolina Department of Environment and Natural Resources, Division of Water Resources (NCDENR-DV%TR) does not designate sole source aquifers on a State level (Johnson, 2015). The only EPA -designated sole source aquifer in Virginia is the Columbia & Yorktown - Eastover Multiaquifer System, which is across the Chesapeake Bay and over 25 miles to the northeast of the nearest ACP facility (EPA, 2007 and 2013 a). The Commonwealth of Virginia regulates groundwater withdrawal within two Ground Water Management Areas that are managed by the Virginia Department of Environmental Quality (VDEQ) in accordance with the Ground Water Management Act of 1992. These management areas are outlined under Title 9 of Virginia Administrative Code (VAC) Agency 25, Chapter 600, Section 20 (Virginia's Legislative hiformation System [VLIS], 2014a). The portions of the ACP within the Cities of Suffolk and Chesapeake and Southampton County occur within the Eastern Virginia Groundwater Management Area (VDEQ, 2014a). The other management area, the Eastern Shore Groundwater Management Area, is located in the Counties of Accomack and Northampton, over 25 miles to the northeast of the nearest ACP facility. There are two sole source aquifers in Pennsylvania, but both are located far from the nearest proposed SHP facilities. The Seven Valleys Aquifer and New Jersey Coastal Plain Aquifer are located approximately 140 miles southeast and 300 miles east of the nearest SHP facilities, respectively (EPA, 2008). The Pennsylvania Department of Environmental Protection (PADEP) Bureau of Safe Drinking Water does not designate sole source aquifers on a Commonwealth level and defers to EPA -designated sole source aquifers in the region (Reisch, 2015). 2.1.3 Water Supply Wells Atlantic and DTI are in the process of identifying public and private supply wells and springs within the Project area, as outlined below. Atlantic will continue to identify public and 2-9 Resource Report 2 Water Use and Quality private supply wells and springs within 150 feet of the construction workspace. In addition, wells and springs will be identified within 500 feet of the proposed pipelines in karst areas and within 0.25 mile of horizontal directional drill (HDD) activities. 2.1.3.1 Public Wells Atlantic consulted with the WVDHHR Source Water Assessment and Wellhead Protection Program, Virginia Department of Health — Office of Drinking Water (VDH-ODW), and NCDENR-DWR to obtain -location data for public water supply wells within 150 feet of the workspace for proposed ACP facilities. DTI similarly consulted with the WVDHHR and PADEP Bureau of Safe Drinking Water to obtain location data for public water supply wells within 150 feet of the proposed workspace for the SHP facilities. The results of these consultations are described below and summarized in Table 2.1.3-1. TABLE 2.1.3-1 I Public Water Supply Wells Within 150 Feet of the Atlantic Coast Pipeline and Supply Header Project Facility/County or City/State or Distance and Direction Commonwealth Milepost(s) Public Water Well Name from Workspace (feet) ATLANTIC COAST PIPELINE AP -1 None Identified AP -2 Wilson County, NC Cumberland County, NC AP -3 None Identified AP4 None identified AP -5 None identified Aboveground Facilities None identified SUPPLY HEADER PROJECT TL -635 None identified TL -636 None identified Aboveground Facilities None identified 67.5 Town of Sims 141.6 United Church of Christ Shiloh Within Workspace 121, NW Location data for water supply wells is not publicly available in West Virginia. However, the WVDHHR reviewed maps of the proposed ACP and SHP facilities to identify public water supply wells located along or near the proposed facilities in West Virginia. The WVDHHR (2015a) did not identify any public water wells within 150 feet of the proposed workspace for the ACP and SHP facilities in West Virginia. The VDH-ODW provided Atlantic with digital location data for public water supply wells in Virginia (Soto, 2015). No public water supply wells were identified within 150 feet of the proposed workspace for the ACP facilities in Virginia. at$] Resource Report 2 Water Use and Quality Public water supply well data was acquired from the NCDENR-DWR (2014a). Review of these data identified two public wells within 150 feet of the proposed workspace for the AP -2 mainline in North Carolina. The PADEP Bureau of Safe Drinking Water identified the eMapPA application as the best source of information on public water supply wells in the Commonwealth (McCaffrey, 2015). No public wells were identified within 150 feet of the TL- 636 loop and other SHP facilities in Pennsylvania through review of this application (PADEP, 2015a). 2.1.3.2 Private Wells Location data for private wells are not readily available from the PADEP, WVDHHR, VDEQ, VDH-ODW, and NCDENR-DWR. Atlantic and DTI, respectively, are documenting locations of private wells within 150 feet of the proposed ACP and SHP facilities through discussions with landowners and field (civil) surveys: Private water supply wells identified to date within 150 feet of the proposed workspace for the ACP and SHP facilities are listed in Table 2.1.3-2. Atlantic will continue to identify private supply wells within 150 feet of the construction workspace. In addition, wells will be identified within 500 feet of the proposed pipelines in karst areas and within 0.25 mile of horizontal directional drill (HDD) activities. These additional survey efforts are scheduled to begin in the Fall of 2015. Results of the surveys will be provided in supplemental filing. 2.1.3.3 Wellhead Protection Areas Amendments to the Safe Drinking Water Act in 1986 established requirements for States to implement wellhead protection programs designed to protect underground sources of drinking water. A wellhead protection area (ATA) is an area around a public water supply well that has been delineated to regulate and protect the water supply drawn by the well. The size of the WPA is based on an evaluation of geology and hydraulics or is mandated based on the type of public water supply well. Shallow wells, which are susceptible to impacts on near surface groundwater, generally have larger surface protection areas than deeper wells. Atlantic and DTI, respectively, are consulting with the State/Commonwealth agencies responsible for overseeing wellhead protection programs to identify WPAs proximate to the proposed ACP and SHP facilities (i.e., the WVDHHR, VDEQ, VDH, NCDENR-DVY'R, and PADEP). Crossings of WPAs identified by these agencies along the proposed facilities are identified in Table 2.1.3-3. In West Virginia, the Source Water Assessment and Wellhead Protection Program is administered by the W-VDHHR. While locations of WPAs data are not publically available, the W'VDHHR (2015a, 2015b) reviewed the proposed facilities. No WPAs were identified within 3 miles of the ACP or SHP facilities (WVDHHR, 2015b). 2-11 Resource Report 2 Water Use and Quality TABLE 2 13-2 Private Water Wells Within 150 Feet of the Atlantic Coast Pipeline and Supply Header Project Distance (feet) and Direction Facility/County or City/State or Commonwealth Milepost From Workspace ATLANTIC COAST PIPELINE 17, W Nash County, NC AP -1 18, SE Nash County, NC Lewis County, WV 2.2 Within Workspace Lewis County, WV 9.4 3, E Upshur County, W 39.5 3 1, NE Augusta County, VA 120.9 39, SW Nottoway County, VA 229.9 24, NE Nottoway County, VA 240.8 4,S AP -2 Halifax County, NC 319.9 54, SE Nash County, NC 3322 17, W Nash County, NC 3381 18, SE Nash County, NC 3473 90, NW Nash County, NC 347.5 65, NW Nash County, NC 347.5 Within Workspacc Nash County, NC 347.6 Within Workspacc Nash County, NC 353.3 Within Workspace Johnston County, NC 379.2 70, W Johnston County, NC 385.1 Within Workspace Johnston County, NC 401.2 Within Workspacc Cumberland County, NC 433.5 Within Workspace Cumberland County, NC 433.6 Within Workspace Cumberland County, NC 450.6 86, NW Robeson County, NC 466.1 119's Robeson County, NC 474.1 77,S AP -3 Southampton County, VA 24.0 146, NW City of Suffolk, VA 58.2 5,S AP -4 None identified to date AP -5 None identified to date Abovcground Facilities None identified to date SUPPLY HEADER PROJECT TL -635 Doddndgc County, WV 15.2 117, E TL -636 Westmoreland County, PA 12 70, S The Commonwealth of Virginia, under the oversight of VDEQ and VDH, has a Wellhead Protection Plan that was adopted in April 2005 (VDEQ, 2005). The plan provides a framework for establishing wellhead protection areas and a process for local agencies and various I government units to apply for funding to implement wellhead protection plans for public water supplies. Atlantic consulted with the VDH-ODW to identify public water wells that may have associated wellhead protection areas. The VDH-ODW conducted Source Water Assessments and susceptibility evaluations in 2003, after which Zone 1 and Zone 2 Groundwater Assessment 2-12 0 Resource Report 2 Water Use and Quality Areas were defined as a 1,000 -foot and 1 -mile fixed radius surrounding a source, respectively (VDH, 1999). Atlantic identified two Zone 1 Groundwater Assessment Areas crossed by the proposed route, and 10 Zone 2 Groundwater Assessment Areas. Of these Groundwater Assessment Areas crossed, Atlantic identified one wellhead protection area crossed between MP 145.5 and 147.0 in Augusta County, where groundwater protection measures have been implemented. Atlantic will evaluate these measures for use during construction. Augusta County has established Source Water Protection Overlay (SWPO) Districts, divided into Area 1 and Area 2 classification, to protect public groundwater supply sources. Lyndhurst Area 2 SWPO District, which is crossed by the proposed route, is defined as an area that contributes to recharge of a public groundwater supply source (Augusta County, 2011). The Augusta County Service Authority (ACSA) noted that the Lyndhurst Well is the largest in the county and provides water to various residential, commercial, and industrial consumers (Hoover, 2015). Atlantic is reviewing information to potentially further minimize the crossing of Lyndhurst Area 2 SWPO District. TABLE 2.13-3 Wellhead Protection Areas Crossed by the Atlantic Coast Pipeline and Supply Header Project Facility/County or City/State or Commonwealth Milepost(s) Wellhead Protection Area Crossing Length (feet) ATLANTIC COAST PIPELINE AP -1 Lyndhurst/Augusta, VA 145.5 —147.0 Lyndhurst Well 15 miles AP -2 None identified AP -3 None identified AP4 None identified AP -5 None identified Aboveground Facilities None identified SUPPLY HEADER PROJECT TL -635 None identified TL,636 None identified Aboveground Facilities None identified The NCDENR-DWR (NC OneMap, 2015a) provided Atlantic with statewide digital data for WPAs in North Carolina. Based on) provided Atlantic with statewide digital data for WPAs in North Carolina. Based on a review of this data, no WPAs are crossed by the proposed ACP facilities in North Carolina. The nearest VVTA is located approximately 0.8 mile from MP 382.0 of the AP -2 mainline. Based on a review of data from the Pennsylvania Groundwater Information System, no WPAs are crossed by the proposed SHP facilities in Pennsylvania (Pennsylvania Department of Conservation and Natural Resources, 2015). 2-13 Resource Report 2 Water Use and Quality 2.1.4 Springs 0 Based on a review of USGS 7.5 -minute series topographic maps and the results of discussions with landowners, civil field surveys, and biological field surveys conducted to date, four springs are located within 150 feet of the proposed workspace for the ACP AP -1 mainline (see Table 2.1.4-1). Atlantic will continue to identify springs within 150 feet of the construction workspace. In addition, springs will be identified within 500 feet of the proposed pipelines in karst areas and within 0.25 mile of HDD activities. These additional survey efforts are scheduled to begin in the Fall of 2015. Results of the surveys will be provided in supplemental filing. TABLE 2 14-1 Springs Located Within 150 Feet of the Atlantic Coast Pipeline and Supply Header Project lb Pipeline Segment/County or City/ Distance and Direction from Workspace Surface Drainage Direction State or Commonwealth Approximate Milepost (feet) of Spring from Project' ATLANTIC COAST PIPELINE AP -1 Highland County, VA 85.3 51, SW Up Gradient Augusta County, VA 115.2 140, N Up Gradient Buckingham County, VA 204.0 Within Workspace Side Gradient Buckingham County, VA 204.0 33, NE Down Gradient a No springs are located within 150 feet of the Atlantic Coast Pipeline in West Virginia or North Carolina, or within 150 feet of the Supply Header Project. b Spring information is based on USGS 7.5 -minute series topographic maps, discussions with landowners, civil field surveys, and biological field surveys. C Surface drainage direction of a spring is evaluated from the pipeline right-of-way. Atlantic reviewed comments regarding potential for the ACP to influence sinking points in the Cowpasture River valley that feed the Coursey Springs State Fish Hatchery.5 Within the Cowpasture River watershed the ACP will remain over 1,500 feet from VDCR documented sinkholes. In addition, the ACP crosses the Cowpasture River approximately 11 miles to the northeast, upstream of the Coursey Springs State Fish Hatchery. The immediate watershed that feeds into the hatchery along the Pheasanty Run is not crossed by the ACP. Atlantic will construct across the Cowpasture River using the dam -and -pump method in accordance with the Plan and Procedures (see Section 1.5.2.1 of Resource Report 1 for a description of this method), and will restore the bed, banks, and water flow to the Cowpasture River once construction across the river is complete. 2.1.5 Contaminated Groundwater Atlantic and DTI, respectively, searched Federal and State/Commonwealth databases to identify contaminated sites, including sites which may have contributed to contaminated groundwater, in the vicinity of the proposed ACP and SHP facilities. The EPA's Facility Registry System map service was used to locate sites within one mile of the Projects that are 5 During the ACP and SHP Open Houses, and in comments filed with the FERC, a comment suggested that ACP crosses a recharge area that feeds the Coursey Springs State Fish Hatchery. C-) 2-14 Resource Report 2 Water Use and Quality listed on the Comprehensive Environmental Response, Compensation, and Liability Information System (CERCLIS) and the Assessment, Cleanup and Redevelopment Exchange System (ACRES) (EPA, 2014) .6 In addition, various other map services and databases were reviewed for each State/Commonwealth as described below. As shown in Table 2.1.5-1, the review of EPA records identified one Federal Brownfield site and six Federal Superfund sites mapped within one mile of the proposed ACP and SHP facilities. The majority of these federally -listed contaminated sites are located along the eastern extent of the proposed AP -3 lateral, where it crosses industrialized areas within the City of Chesapeake, Virginia. Based on the geospatial point data available on the EPA's Facility Registry System map service, Envirofacts online database, and additional site-specific information that was provided to Atlantic by EPA staff, none of the Federal Brownfield or Superfilnd sites are known to be crossed by the proposed route for the ACP facilities. In order to verify the boundaries associated with each of the federally -listed sites located within one mile of the proposed ACP facilities, Atlantic submitted several site-specific information requests to the EPA asking for additional documentation to confirm the boundaries of each Federal Superfund and Brownfield site listed in Table 2.1.5-1. The boundaries have been verified for six of the seven Federal Superfimd and Brownfield sites listed in Table 2.1.5-1, none of which are crossed by the proposed ACP facilities. However, verification of site boundaries for the Borden Smith Douglass Superfund Site is pending a response from the EPA to a Freedom of Information Act (FOIA) request that was submitted by Atlantic in August 2015. The response is anticipated to be provided by the EPA in September 2015. In addition to the EPA resources, Atlantic and DTI reviewed the WVDEP web -based list of municipal solid waste landfills and online database of leaking underground storage tanks (LUST). No contaminated sites were found within one mile of the proposed ACP and SHP facilities in West Virginia (WVDEP, 2013, 2014b, 2014c). The VDEQ's Environmental geographic information system (VEGIS) system was used to obtain geospatial databases of LUSTS and other solid or hazardous waste sites in Virginia (VDEQ, 2014b). Review of these sources identified one municipal solid waste (MSW) landfill complex, one industrial landfill, and one inert landfill mapped within 0.5 mile and 18 LUST sites mapped within 1,000 feet of the proposed ACP facilities in Virginia. Based on the geospatial point data and additional site-specific information provided by the VDEQ, a portion of the Augusta Regional Landfill may be crossed by the proposed route for the AP -I mainline. Therefore, as discussed in Section 2.1.6, Atlantic has incorporated a route adjustment that increases the distance between the AP -1 mainline and the landfill in order to mitigate the potential impacts of blasting that is anticipated to take place near the Augusta Regional Landfill site boundary. The review of VDEQ records indicated that none of the other contaminated sites identified will be crossed by the proposed ACP facilities. In addition, eight of the sites are estimated to be hydraulically down gradient from the proposed ACP facilities and are therefore unlikely to contribute to groundwater contamination in the vicinity of the proposed ACP facilities. 6 CERCLIS and ACRES sites are commonly known as Federal Superfund and Brownfield sites, respectively. 2-15 Resource Report 2 Water Use and Quality TABLE 2.1.5-1 Contaminated Sites, Landfills, and Leaking Underground Storage Tanks Near the Atlantic Coast Pipeline and Supply Header Project' Surface County/ City and Distance and Drainage State/ Pipeline Nearest Direction from Direction from Commonwealth Segment Milepost Site Name Centerlme (ft) Facility Type projeetb ATLANTIC COAST PIPELINE CERCLIS and ACRES Sites Identified within I mile of the Centerline and Aboveground Facilities Northampton, NC AP -2 78 Garysburg Community 1,510 W Brownfield Up Gradient Center Johnston, NC AP -2 912 Hot -Z Selina Spill 1,124 W Superfund Site Up Gradient Cumberland, NC AP -2 142.8 Woody's Salvage Yard 252 SE Superfand Site Down Gradient Chesapeake, VA AP -3 77.3 Norfolk hitercoastal. Steel 201 SE Superfund Site Side Gradient Chesapeake, VA AP -3 78.1 Money Point Creosite Site 124 N Superfund Site Down Gradient Chesapeake, VA AP -3 78.5 Eppinger & Russel Co hic. 1,250 N Superfund Site Down Gradient Chesapeake, VA AP -3 79.0 Borden Smith Douglass los Superfund Site Side Gradient Landfill and Solid Waste Sites Identified within 0.5 mile of the Centerline and Aboveground Facilities Augusta, VA AP -1 141.4 Jolivue Landfill/Augusta 586 NE Closed MSW Landfill Up Gradient Regional Landfill and Active MSW Landfill Complex Chesapeake, VA AP -3 155.1 Dominion Chesapeake 247 E Closed Industrial Side Gradient Energy Center Landfill and Active Industnal Landfill Chesapeake, VA AP -3 79.1 Atlantic Aggregate Recyclers 269N E inert Landfill Up Gradient Leaking Underground Petroleum Storage Tank (LUST) Sites within 1000 feet of the Centerline and Aboveground Facilities Augusta, VA AP -1 143.9 Starkey Residence 148 SW LUST Side Gradient Nelson, VA AP -1 1825 Woodson's Grocery 237 E LUST Side Gradient Buckingham, VA AP -1 209.3 Betty Brown Property 197 NE LUST Up Gradient Nash, NC AP -2 49.0 NCCU-Turner Law School 256 SE LUST Side Gradient Nash, NC AP -2 49.0 NCCU-Eagleson Hall 82 NW LUST Down Gradient Johnston, NC AP -2 90.7 Days Inn Motel 9 SE LUST Side Gradient Johnston, NC AP -2 108.1 Tippet Residential 188 SE LUST Down Gradient Sampson, NC AP -2 117.8 Plain View Grocery 294 SE LUST Up Gradient Robeson, NC AP -2 1818 Rudy's Restaurant 233 SW LUST Down Gradient Southampton, VA AP -3 23.6 Cooke Residence 269 NW LUST Up Gradient Suffolk, VA AP -3 City of Suffolk Pump Station LUST Side Gradient 62.0 11 244 NW Chesapeake, VA AP -3 75.2 Deep Creek Pharmacy 70 SW LUST Down Gradient Chesapeake, VA AP -3 75.3 BOX USA Group, hic. 284 N LUST Up Gradient Chesapeake, VA AP -3 754 Mid Atlantic Repair, hic. 163 S LUST Down Gradient Chesapeake, VA AP -3 75.4 Watkins Motor Lines, hic llos LUST Down Gradient Chesapeake, VA AP -3 766 Deep Creek Pumping Station 235 N LUST Up or Side Gradient Chesapeake, VA AP -3 77.8 IMT -r -Chesapeake Terminal 200 NW LUST Up or Side Gradient Chesapeake, VA AP -3 782 Chesapeake Energy Center 196S LUST Up or Side Gradient Chesapeake, VA AP -3 782 Chesapeake Energy Center 205S LUST Up or Side Gr -adient Chesapeake, VA AP -3 78.2 Chesapeake Energy Center 211 S LUST Up or Side Gradient 2-16 0 0) Resource Report 2 Water Use and Quality TABLE 2 15-1 (cont'd) Contaminated Sites, Landfills, and Leaking Underground Storage Tanks Near the Atlantic Coast Pipeline and Supply Header Project' Surface County/ City and Distance and Drainage State/ Pipeline Nearest Direction from Direction from Commonwealth Segment Milepost Site Name Centerline (ft) Facility Type ,tb projer Chesapeake, VA AP -3 78.2 Chesapeake Energy Center 203S LUST Up or Side Gradient Chesapeake, VA AP -3 78.2 Chesapeake Energy Center 243S LUST Up or Side Gradient Chesapeake, VA AP -3 78.6 OneSteel Recycling, Inc. 266 N LUST Up or Side Gradient Chesapeake, VA AP -3 78.7 Former Smith Douglas Plant 135S LUST Up or Side Gradient a No contaminated sites, landfills, or LUST sites were found within the search distances identified above for SHP. b USGS topographic maps were reviewed to evaluate the topographic disposition of each site in relation to the Projects. The NCDENR OneMap Geospatial Portal was used to obtain geospatial databases of LUSTS, landfills, and other solid or hazardous waste sites in North Carolina (NCDENR, 2014a, 2014b, 2014c). Review of these sources identified six LUST sites mapped within 1,000 feet of the proposed ACP facilities in North Carolina. Based on the geospatial point data available on the OneMap Geospatial Portal, none of the contaminated sites located in North Carolina appear to be crossed by the proposed facilities. In addition, three of these sites are located hydraulically down gradient from the proposed ACP facilities and are therefore unlikely to have contributed to groundwater contamination in the vicinity of the proposed ACP facilities. The PADEP's web -based list of Municipal Waste Landfills & Resource Recovery Facilities and an online database for Bureau of Environmental Cleanup and Brownfields Regulated Storage Tank Cleanup Incidents was reviewed to identify contaminated sites in Pennsylvania (PADEP, 2014). No contaminated sites were identified within one mile of the proposed SHP facilities in Pennsylvania in these or the EPA sources. As discussed in Section 2.6.1, Atlantic and DT1 are currently coordinating with Augusta County in order to minimize the impact of the proposed ACP facilities on the Augusta Regional Landfill. In addition, Atlantic and DTI are currently awaiting a response from the EPA in order to verify the site boundaries of the Borden Smith Douglass Superfund Site. Based on the geospatial data and other information provided by State/Commonwealth and Federal agencies, Atlantic and DTI have concluded that none of the other contaminated sites listed in Table 2.1.5-1 are crossed by the current route for the proposed ACP facilities. However, in the event that contaminated soil or groundwater is encountered during construction, Atlantic and DTI will implement the appropriate containment and mitigation measures described in the Contaminated Media Plan (see Appendix 1F of Resource Report 1). 2.1.6 Groundwater Construction Related Impacts and Mitigation Standard procedures for construction of the pipeline and aboveground facilities could potentially affect groundwater in Several ways. Clearing, grading, trenching, and soil stockpiling activities could temporarily alter overland flow and groundwater recharge or could result in minor fluctuations in groundwater levels and/or increased turbidity. Near -surface soil 2-17 Resource Report 2 Water Use and Quality compaction caused by the operation of heavy construction equipment could reduce the ability of soil to absorb water, which could increase surface runoff and the potential for ponding. These impacts will be minimized or avoided through implementation of the construction practices outlined in the 2013 versions of the FERC's Upland Erosion Control, Revegetation, and Maintenance Plan (Plan) and Wetland and Waterbody Construction and Mitigation Procedures (Procedures). Ground disturbance associated with construction of pipelines and aboveground facilities is generally within the upper 10 feet or less of the existing ground surface, which is above the typical minimum depth of the bedrock aquifers in the areas crossed by the Projects. A depth of 10 feet is also above most near -surface aquifers and most wells that might be completed in a localized shallow aquifer. Where near -surface aquifers are present or localized alluvial aquifers occur, they typically consist of unconsolidated alluvial sand and gravel exhibiting rapid recharge and groundwater movement. If disturbed, these aquifers quickly re-establish equilibrium and turbidity levels rapidly subside, such that impacts are localized and temporary. Upon completion of construction, Atlantic and DTI will restore the ground surface as closely as practicable to original contours and reestablish vegetation on the right-of-way to facilitate restoration of preconstruction overland flow and recharge patterns. To minimize the potential impact of hazardous material spills on surficial aquifers during construction and operation of the ACP and SHP, Atlantic and DTI have prepared and will implement a Spill Prevention, Control, and Countermeasures Plan (SPCC Plan) (see Appendix lF of Resource Report 1). Hazardous or toxic materials used on the right-of-way would typically be limited to fuels, oils, lubricants, and in some cases blasting materials. These materials would be handled in accordance with the SPCC Plan and Blasting Plan. In addition, to minimize impacts associated with construction water discharges on surficial aquifers Atlantic and DTI will implement measures outlined in the Plan and Procedures during construction dem�atering activities. Karst features that have an opening into the subsurface bedrock have the potential to provide a conduit for impacts to groundwater. 7 Atlantic and DTI conducted a detailed desktop assessment and field survey along those portions of the Projects considered prone to the development of karst to identify sinkholes and other karst features. As warranted, Atlantic and DTI will make minor route adjustments to avoid areas containing dense concentrations of features, such as sinkholes, which are indicative of karst development. Atlantic and DTI have prepared and will implement a Karst Monitoring and Mitigation Plan (see Appendix 1 F of Resource Report 1), which identifies construction and restoration practices in karst areas. During construction, erosion and sediment controls will be installed along the edge of the construction right-of-way and in other work areas upslope of known sinkholes or other karst features with a direct connection to the phreatic zone of the karst (i.e., groundwater). In addition, refueling, hazardous materials storage, and overnight equipment parking within 300 feet of karst features with direct connection to the phreatic zone will be prohibited. Results of the desktop assessment and field surveys as well as proposed construction and mitigation measures for karst areas are discussed in more detail in Resource Report 6. 7 During the ACP and SHP Open Houses, and in comments filed with the FERC, several individuals commented about karst features and the potential to impact groundwater resources. 2-18 Resource Report 2 Water Use and Quality Potential project -related groundwater contamination sources may also include accidental spills and leaks of hazardous materials associated with construction; refueling or maintenance of vehicles; and storage of fuel, oil, and other fluids. Spills or leaks from equipment used during construction pose the greatest risk to groundwater resources. If not cleaned up, soils contaminated by spilled materials could leach and add pollutants to groundwater. To avoid or minimize the potential impact of hazardous material spills during construction and operation of the ACP and SHP, Atlantic and DTI have prepared and will implement a SPCC Plan. The SPCC Plan will specify preventive measures such as regular inspection of storage areas for leaks, replacement of deteriorating containers, and construction of containment systems around hazardous liquids storage facilities. The SPCC Plan will restrict refueling or other liquid transfer areas within 100 feet of wetlands, waterbodies, and springs, and within 300 feet of karst features with a direct connection to the phreatic zone; prohibit refueling within 200 feet of private water supply wells and within 400 feet of municipal water supply wells; and require additional precautions (e.g., secondary containment) when specified setbacks cannot be maintained. In addition, Atlantic and DTI will evaluate recommended measures provided by local agencies where wellhead protection or groundwater protection areas are crossed. The SPCC Plan also will identify emergency response procedures, equipment, and cleanup measures to be implemented in the event of a spill, and require the construction contractor to complete an inventory of construction fuels, lubricants, and other hazardous materials that may be used or stored in designated areas, as well as the amount and type of containers that will be used to store these materials. It is possible that previously undocumented sites with contaminated soils or groundwater could be discovered during construction of the Projects. Atlantic and DTI have prepared and will implement a Contaminated Media Plan to address these circumstances (see Appendix IF of Resource Report 1). The Contaminated Media Plan describes measures to be implemented in the event that signs of contaminated soil and/or groundwater are encountered during construction. Signs of potential contamination could include discoloration of soil, chemical -like odors, or sheens on soils or water. Containment measures will be implemented to isolate and contain suspected soil or groundwater contamination, and collect and test samples of the soil or groundwater to identify the contaminants. Once the contaminants are identified, a response plan will be developed for crossing or avoiding the site. Blasting may be necessary along portions of the proposed ACP and SHP facilities where bedrock is located at or near the ground surface (see Section 6.2 of Resource Report 6). Atlantic and DTI have prepared and will implement a Blasting Plan which identifies procedures for the use, storage, and transportation of explosives consistent with safety requirements as defined by Federal, State/Commonwealth, and local agency regulations. The Blasting Plan is provided in Appendix IF of Resource Report 1. Where blasting is necessary, it will be conducted in a manner to minimize possible impacts on nearby public and private water supply wells, springs, or karst features with a direct connection to the phreatic zone. 2-19 Resource Report 2 Water Use and Quality Without proper planning, blasting could affect groundwater quality and 8 bedrock -based water well systems located in close proximity to the construction right-of-way. The use of controlled blasting techniques, where small, localized detonations are utilized, will avoid or minimize the impacts of blasting and limit rock fracture to the immediate vicinity of these activities. As noted in Sections 2.1.3.2 and 2.1.4, Atlantic and DTI will contact landowners to determine the location of private water wells and private water supply springs within 150 feet of approved construction workspaces. Atlantic and DTI will, with landowner permission, conduct preconstruction and post -construction well testing, and perform necessary repair or restoration to maintain well productivity and water quality, for wells located within 150 feet of the construction area. Atlantic plans to monitor groundwater quality and yield for public and private supply wells and springs proximate to the Project area, as described in more detail below. Groundwater inventory and sample collection will be conducted before and after construction to determine whether water supplies have been affected by pipeline construction activities. Atlantic and DTI will establish baseline groundwater conditions prior to construction of the Projects through investigative field surveys and a sampling protocol. The surveys will include a groundwater inventory of all wells or springs within 500 feet of the proposed pipelines in karst areas and within 150 feet of the construction workspace along the remainder of the proposed pipelines. In order to conduct these inventories, land owner permission will need to be obtained first. With landowner permission, water samples will be obtained prior to construction to establish water quality and yield baselines during the varying seasons. These samples will be tested for pH, total suspended solids, total dissolved solids, conductivity, alkalinity, acidity, sulfates, oil/grease, phenolic, iron, manganese, aluminum, fecal coliform, copper, lead, nickel, silver, thallium, zinc, chromium, arsenic, mercury, selenium, cyanide, calcium magnesium, hardness, chlorides, antimony, cadmium, and beryllium. Sampling methods will adhere to the prevailing EPA and State/Commonwealth sampling, analytical and data quality assurance and quality control procedures. The samples will be analyzed using EPA -approved methods and the analysis will be performed by a certified laboratory in each State/Commonwealth. Any well damage claim will be investigated for cause; during this investigation a temporary potable water source will be supplied to the well owner. This temporary potable water source will be supplied by a potable water storage device and/or a temporary water treatment system to restore potable water. In the event the damage claim investigation yields positive results that construction activities caused or contributed to well damage. Atlantic or DTI will provide a permanent potable water source. This will be supplied by a permanent water treatment system and/or a new well drilled to a deeper aquifer. To respond to mitigation requested by the ACSA regarding potential blasting near the Augusta Regional Landfill, Atlantic has incorporated a route adjustment that increases the 8 In comments filed with the FERC, several individuals commented about blasting during construction and potential impacts on water sources and water quality. 2-20 Resource Report 2 Water Use and Quality distance between the AP -1 mainline and the landfill.9 The purpose of this adjustment was an added precaution to mitigate potential impacts of blasting near the landfill's monitoring wells. Atlantic will also develop a site-specific blasting and monitoring plan for this area in consultation with the ACSA. Atlantic and DTI are evaluating the need to use groundwater for the aboveground facilities. Groundwater may be used for hydrostatic testing of facility piping, dust control, operation and maintenance activities, and domestic uses. 2.1.7 Facility Operations The Projects will transport pipeline quality natural gas that has been processed to remove natural gas liquids (NGL) prior to being received by the ACP and SHP. However, a small amount of residual NGLs may still exist in the gas transported by ACP and SHP. Several important considerations are incorporated into the design and operation of the Projects with regard to NGLs. These design elements will minimize the risk of release of residual NGLs that may accumulate in the pipeline as a result of normal natural gas pipeline operations. 49 CFR Parts 192.475, 192.476., 192.477, and 192.491 address operations of natural gas pipelines. Gas pressure and receipts along the pipelines will be monitored continuously to ensure gas quality parameters are met at the receipt points. In addition, construction design and operations procedures for the Projects will limit the potential for NGLs to occur in the pipelines. Filter separators will be installed at the receipt points and at the compressor stations. These filter separators will remove those trace amounts of liquids that may be in the gas stream. Additionally, pigging of the pipeline will be conducted to remove fluids from the pipeline in a controlled manner. When the ACP and SHP are pigged, the NGLs will be collected in vessels that are enclosed within secondary containment equipped with alarm systems to notify the operators if levels change. The fluids in the tanks will hauled to approved -disposal facilities. Additionally, SPCC Plans which outline the training, procedures, processes and equipment to be utilized by Atlantic and DTI and/or contractors pertaining to spill response during operations will be established for the facilities. In the event of an inadvertent NGL release, Atlantic and DTI will have spill kits staged at work locations where trained employees and contractors are able to ensure compliance and that safety requirements are met during the spill cleanup process. The new pipelines and aboveground facilities are not expected to result in impacts on groundwater use or quality under typical operating conditions. Impacts could occur if maintenance activities require excavation or repair in proximity to water supply wells or springs. In such a case, the impacts and mitigation would be similar to those described above for construction activities. 9 In comments filed with the FERC the ACSA commen ed that blasting near the Augusta Regional Landfill could damage monitoxing wells. 2-21 Resource Report 2 Water Use and Quality 2.2 SURFACE WATER RESOURCES 2.2.1 Existing Watersheds The USGS has organized watersheds of the United States into seven successively smaller levels of subdivisions using hydrologic unit codes (HUC). Regions (level one) are the largest watersheds (two -digit HUCs), followed by sub -regions (four -digit HUCs), basins (six -digit HUCs), and sub -basins (eight -digit HUCs), which are further divided into smaller watersheds. Information on the basins and watersheds crossed by the proposed ACP and SHP facilities is described below and summarized in Table 2.2.1-1. The proposed ACP facilities will cross three regional watersheds (the Ohio, Mid -Atlantic, and South Atlantic -Gulf) and eight sub -regions (Monongahela, Kanawha, Lower Chesapeake, Potomac, Chowan -Roanoke, Neuse-Painlico, Cape Fear, and Pee Dee). The sub -regions are further broken into 10 basins and 26 sub -basins. The Ohio Regional Watershed covers approximately 161,250 square miles encompassing portions of nine States, including Illinois, Indiana, Kentucky, Maryland, New York, North Carolina, Ohio, Tennessee, West Virginia and the Commonwealths of Pennsylvania and Virginia (USGS, 1994). Major rivers within this regional watershed include the Ohio, Wabash, Allegheny, Monongahela, Kanawha, and New Rivers. The Mid -Atlantic Regional Watershed covers approximately 95,360 square miles encompassing all or portions of eight States, including Connecticut, Delaware, Maryland, Massachusetts, New Jersey, New York, Vermont, West Virginia, and the Commonwealths of Pennsylvania and Virginia (USGS, 1994). Major rivers in the southern portion of this regional watershed include the Potomac, James, and Shenandoah Rivers, as well as the beginning of the Ohio River at the confluence of the Allegheny and Monongahela Rivers. The Mid -Atlantic Regional Watershed also contains the nation's largest estuary, Chesapeake Bay. The South Atlantic -Gulf Regional Watershed covers approximately 278,680 square miles encompassing all or portions of eight States including Alabama, Florida, Georgia, Louisiana, Mississippi, North Carolina, South Carolina, Tennessee, and the Commonwealth of Virginia (USGS, 1994). Major rivers in this regional watershed include the Roanoke, Cape Fear, Savannah, Ogeechee, and Chattahoochee Rivers. This South Atlantic -Gulf Regional Watershed also includes the Outer Banks of North Carolina and Florida Everglades. The proposed SHP facilities are located within the Ohio Regional Watershed and portions of two sub -regions, Upper Ohio and Monongahela. The sub -regions are further broken into two basins and three sub -basins. 2.2.2 Waterbodies Crossed Waterbodies are defined by the FERC as "any natural or artificial stream, river, or drainage with perceptible flow at the time of crossing, and other permanent waterbodies such as lakes and ponds." The flow regime for waterbodies may be characterized as perennial, intermittent, or ephemeral. Perennial waterbodies contain water for all or most of the year and have flow. Intermittent waterbodies flow seasonally or following rainfall events. Ephemeral waterbodies flow during or shortly after precipitation events or Spring snowmelt. 2-22 Resource Report 2 Water Use and Quality As used in this Resource Report, the tenn "waterbodies" follows the FERC definition noted above. Through the Clean Water Act permitting process, Atlantic and DTI will determine with the U.S. Army Corps of Engineers (USACE), EPA, and State/Commonwealth agencies whether given features are jurisdictional "waters of the U.S." The tenn "waterbodies," as used here, is best understood as those water features — excluding wetlands — that are potentially subject to jurisdiction under the Clean Water Act. TABLE2.2.1-1 Watersheds Crossed by the Atlantic Coast Pipeline and Supply Header Project Pipeline Segment/Regional Watershed/ Sub -Region Approximate MilepoStS b County/City and State/Commonwealth ATLANTIC COAST PIPELINE AP -1 Ohio Regional Watershed Monongahela 0.0-69.7 Harrison, Lewis, Upshur, and Randolph Counties, Wv Kanawha 697-83 1 Pocahontas County, WV Mid -Atlantic Regional Watershed Potomac 83.1 — 85 9; 118.1 — 158.2 Highland and Augusta Counties, VA Lower Chesapeake 85.9-118.1; 158.2-247.3 Highland, Augusta, Nelson, Buckingham, Cumberland, Prince Edward and Nottoway Counties, VA Atlantic -Gulf Regional Watershed Chowan -Roanoke AP -2 Atlantic -Gulf Regional Watershed Chowan -Roanoke Neuse-Panihco Cape Fear Pee Dee AP -3 Atlantic -Gulf Regional Watershed Chowan -Roanoke 247.3 — 300.1 Nottoway, Dmwiddie, Brunswick, and Greensville Counties, VA, and Northampton County, NC 0.0-18.0 Northampton and Halifax Counties, NC 18.0-115.3 Halifax, Nash, Wilson, Johnston, and Sampson Counties, NC 115.3 — 159.3 Sampson and Cumberland Counties, NC 159.3 — 183.0 Cumberland and Robeson Counties, NC 0 0 — 52 0, and 68.0 — 68 4 Northampton County, NC, Southampton County, VA and City of Suffolk and City of Chesapeake, VA Mid -Atlantic Regional Watershed Lower Chesapeake 52.0 — 68.0, and 68.4 — 79.3 City of Suffolk and City of Chesapeake, VA AP -4 Atlantic -Gulf Regional Watershed Chowan -Roanoke AP -5 Atlantic -Gulf Regional Watershed Chowan -Roanoke SUPPLY HEADER PROJECT TL -635 Ohio Regional Watershed Monongahela Upper Ohio TL -636 Ohio Regional Watershed Monongahela Source- USGS, 1994 0.0-0.6 Brunswick County, VA 0.0-1 1 Greensville County, VA 0.0-0.7 Harrison County, WV 0.7-33.6 Wetzel, Tyler, and Doddridge Counties, WV 00-39 Westmoreland County, PA 2-23 Resource Report 2 Water Use and Quality The FERC categorizes surface waters as major, intermediate, or minor waterbodies based on the width of the water's edge at the time of crossing. Major waterbodies are greater than 100 feet wide, intermediate waterbodies are between 10 feet and 100 feet wide, and minor waterbodies are 10 feet wide or less. Atlantic and DTI are completing waterbody surveys to document waterbody crossings along the proposed pipeline routes and in other work areas. Table 2A- I and Table 2A-2 in Appendix 2A provide a list of the waterbodies crossed by the proposed ACP and SHP facilities, respectively. For each waterbody crossing, the tables include the field survey designation (Feature ID), waterbody name, approximate crossing width, flow regime (perennial, intennittent, ephemeral, or canal/ditch), proposed crossing method, and State/Commonwealth water classification, and indicates if there is a time of year restriction at the crossing. Waterbodies that were not surveyed in the field due to a lack of survey permission or recent changes to the proposed pipeline routes were identified based on the National Hydrography Dataset (NHD) (USGS, 2015) and/or recent aerial photography. These features are designated as "NHD" in the Feature ID column of each table. Table 2.2.2-1 below provides a summary of the waterbodies crossed by the Projects. Waterbody and wetland delineation reports for the ACP and SHP are provided in Appendices 2D and 2E, respectively. Information on the major waterbodies crossed by the Projects is provided in Table 2.2.2- 2. Site-specific drawings for each of the major waterbodies crossed are provided in Appendix 2F. Information for intermediate and minor waterbody crossings is provided in Appendices 2A - I and 2A-2. Table 2.2.2-3 summarizes the waterbodies crossed by the ACP on Federal lands. Table 2A-3 and Table 2A-4 in Appendix 2A provide a listing of the proposed stream crossings location on U.S. Forest Service (USFS) lands in the MNF and GWNF. 2-24 TABLE 2.2.2-1 waterbodies Affected by the Atlantic Coast Pipeline and Supply Header Project Waterbody Type FERC Classification Open Canal/ Open Water Water Project/Facility Perennial Intermittent Ephemeral Ditch Ponds Major Intermediate Minor Ponds ATLANTIC COAST PIPELINE Pipeline Facilities 448 434 128 45 22 14 316 725 22 Aboveground 1 0 0 0 0 0 1 0 0 Facilities Access Roads 74 106 23 3 5 0 52 154 5 Pipe Storage and 3 2 0 0 0 0 2 3 0 Contractor Yards Project Total 526 542 151 48 27 14 371 882 27 SUPPLY HEADER PROJECT Pipeline Facilities 57 8 0 0 1 0 33 32 1 Aboveground 6 1 0 0 1 0 2 5 1 Facilities Access Roads 56 15 0 0 0 0 30 41 0 Pipe Storage and 0 0 0 0 0 0 0 0 0 Contractor Yards Project Total 119 24 0 0 2 0 65 78 2 2-24 Resource Report 2 Water Use and Quality TABLE 2 2 2-2 Major waterbodies Crossed by the Atlantic Coast Pipeline and Supply Header Project Pipeline Segment/County or Approximate City/State or Commonwealth Waterbody Name Milepost Flow Type' Crossing Width (feet) Crossing Method AP -1 Federal Land Unit Crossed (miles) Perennial Intermittent Ephemeral Ditch Randolph County, WV Shavers Fork 67.9 Perennial 103 Cofferdam Nelson and Buckingham James River 1847 Perennial 387 HDD Counties, VA Blue Ridge Parkway 0.1 0 0 0 0 Cumberland and Prince Edward Appomattox River 220.8 Perennial 104 Coffffdam Counties, VA Greensville County, VA Meherrin River 2863 Perennial 182 Open Cut AP -2 Northampton and Halifax Roanoke River 9.8 Perennial 360 HDD Counties, NC Halifax and Nash Counties, NC Fishing Creek 33.9 Perennial 105 Dam and Pump/Flume Nash County, NC Swift Creek 406 Perennial 127 Dam and Pump/Flume Nash County, NC Tar River 59.4 Perennial 165 Open Cut Johnston County, NC Neuse River 984 Perennial 137 Open Cut Cumberland County, NC Cape Fear River 149.3 Perennial 325 HDD AP -3 Greensville and Southampton Meherrin River 12.4 Perennial 116 Cofferdam County, VA Southampton, VA Nottoway River 32.6 Perennial 240 HDD Southampton County and City of BIackwater River 386 Perennial 205 HDD Suffolk, VA City of Chesapeake, VA South Elizabeth River 78.4 Perennial 851 HDD No major waterbodies are crossed by the Supply Header Project in Pennsylvania or West Virginia. TABLE 2.2.2-3 waterbodies Crossed by the Atlantic Coast Pipeline on Federal Lands Waterbody Type Federal Land Canal/ Open Water Federal Land Unit Crossed (miles) Perennial Intermittent Ephemeral Ditch Ponds Monongahela National Forest 18.6 48 52 22 0 2 George Washington National Forest 12.2 16 10 4 0 0 Blue Ridge Parkway 0.1 0 0 0 0 0 Great Dismal Swamp National Wildlife Refuge 17 1 0 0 3 0 2.2.3 Surface Water Standards and Classifications Each of the States/Commonwealths crossed by the proposed ACP and SHP facilities has developed its own regulatory system for evaluating, classifying, and monitoring the quality and uses of surface waters. Each system includes the assignment of "beneficial use designations" that describe the potential or realized capacity of a waterbody to provide defined ecological and human population benefits. A summary of the use designation system for each State/Commonwealth is provided below. The designations for the waterbodies crossed by the proposed ACP and SHP facilities, respectively, are listed in Tables 2A-1 and 2A-2 in Appendix 2A. 2-25 Resource Report 2 Water Use and Quality 2.2.3.1 West Virginia Surface Water Classifications West Virginia Code of State Regulations (CSR) §47-2-4 (West Virginia Code of State Regulations [VvrVCSR], 2014) outlines an antidegradation policy that establishes three classes for waters of the State. The classes are assigned to waters in an effort to maintain quality or existing uses (WVDEP, 2014a). The three tiers of protection are defined as follows (WVCSR, 2014): Tier 1 Protection: existing water uses and the level of water quality necessary to protect the existing uses shall be maintained and protected. Existing uses are those uses actually attained'in a water on or after November 28, 1975, whether or not they are included as designated uses within the State code, water quality standards. Tier 2 Protection: existing high quality waters of the State must be maintained at their existing high quality. High quality waters are defined in the State code as those waters whose quality is equal or better than the minimum levels necessary to achieve the national water quality goal uses. Tier 3 Protection: outstanding national resource waters that have been placed on the highest tier of the State classification to provide greater protection. These include waters that are in federally designated Wilderness Areas and waters with naturally reproducing trout in State parks, national parks, and national forests. West Virginia CSR §47-2-6 further outlines general Water Use Categories and Water Quality Standards for waters of the State. Under the CSR, waters of the State are designated for Propagation and Maintenance of Fish and Other Aquatic Life (Category B) and Water Contact Recreation (Category C) unless otherwise designated. Other use designations assigned under the CSR include: Public Water (Category A), Warm Water Fishery (Category B 1), Trout Waters (Category 132), Wetlands (Category B4), Water Contact Recreation (Category C), Agricultural and Wildlife Uses (Category D), Irrigation (Category Dl), Livestock (Category D2), Wildlife (Category D3), Water Supply Industrial, Water Transport, Cooling and Power (Category E), Water Transport (Category El), Cooling Water (Category E2), Power Production (Category E3), and Industrial (Category E4) (West Virginia CSR, 2014). The proposed ACP facilities will cross ten Tier 3 streams in West Virginia (Tygart Valley River, MP 56.5; Becky Creek at two locations, MP 60.3 and MP 60.6; Shavers Fork, MP 67.9; Unnamed Tributary to West Fork Greenbrier River, MP 70.5; West Fork Greenbrier River, MP 71.4; Mountain Lick Creek, MP 72.2; John's Run, MP 74.8; East Fork Greenbrier River, MP 77.1; and Little River, MP 79.2).10 Construction and operation of the ACP will meet applicable requirements for Tier 3 outstanding national resource waters. The SHP will not cross Tier 3 streams in West Virginia. According to WVDEP staff Tier 1 and Tier 2 streams are determined on a case by case basis during permitting and determinations may vary based on the water quality parameters (Peterson, 2015). For example, a stream could be designated as a Tier 1 for one parameter and a Tier 2 for a different parameter. Therefore, streams are not able to be categorized as Tier I or Tier 2 at this time. 10 In comments filed with the FERC the US Forest Service indicated additional Tier 3 streams are present within National Forest Boundaries based on presence of naturally reproducing trout. Based on additional research Atlantic has included three additional waterbodies. 2-26 Resource Report 2 Water Use and Quality 1—) 2.2.3.2 Virginia Surface Water Classifications LI) Title 9 of VAC Agency 25, Chapter 260, Section 30 (9VAC25-260-30) outlines an antidegradation policy that establishes three classes for waters of the Commonwealth of Virginia (VLIS, 2014b). The three classes are defined as follows: Tier 1: waters where existing water quality and uses need to be maintained. Tier 2: waters that are exceeding water quality standards. Tier 3: exceptional waters where no new discharges of pollution are allowed; these waters are required to be listed in the VAC. The proposed ACP facilities do not cross Tier 3 streams in Virginia (see Appendix 2A). According to VDEQ staff, Tier I and Tier 2 streams are determined on a case by case basis during permitting (Barron, 2015). Therefore, streams are not able to be categorized as Tier 1 or Tier 2 at this time. Under 9VAC25-260-1 0, Commonwealth of Virginia waters, including wetlands, are designated for recreational uses; propagation and growth of a balanced, indigenous population of aquatic life; wildlife; and the production of edible and marketable natural resources. Subcategories have been established for the propagation and growth of a balanced indigenous population of aquatic life in Chesapeake Bay and its tidal tributaries. Other subcategories have not been defined in the VAC (VLIS, 2014c). 2.2.3.3 North Carolina Surface Water Classifications Title 15A of North Carolina Administrative Code (NCAC), Chapter 2, Subchapter 02B outlines State surface water and wetland standards (15ANCAC 02B.0101). Withinthis subchapter, classifications for surface waters are defined as follows: Class C: freshwater protected for secondary recreation, fishing, and aquatic life; this category includes all freshwater in the State to protect these uses. Class B: freshwater protected for primary recreation, including swimming and all Class C uses. Classes WS -1, WS -II, WS -III, WS -IV, and WS -V: waters that are protected as water supplies within watersheds of increasing development, ranging from natural, undeveloped, and upstream watersheds to moderate or highly developed watersheds. Class VVL: waters that meet the definition of wetlands, except coastal wetlands. Classes SC, SB, SA, and SWL: waters including various categories of tidal salt - waters. In addition to these classifications, the NCAC defines a number of supplemental classes for State waters. These include designations for Trout Waters (Tr), Swamp Waters (Sw), Nutrient Sensitive Waters (NSW), Outstanding Resource Waters (ORW), High Quality Waters (HQ), Future Water Supply, and Unique Wetland. The NCAC (I 5A NCAC 02B.0201 Antidegradation) under subsection 2B, Rule.0201, establishes an antidegradation policy for North Carolina. This policy requires the establishment 2-27 Resource Report 2 Water Use and Quality of classes protecting existing uses of State waters. It additionally states that projects affecting waters shall not be permitted unless existing uses can be protected (NCAC, 1996). In North Carolina surface waters are assigned a minimum Class C designation. In addition, the proposed ACP pipeline facilities will cross three Class WS -III, 17 Class WS -IV, three Class WS -V, 29 Class Sw, and 46 Class NSW waterbodies (see Appendix 2A). 2.2.3.4 Pennsylvania Surface Water Classifications Provisions of water quality standards in Pennsylvania are provided under Title 25, Subpart C, Article II, Chapter 93 of the Pennsylvania Code (Pennsylvania Code, 1971). The general provisions for protected water uses in Chapter 93.3 identifies several categories of water uses to be protected, including cold water fisheries (C)AT), warm water fisheries (WWF), migratory fishes, trout stocking, potable water supply (PWS), industrial water supply (IWS), livestock water supply (LWS), wildlife water supply (AWS), irrigation (IRS), boating (B), fishing (F), water contact sport (WC), esthetics (E), high quality waters (HQ), exceptional value waters (EV), and navigation. Pennsylvania Code chapter 93.4 outlines uses for waters of the Commonwealth. Under this chapter, the following uses apply to surface waters unless otherwise specified in law or regulation: WWF, PWS, IWS, LWS, AWS, IRS, B, F, WC, and E. These uses must be protected in accordance with Chapter 96 of the Pennsylvania Code with regard to water quality standards and other applicable Commonwealth or Federal laws and regulations. Pennsylvania Code Chapter 93.4a outlines an antidegradation policy for surface waters of the Commonwealth. The policy states that existing in -stream water uses and the level of water quality necessary to protect existing uses shall be maintained and protected. The policy additionally states that the water quality of HQ and EV streams and lakes shall be maintained and protected, except as provided in § 93.4c(b)(1)(iii). HQ waters are defined as surface waters that have long-term water quality to support the propagation of fish, shellfish, and wildlife as well as recreation; that support high quality aquatic communities; and/or that meet Class A wild trout stream qualifications. Surface waters that qualify as EV must meet the requirements of HQ surface waters as well as one or more of the following: the water is located within a national wildlife refuge, national natural landmark, Federal wild river, Federal wilderness area, national recreation area, or areas designated by the Commonwealth as game propagation and protection areas, park natural areas, forest natural areas, or wild rivers; the water is an outstanding national, Commonwealth, regional or local resource water; the water is a surface water of exceptional recreational significance; the water achieves a score of at least 92 percent using the methods and procedures described in subsection (a)(2)(i)(A) or (B); or the water is designated as a 'wilderness trout stream' by the Pennsylvania Fish and Boat Commission. 2-28 Resource Report 2 Water Use and Quality In Pennsylvania, the SHP facilities will cross 12 streams with CVVT and HQ designations, and two streams with trout stocking designations (see Appendix 2A; PADEP, 2013). Construction and operation of the SHP will meet applicable requirements for HQ waters. None of the waterbodies within the SHP Project area are classified as EV. - 2.2.4 Contaminated Waters or Sediments The EPA's List of Sediment Sites with Substantial Contamination identifies Superfarid sites where remediation includes the dredging or excavation of more than 10,000 cubic yards of contaminated sediment. According to the EPA, these sites contain sediments associated with waterbodies that present an unacceptable risk to human health and/or the environment (EPA, 2013b). Based on a review of the EPA list, no such sites are located in Pennsylvania, West Virginia, or North Carolina (EPA, 2012a). One such site is listed in the City of Roanoke, Virginia, but it is located greater the 50 miles from the proposed ACP facilities. Atlantic and DTI reviewed the list of 303(d) hnpaired Waters for each State/Commonwealth to identify crossings of waterbodies that may contain contaminated sediments (WVDEP, 2012a, 2012b; VDEQ, 2015; NC OneMap, 2015a; PADEP, 2015c). Waterbodies crossed by the proposed ACP or SHP facilities that are included on the EPA approved 303(d) impaired waters list are identified in Table 2B in Appendix 2B. There are 16 3 03 (d) impaired streams crossed by the ACP in West Virginia, 20 in Virginia, and one in North Carolina. There are nine 303(d) impaired streams crossed by the SHP pipeline facilities in West Virginia and nine in Pennsylvania. Atlantic and DTI are evaluating the contaminants listed within these waterbodies for the probability to encounter contaminated water or sediments during construction, or to exacerbate impairments during construction. In the event that contaminants are encountered during construction of the Projects, Atlantic and DTI will implement the measures identified in the Contaminated Media Plan (see Appendix IF of Resource Report 1). 2.2.5 Public Surface Water Intakes and Surface Water Protection Areas Atlantic and DTI are consulting with the WVDHHR, VDH-ODW, NCDENR-DWR, and PADEP in an effort to identify public surface water intakes within 3.0 miles and surface water protection areas within 250 feet of the proposed ACP and SHP facilities. Similar to the public supply wells discussed in Section 2.1.3 above, surface water intake data are not publicly available from the WVDHHR. At Atlantic's and DTI's request, however, the WVDHHR (2015a) reviewed maps of the Projects and determined that there are four surface water intakes within 3.0 miles of the ACP and there is one surface water intake within 3.0 miles of the SHP. The WVDHHR also determined that there are four surface water protection areas within 250 feet of the ACP and none within 250 feet of the SHP (WVDHHR, 2015a). During a supplemental review, the VTVDHHR (2015b) determined that the Projects do not intersect any drinking water sources; however, the Projects intersect multiple protection areas and zones associated with six public water systems. The WVDHHR (2015b) provided a shapefile for a three mile buffers around protection areas and zones associated with the ACP and SHP. Atlantic and DTI reviewed Source Water Assessment Reports, prepared by the VYVDHHR Office of Environmental Health Services Source Water Protection Unit, for each of the surface water intake facilities outlined in the WVDHHR (2015a) correspondence letter 2-29 Resource Report 2 Water Use and Quality (VVVDHHR, 2003a -e). The Source Water Assessment Reports identify the Source Water Protection Watershed for each intake, which includes the entire watershed area upstream of the intake structure. The reports and shapefile provided by the VV'VDHHR (2015b) also identify Zones of Critical Concern (ZCC), which are considered surface water protection areas in corridors along waterbodies within Source Water Protection Watersheds. The ZCC is based on a protection zone of five hours above the water intake. The Zones of Peripheral Concern (ZPC) were provided in a shapefile from the WVDHHR (2015b) and are considered surface water protection areas in corridors along waterbodies Source Water Protection Watersheds. The ZPC is based on a protection zone of ten hours above the water intake. The ZCCs and ZPCs warrant a more detailed inventory and management due to their proximity to the source water and the susceptibility to potential contaminants. ZCCs, Wellhead Protection Areas, and Zones of Peripheral Concern within three miles of the Projects were included in the shapefile provided by the WVDHHR (WVDHHR, 2015b). Table 2.2.5-1 lists the surface water intake facilities within 3.0 miles of the Projects. The VDH-ODW provided Atlantic with location data for public surface water intakes (Soto, 2015). Based on a review of these data, Atlantic identified four public surface water intakes located within 3.0 miles downstream of the proposed ACP facilities (see Table 2.2.5-1). The ACP will cross the Zone 1 assessment watershed associated with each of the four surface water intakes. The VDH-ODW identifies Zone I assessment watersheds as the area within a 5 mile radius of the raw water intake. Two additional Zone 1 assessment watersheds for a surface water intake are crossed by both the AP- I mainline and AP -5 lateral, and the AP- 1 mainline, but the ACP is further than 3.0 miles upstream from the intakes. The ACP also crosses a shoreline protection buffer of approximately 30 feet around Lake Kilby, a source waterbody owned and managed by the City of Portsmouth (Umphlette, 2015). The NCDENR-DWR provided Atlantic with digital data on the locations of public surface water intakes in North Carolina. Based on a review of this data, Atlantic determined that there are no public surface water intakes within 3.0 miles downstream of waterbody crossings along the proposed ACP pipelines and other facilities in North Carolina. The nearest public surface water intake is approximately 3.5 miles from the Project. In addition to maintaining data pertaining to surface water intakes, the NCDENR-DWR has established public water source watersheds for areas that drain to public surface water intakes. Atlantic evaluated these data and determined that seven of these watersheds are crossed by the proposed ACP facilities (see Table 2.2.5-2). Similar data are not available for West Virginia, Virginia, or Pennsylvania. Based on a review of geographic information system (GIS) data available from the Pennsylvania Spatial Data Access website and the PADEP's eMapPA, there are no public surface water intakes within 3.0 miles of the SHP (PADEP, 2015a and 2015b). However, the SHP facilities are located within two public water systems service areas. Public water systems service areas are defined as a system that provides water to the public for human consumption, which has at least 15 service connections or regularly serves an average of at least 25 individuals daily at least 60 days out of the year (PADEP, 2015a). The TL -636 loop and the JB Tonkin Compressor Station are located within the Westmoreland County Municipal Authority public water systems service area. The Crayne Compressor Station is located within the Southwestern Pennsylvania Municipal Authority public water systems service area. 2-30 Resource Report 2 Water Use and Quality TABLE 2 2.5-1 Surface Water Intake Facilities Within 3.0 Miles Downstream of and Water Protection or Assessment Watersheds Crossed by the Atlantic Coast Pipeline and Supply Header Project Length of Source Waterbody Milepost of Length of Zones of Water Protection or Associated with Project Critical Concem/Length Assessment Pipeline Segment/ County or Surface Water Public Water Crossing of of Zone of Peripheral Watershed Crossed City/State or Commonwealth Intake Facility Intake Waterbody' Concern Crossed (miles) (miles) ATLANTIC COAST PIPELINE AP -1 Upshur County, WV Quality hin TBD 26.4 0.0/0.2 N/A Upshur County, V*rV Buckhannon Buckhannon River 28.3 41/46 124 Water Board Upshur County, WV Grand Badger Buckhannon River 339 2.2/22 6.1 Community Hawthorne Randolph County, WV Mill Creek Water Mill Creek 53.4 0.8/0.8 2.0 Department Randolph County, WV Town of Beverly TBD 53.5 0.0/2.5 N/A Randolph County, WV Huttonsville Tygart River 55.2 2.8/3.8 64 Medium Security Valley Prison Augusta County, VA City of Staunton Middle River 1292 N/A 6.7 Greensville County, VA City of Emporia Mehenin River 2863 b N/A 3 2 Nelson County, VA NCSA — Schuyler Johnson's Branch 175 2 N/A 18 8 AP -2 None Identified AP -3 City of Suffolk, VA Lake Kilby- Lake Kilby and 569 N/A 5.6 Pitchkettle Creek City of Suffolk, VA Lake Meade' Lake Kilby and 56.9 N/A 55 Pitchkettle Creek City of Suffolk, VA Pitchkettle Raw Lake Kilby and 56.9 N/A 4.3 Watet' Pitchkettle Creek AP -4 None Identified AP -5 Greensville County, VA City of Emporia Mehenin River N/Ad N/A 0.2 SUPPLY HEADER PROJECT TL -635 Wetzel County, WV Pine Grove Water North Fork N/A N/A N/A Fishing Creek TL -636 None Identified Sources: V*rVDHHR, 2015a, 2015b, 2003 a -e; Soto, 2015; NCDENR, 2014a, a Milepost of project crossing of waterbody or if associated with a Zone of Critical Concern or Zone of Peripheral Concern it is the imlepost where the Project first enters the zone. b Pipeline crossing is not within 3.0 miles upstream of the public surface water intake. C The three water intake facilities within the City of Suffolk, Virginia, are operated by the City of Portsmouth. d AP -5 crosses within the Assessment Watershed, but does not cross the Mehenin River N/A Zones of Critical Concern are identified in West Virginia and do not apply in Virginia. 2-31 Resource Report 2 Water Use and Quality TABLE 2 2 5-2 Water Source Watersheds Crossed by the Atlantic Coast Pipeline in North Carolina Water Supply Classifications in North Carolina (NCDENR-DWR, 2014): WS -III = Waters used as sources of water supply for drinking, culinary, or food processing purposes; generally in low to moderately developed watersheds. WS -IV = Waters used as sources of water supply for drinking, culinary, or food processing purposes; generally in moderately to highly developed watersheds NSW — Nutrient Sensitive Waters, supplemental classification where additional nutrient management is needed due to potential for excessive growth of microscopic or macroscopic vegetation. 2.2.6 Horizontal Directional Drill Mud Water Use Atlantic and DTI are proposing to cross six waterbodies, one water impoundment, and two road rights-of-way using the HDD method. In addition, the HDD method is proposed to cross beneath both the Blue Ridge Parkway and the Appalachian National Scenic Trail at the same time. A detailed description of the HDD method is provided in Section 1.5.2.1 of Resource Report 1. Geotechnical studies will be conducted at each of the planned HDD crossings. To the extent possible, these studies will identify subsurface conditions along the proposed drill paths and at the entry and exit sides of each of the respective crossings. Throughout the drilling process, a fluid mixture consisting of water and bentonite clay (a naturally occurring mineral) will be pumped into the drill hole to lubricate the bit, transport cuttings to the surface, and maintain the integrity of the hole. Small pits will be dug at or near the entry and exit points for the HDD to temporarily store the drilling fluid and cuttings, which will consist of a non-toxic slurry of water, bentonite, and native ground substrate (rock and soil). The fluid and cuttings will be pumped from the pits to an on-site recycling unit where the fluid will be processed for reuse. After completion of the HDD operations, the recovered drilling mud will be recycled or disposed of at an approved upland location or disposal facility in accordance with Federal and State/Commonwealth regulations. The estimated water requirements and withdrawal location for each of the proposed HDDs are summarized in Table 2.2.6-1. Withdrawals will be conducted in accordance with State/Commonwealth regulations and permit requirements. 2.2.7 Hydrostatic Test Water and Fugitive Dust Control Water After backfilling and other construction activities that could affect the proposed ACP and SHP pipelines are complete, each pipeline will be hydrostatically tested, in accordance with 49 CFR 192 and applicable permit conditions, to verify that each pipeline is free from leaks and will provide the required margin of safety at operating pressures. Additional information about hydrostatic testing is provided in Section 1.5.1.6 of Resource Report 1. 2-32 Approximate Mileposts Watershed Name (AP -2 Mainline) County Water Supply Classification' Fishing Creek (Enfield) 30 1 to 39.5 Halifax and Nash Counties WS -IV, NSW Tar River (Tar River Res.) 5 1.0 to 60.4 Nash County WS -IV, NSW Toisnot Swamp 60.4 to 63.8 Nash County WS -111, NSW Cape Fear River (Fayetteville) 130.6 to 134.8 Cumberland County Ws_iv Cape Fear F iver (Smithfield Packing Co) 155 9 to 159.3 Cumberland County WS -1v Lumber River (Lumberton) 173.1 to 180.4 Robeson County WS -1v Water Supply Classifications in North Carolina (NCDENR-DWR, 2014): WS -III = Waters used as sources of water supply for drinking, culinary, or food processing purposes; generally in low to moderately developed watersheds. WS -IV = Waters used as sources of water supply for drinking, culinary, or food processing purposes; generally in moderately to highly developed watersheds NSW — Nutrient Sensitive Waters, supplemental classification where additional nutrient management is needed due to potential for excessive growth of microscopic or macroscopic vegetation. 2.2.6 Horizontal Directional Drill Mud Water Use Atlantic and DTI are proposing to cross six waterbodies, one water impoundment, and two road rights-of-way using the HDD method. In addition, the HDD method is proposed to cross beneath both the Blue Ridge Parkway and the Appalachian National Scenic Trail at the same time. A detailed description of the HDD method is provided in Section 1.5.2.1 of Resource Report 1. Geotechnical studies will be conducted at each of the planned HDD crossings. To the extent possible, these studies will identify subsurface conditions along the proposed drill paths and at the entry and exit sides of each of the respective crossings. Throughout the drilling process, a fluid mixture consisting of water and bentonite clay (a naturally occurring mineral) will be pumped into the drill hole to lubricate the bit, transport cuttings to the surface, and maintain the integrity of the hole. Small pits will be dug at or near the entry and exit points for the HDD to temporarily store the drilling fluid and cuttings, which will consist of a non-toxic slurry of water, bentonite, and native ground substrate (rock and soil). The fluid and cuttings will be pumped from the pits to an on-site recycling unit where the fluid will be processed for reuse. After completion of the HDD operations, the recovered drilling mud will be recycled or disposed of at an approved upland location or disposal facility in accordance with Federal and State/Commonwealth regulations. The estimated water requirements and withdrawal location for each of the proposed HDDs are summarized in Table 2.2.6-1. Withdrawals will be conducted in accordance with State/Commonwealth regulations and permit requirements. 2.2.7 Hydrostatic Test Water and Fugitive Dust Control Water After backfilling and other construction activities that could affect the proposed ACP and SHP pipelines are complete, each pipeline will be hydrostatically tested, in accordance with 49 CFR 192 and applicable permit conditions, to verify that each pipeline is free from leaks and will provide the required margin of safety at operating pressures. Additional information about hydrostatic testing is provided in Section 1.5.1.6 of Resource Report 1. 2-32 Resource Report 2 Water Use and Quality TABLE 2.2.6-1 Water Requirements for Horizontal Directional Drills for the Atlantic Coast Pipeline Pipeline Approximate Water County or City / State or Segment Requirement Locations of Water Project/HDD Commonwealth Milepost (thousands of gallons)' Withdrawals ATLANTIC COAST PIPELINE Blue Ridge Parkway/ Appalachian Augusta County, Virginia AP -1 Mainline/ 336 Water will be National Scenic Trail MP 158.2 Trucked In James River Nelson and Buckingham AP-IMamlme/ 229 James River Counties, Virginia MP 184.7 Roanoke River Northampton and Halifax AP -2 Mainline/ 73 Roanoke River Counties, North Carolina MP 9.9 Cape Fear River Cumberland County, North AP -2 Mainline/ 146 Cape Fear River Carolina MP 149.3 Nottoway River Southampton, Virginia AP -3 Lateral/ 15 Nottoway River MP 32.6 Blackwater River Southampton County and City AP -3 Lateral/ 17 Blackwater River of Suffolk, Virginia MP 38.6 1-64 Crossing City of Chesapeake, Virginia AP -3 Lateral/ 28 Water will be MP 74.4 Trucked In US Route 17 City of Chesapeake, Virginia AP -3 Lateral/ 27 Water will be MP 75.3 Trucked In VEPCO Impoundment City of Chesapeake, Virginia AP -3 Lateral/ 17 Water Impoundment MP 75.6 South Elizabeth River City of Chesapeake, Virginia AP -3 Lateral/ 37 Elizabeth River MP 78.5 SUPPLY HEADER PROJECT No HDI)s proposed N/A N/A a Atlantic and DTI continue to review waterbodies for supply capacity Water for hydrostatic testing will be withdrawn and discharged in accordance with State/Commonwealth regulations and required permits. To minimize impacts of the short duration of larger volume withdrawals of water from streams, Atlantic and DTI will construct water impoundment structures adjacent to several of the water withdrawal points. Use of the water holding areas will allow for a longer duration of withdrawal at lower rates to minimize impacts on stream flows. Extending the timeframe for withdrawal of water and complying with State/Commonwealth regulations and permit requirements will minimize impacts on the aquatic resources within streams used for water withdrawal." Table 2.2.7-1 summarizes the water withdrawal and discharge locations for the proposed hydrostatic testing of ACP and SHP facilities. During water withdrawal, surface water intakes will be set in areas of flowing water to avoid sedimentation. The rate of withdrawal will be controlled to assure a continued flow within the surface water source. Typically, water will be withdrawn at a rate of 1,500 to 3,000 gallons per minute at each withdrawal location, unless otherwise specified in applicable permits. To minimize impacts, water will be drawn out with a low-pressure pump. Screening on the intakes will be sized according to withdrawal permit requirements. Secondary containment will be used on all pumps. In comments filed with the FERC, the USFS commented that the effects of water withdrawals on aquatic resources on National Forest lands should be discussed. 2-33 Resource Report 2 Water Use and Quality Once hydrostatic testing is complete, the test water will be discharged to well -vegetated upland areas or back to the same source from which it was obtained, which will eliminate the translocation of invasive aquatic species that may be present. In addition, this practice will also prevent transporting water from impaired streams (i.e., 3 03 d listed waters) to other waterbodies. Water discharged over land will be directed through containment structures such as hay bales and/or filter bags. The discharge rate will be regulated using valves and energy dissipation devices to prevent erosion. Water will be discharged at a rate commensurate with agency consultations and permit requirements, but will typically range from 1,500 to 2,500 gallon per minute. No chemicals will be added to the test water during hydrostatic testing. Water will be tested prior to introducing it in the pipeline. The water will be tested again prior to discharge once the hydrostatic test is complete. The water will then be discharged in accordance with the Plan and Procedures and applicable permits through an approved discharge structure to remove turbidity or suspended sediments (i.e., dirt left in the pipe during construction) and to prevent scour and erosion. Alternatively, the water will be hauled offsite for disposal at an approved location (Resource Report 1, Section 1.5.1.6). Construction related water discharges in karst areas will be directed to well -vegetated upland areas with no karst features present or to approved discharge structures. Water will not be discharged directly into sinkholes, and discharged water will be directed away from known karst features with a direct connection to the phreatic zone of the karst. 12 Where required, Atlantic and DTI will verify coverage under each State's/Commonwealth's National Pollutant Discharge Elimination System (NPDES) or State/Commonwealth-equivalent general permit prior to discharge of hydrostatic test water. In addition to the water required for hydrostatic testing, approximately 3 8.2 million and 3.4 million gallons of water will be required for dust control during construction of the ACP and SHP, respectively. The water needed for dust control will vary based on site and weather conditions and will be obtained in relatively small volumes throughout the construction and restoration phases of the Projects. The sources for this water are still being evaluated; the majority will be identified during construction. The withdrawals will be in accordance with State/Commonwealth regulations and required permits. Typically, water for dust control will be withdrawn at a rate of 1,500 to 3,000 gallons per minute. Water for hydrostatic testing will generally be withdrawn from August through October; however, this schedule will be dependent on the timing of permit approvals and construction schedules for the Projects and may be subject to adjustment. Water for fugitive dust control will generally be withdrawn between the months of May and September. 2.2.8 Sensitive Surface Waters Waterbodies can be considered sensitive to pipeline construction for several reasons, including the presence of critical aquatic habitat or special status species; high-quality recreational, visual resource, or historic value (e.g., waterbodies listed in the Nationwide Rivers Inventory [NRI]); sensitive State/Conunonwealth use or high quality designations (e.g., coldwater fishery or trout water, Tier 3 waterbodies); or an important riparian area. NRI rivers 12 In comments filed with the FERC, the Virginia Cave Board raised concerns about discharging hydrostatic test water within the Jackson River Valley Atlantic is currently proposing one discharge location with the Jackson River Valley. ( ) 2-34 Resource Report 2 Water Use and Quality crossed are summarized in Resource Report 8. Additionally, waterbodies that have special fisheries designations and/or protected species are addressed in greater detail in Resource Report 3, and time of year restrictions associated with State/Commonwealth designated streams are included in Appendix 2A. Waterbodies can also be considered sensitive if they are of special interest to a land management agency, resource agency, or Native American Tribe. TABLE 2.2.7-1 Water Requirements for Hydrostatic Testing for the Atlantic Coast Pipeline and Header Project State or Approximate Water Commonwealth/ Requirement Locations of Discharges Spread (Millions of Gallons)' Locations of Water Withdrawals (Milepost) (Milepost) ATLANTIC COAST PIPELINE West Virginia Spread 1 4.1 West Fork River (MP 8.2) 113; 21.7; 26 9; 29 79 Spread 2 3.0 Buckhannon River (MP 31.7) 38.7, 46.8; 54.1; 55.8; 57.2 Spread 3 2.8 Tygart Valley River (MP 56 5) 58.1; 63.1 Spread 3 25 Shaver's Fork River (MP 67 .9) b 703 b ; 77.3 Spread 3 13 West Fork Greenbrier River (MP 71.4) b 84.0; 90.7 Spread 3 13 East Fork Greenbrier River (MP 77. 1) 93.2 Virginia Spread 4 3.2 BuIlpasture Creek (MP 102 9) 103 9; 109.9 b; 1157,1214 b, 125.5 Spread 5 32 Middle River (MP 130 4) 129 5, 132. 1; 134.2; 14 1. 1; 149 6; 159.9; 165.9 Spread 5 36 Rockfish Creek (MP 163.7) 168 8, 172 8; 178.9; 183.4 Spread 6 8.1 James River (MP 184.7) 183.4; 205.0 Spread 6 7.5 Appomattox River (MP 220.8) 222.9,2396 Spread 7 7.8 Nottoway River (MP 260.7) 239.6; 260.7; 280.1; 300 1 Spread I 1 1.1 Meherrin River(MP 12.4) 0.0; 12.4 Spread 11 0032 Nottoway River (MP 32 7) 24 3; 35.7, 37.8, 38.3 Spread 11 12 Blackwater River (MP 38.6) 38.6; 53.2, 55 9 Spread 11 0.5 South Branch Elizabeth River (MP 78.5) 76.1; 78.5 North Carolina Spread 8 8.1 Roanoke River (MP 9.9) 0 0; 9 85; 40.0; 47.6; 50.9, 52 7; 56.4 Spread 8 39 Tar River (MP 59.4) 59.7; 63 0; 64 2; 65.6 Spread 9 5.3 Neuse River (MP 98.5) 65 6; 67.1; 74.7; 79 1, 88 0; 93 3; 98.5; 100.9; 105 0, 107.6; 117.8; 124.0 Spread 10 62 Cape Fear River (MP 149.3) 126.7; 137 5; 144. 1; 149.3; 160.7; 167. 1; 177.8, 181 0; 182 3 SUPPLY HEADER PROJECT West Virginia Spread 13 09 South Fork Fishing Creek (MP 29.0) Spread 13 2.1 McElroy Creek (MP 18.5) Pennsylvania Spread 14 0.7 Municipal Water Trucked In (MP 2.7) a Atlantic and DTI continue to review waterbodies; for supply and discharge capacity. b Located on USFS lands 29.0; 30 4; 33 6 0 0, 7 4; 10.4; 10.9; 18.5, 29 0 0.0; 2.7; 3.9 The proposed ACP and SHP pipeline facilities will cross 129 and 17 waterbodies, respectively, which are considered sensitive based on the criteria described above. In addition, ACP will cross four drainages with rare fish species. A list of these waterbodies and drainages is 2-35 Resource Report 2 Water Use and Quality provided in Table 2C in Appendix 2C. Applicable timing restrictions, permit requirements and conditions, and best management practices will be utilized to minimize impacts on these waters. The USFS stated in a comment letter to the FERC that between October I through June 1 potential sediment -producing ground disturbing activities within the Monongahela National Forest that are within 100 feet of a perennial trout streams require the use of additional erosion control measures and seeding or mulching, applied concurrently with the activity. Atlantic will implement these measures which are required by the USFS. Additional details are included in Resource Report 3. 1 2.2.9 Waterbody Construction Procedures Atlantic and DTI will use the open -cut, flume, dam -and -pump, cofferdam, conventional bore, or HDD methods to construct the proposed ACP and SHP pipelines across waterbodies. Atlantic and DTI will utilize the least environmentally damaging approach in conjunction with available best management practices for each waterbody crossing to minimize impacts on the waterbody itself and any receiving waters. In each case and for each method, Atlantic and DTI will adhere to the measures specified in the Procedures; site-specific modifications to the Procedures requested by Atlantic and DTI and approved by the FERC; and additional requirements identified in Federal or State/Commonwealth waterbody crossing permits. Permits required for the ACP and SHP are provided in Table 1. 12-1 in Resource Report 1. Atlantic and DTI will prepare a Plan of Development (POD) or Construction, Operation, and Maintenance Plan (COM Plan), which will identify construction procedures and mitigation measures to be implemented on federally managed lands. Atlantic and DTI will submit preliminary draft PODs or COM Plans to the Bureau of Land Management, USFS, and U.S. Fish and Wildlife Service (FWS) in September 2015. The proposed construction method for each waterbody crossing along the proposed ACP and SHP pipelines are identified in Appendix 2A. Detailed descriptions of the proposed crossing methods are provided in Section 1.5.2.1 in Resource Report 1. Construction methods for waterbodies that isolate the pipeline trench from flowing water (e.g. flume, dam -and -pump, or cofferdam) will be utilized where these methods are proposed and perceptible flow is present at the time of the crossing. 2.2.10 Waterbody Construction -Related Impacts and Mitigation Impacts on waterbodies crossed by the proposed ACP and SHP facilities could occur as a result of construction activities in stream channels and on adjacent banks. Clearing and grading of stream banks, blasting (if required), in -stream trenching, trench dewatering, and backfilling could each result in temporary, local modifications of aquatic habitat involving sedimentation, increased turbidity, and decreased dissolved oxygen concentrations. In almost all cases, these impacts will be limited to the period of in -stream construction, and conditions will return to normal shortly after stream restoration activities are completed. Agency recommended time of year restrictions are listed in Appendix 2A and discussed further in Resource Report 3. Additionally, Atlantic and DTI have reviewed the route and made ad ustments to provide for additional avoidance and minimization of impacts on stream crossings, such as avoiding multiple crossings of the same stream, where feasible. 2-36 Resource Report 2 Water Use and Quality Site-specific questions pertaining to avoidance and minimization are common and often can be resolved by reviewing site-specific competing constraints. For example, a comment received by the West Virginia Department of Natural Resources recommended minimization of the number of crossings of Becky Creek near MP 58.7. 13 Close examination of this area indicates there is a nearby home site and many out buildings that require crossing of Becky Creek twice to avoid crossing thru this landowner home site. Similar evaluations have been completed across the Projects and details pertaining to the alternatives review are provided in Resource Report 10. Vegetative clearing, grading for construction, and soil compaction by heavy equipment near stream banks could promote erosion of the banks and the transport of sediment into waterbodies by stormwater runoff. To minimize these potential impacts, Atlantic and DTI will install equipment bridges, mats, and pads, as necessary. Temporary bridges will be installed across waterbodies in accordance with the Procedures to allow construction equipment and personnel to cross. The bridges may include clean rock fill over culverts, timber mats supported by flumes, railcar flatbeds, flexi-float apparatuses, or other types of spans. Additionally, Atlantic and DTI will locate additional temporary workspace (ATWS) at least 50 feet from stream banks (with the exception of site-specific modifications requested by Atlantic and DTI and approved by the FERC). To meet with the requirements within the Forest Plans for both the Monongahela National Forest and George Washington National Forest, ATWS will be setback 100 feet from in -stream waterbody crossings that occur on USFS lands. Temporary sediment barriers will be installed around disturbed areas as outlined in the Plan and Procedures. Upon completion of construction, Atlantic and DTI will install permanent erosion control measures at stream crossing locations to provide long-term protection of water quality according to the Plan and Procedures and permit requirements. Atlantic and DTI will require equipment used during construction to be cleaned prior to working on the ACP and SHP, as required by applicable permits and the Plan and Procedures. Sedimentation and increased turbidity can occur as a result of in -stream construction activities, trench dewatering, or stormwater runoff from construction areas. In slow moving waters, increases in suspended sediments (turbidity) may increase the biochemical oxygen demand and reduce levels of dissolved oxygen in localized areas during construction. Suspended sediments also may alter the chemical and physical characteristics of the water column (e.g., color and clarity) on a temporary basis. Atlantic and DTI will use material excavated from the pipeline trench to backfill the trench once the pipe is installed to avoid introduction of foreign substances into waterbodies. Potential effects on fisheries due to increased turbidity and sedimentation resulting from in -stream construction activities are addressed in Resource Report 3. As noted above, Atlantic and DTI will install temporary equipment bridges to reduce the potential for turbidity and sedimentation resulting from construction equipment and vehicular traffic crossing waterbodies. Temporary bridges will be installed across waterbodies in 13 In comments filed with the FERC, the West Virginia Department of Natural Resources recommended avoiding multiple crossmgs of Becky Creek near MP 58 7. 2-37 Resource Report 2 Water Use and Quality accordance with the Procedures to allow construction equipment and personnel to cross. The bridges may include clean rock fill over culverts, timber mats supported by flumes, railcar flatbeds, flexi-float apparatuses, or other types of spans. Construction equipment will be required to use the bridges, except that the clearing and bridge installation crews will be allowed one pass through waterbodies before bridges are installed. The temporary bridges will be removed when construction and restoration activities are complete. In -stream construction will typically be completed within 24 to 48 hours at each stream crossing where waterbodies are less than 100 feet in width. After the pipeline is installed across a waterbody using one of the methods described above, the trench will be backfilled with native material excavated from the trench. The strearnbed profile will be restored to pre-existing contours and grade conditions to prevent scouring. The stream banks will then be restored as near as practicable to pre-existing conditions and stabilized. Stabilization measures could include seeding, tree planting, installation of erosion control blankets, or installation of riprap materials, as appropriate. Temporary erosion controls will be installed immediately following bank restoration. The waterbody crossing area will be inspected and maintained until restoration of vegetation is complete. In addition, according to the Plan and Procedures, Atlantic and DTI will install temporary erosion control devises in uplands adjacent to waterbody crossings subsequent to construction and until there is successful revegetation of the construction right-of-way. Permanent erosion controls will be installed, such as slope breakers, to aid long-term stabilization along with the restored vegetation. Within riparian corridors on lands managed by the GWNF, in-strearn and terrestrial woody debris will be.replaced during restoration of the pipeline right-of-way as practicable. Additional details regarding restoration of upland vegetation adjacent to waterbodies on USFS lands are provided in Resource Report 3. 14 Construction methods for waterbodies are described in Section 1.5.2. 1. The specific construction method proposed for each waterbody crossing is listed in Appendix 2A. The method proposed for each crossing is dependent on topography, soil conditions, subsurface geology, and the width and depth of the waterbody. HDD is a proven method for minimizing impacts on surface resources, including waterbodies, given the appropriate conditions. 15 The radius of curvature, subsurface geology, and right-of-way configuration are all considered in assessing the feasibility of an HDD. Right- of-way configuration is an important consideration because HDD requires assembly of a drill string (i.e., the segment of pipeline to be installed beneath the waterbody) in line with the alignment of the HDD. This can require clearing a "false" right-of-way, which can affect riparian and/or wetland vegetation adjacent to the waterbody. In routing the pipeline and selecting crossing methods for waterbodies, Atlantic and DTI attempted to minimize the number and lengths of crossings, as well as, potential impacts on wildlife, vegetation, and water quality. Many waterbodies, for example, are proposed to be In comments filed with the FERC, the USFS expressed concerns about sedimentation in streams due to exposed slopes subsequent to construction. In comments filed with the FERC, the EPA identified the HDD method as the least disruptive construction method in many situations. 2-38 Resource Report 2 Water Use and Quality crossed using a dry crossing method, such as flume, dam-and-purnp, or cofferdam, to avoid or minimize impacts on water quality due to sedimentation and turbidity and impacts on fisheries by proving uninterrupted access for fish to swim across or around the construction area. During construction, the open trench may accumulate water, either from a high water table and seepage of groundwater into the trench or from precipitation. In accordance with the Plan and Procedures, and when necessary, trench water will be removed and discharged into an energy dissipation/sediment filtration device, such as a geotextile filter bag and/or straw bale structure, to minimize the potential for erosion and sedimentation. The application of concrete coating will generally occur in contractor yards identified for the Projects. In areas where concrete coating of pipe is required within the construction right-of- way, the concrete coating activities will occur in accordance with the SPCC Plan (see Appendix 1F of Resource Report 1). Concrete coating activities will occur a minimum of 100 feet from wetlands, waterbodies, and springs, and 300 feet from karst features. 16 Concrete - coated pipe will be installed after the concrete is dried and will not be dispersed when submerged in water. Concrete coating is used to create negative buoyancy along the pipeline when required for waterbody or wetland crossings and would only be required on USFS lands if necessitated by site-specific conditions. Based on analysis of the Soil Survey Geographic Database, approximately I I percent (67.8 miles) of the proposed ACP and SHP pipeline routes will cross areas with hard bedrock at depths of less than 60 inches (Soil Survey Staff, 2015). Construction in these areas may require blasting or other special construction techniques (see Section 6.2 of Resource Report 6). Individual stream,crossing locations where blasting may be necessary will be identified during construction based on site-spccific conditions. Blasting in streams will only be used when traditional means of trenching (e.g., ripper shanks, excavators, rock hammers) have failed or are deemed impractical due to constraints imposed by stream crossing time limits. If required, blasting will primarily occur at dry crossings, after the work area has been isolated from stream flow. If blasting is necessary in a flowing waterbody, the use of controlled blasting techniques, where small, localized detonations are utilized, will avoid or minimize the impacts of blasting and limit rock fracture to the immediate vicinity of these activities. Immediately following blasting, Atlantic and DTI will remove shot rock that impedes stream flow. Blasting techniques will be in compliance with Federal, State/Commonwealth, and local regulations governing the use of explosives and in accordance with the Blasting Plan (see Appendix 1 F of Resource Report 1) and the Plan and Procedures. Preparation of the rock for blasting (e.g., drilling shot holes) is expected to cause enough disturbance in waterbodies to displace most aquatic organisms from the immediate vicinity of the blast. To further reduce the potential for impacts on aquatic organisms in flowing waterbodies, Atlantic and DTI will use techniques such as scare charges or banging on a submerged piece of pipe before the blast to disperse mobile aquatic organisms from the blast area before the blast is 16 In comments filed with the Conmussion, the Virginia Department of Game and Inland Fisheries said that in-st,. use of concrete should be done only m dry con(htions, allowmg concrete to harden prior to returning stream flow 2-39 Resource Report 2 Water Use and Quality conducted. These steps will avoid or minimize the impact of blasting, if necessary, on aquatic organisms; nonetheless, organisms that are not displaced by pre -blast measures could be impacted. The SPCC Plan for the Projects (see Appendix 1F of Resource Report 1) will describe measures that personnel and contractors will implement to prevent and, if necessary control, inadvertent spill of fuels, lubricants, solvents, and other hazardous materials that could affect water quality. As required in the Procedures and the SPCC Plan, hazardous materials, chemicals, lubricating oils, and fuels used during construction will be stored in upland areas at least 100 feet from wetlands and waterbodies. Refueling of construction equipment will be conducted at least 100 feet from wetlands and waterbodies, whenever possible. However, there will be certain instances where equipment refueling and lubricating may be necessary in or near waterbodies. For example, stationary equipment, such as water pumps for withdrawing hydrostatic test water, may need to be operated continuously on the banks of waterbodies and may require refueling in place. The SPCC Plan will address the handling of fuel and other materials associated with the Projects. As required by the Procedures, the SPCC Plan will be available during construction on each construction spread. As noted above, it is possible that previously undocumented sites with contaminated soils or groundwater could be discovered during construction of the Projects. Atlantic and DTI have prepared and will implement a Contaminated Media Plan (see Appendix 1 F of Resource Report 1) to address these circumstances. The Contaminated Media Plan will describe measures to be implemented in the event that signs of contaminated soil and/or groundwater are encountered during construction. Signs of potential contamination could include discoloration of soil, chemical -like odors, or sheens on soils or water. Containment measures will be implemented to isolate and contain the suspected soil or groundwater contamination and collect and test samples of the soil or groundwater to identify the contaminants. Once the contaminants are identified, a response plan will be developed for crossing or avoiding the site. Use of the HDD method may avoid impacts on waterbodies because it allows for the pipe to be installed underneath the ground surface without disturbance of the streambed or banks. However, a temporary, localized increase in turbidity could occur in the event of an inadvertent release of drilling fluid to the waterbody. Drilling fluid to be used on the ACP will be composed of water and bentonite clay (a naturally occurring mineral). The EPA does not list bentonite as a hazardous substance, and no long-term adverse environmental impacts are expected should an inadvertent release occur. Similarly, while native soils may mix with the drilling fluid as a result of the drilling process, no adverse environmental impacts from these materials are expected should an inadvertent return occur. Due to the possibility of drilling fluid loss during HDD operations, Atlantic and DTI have prepared and will implement a Horizontal Directional Drill Fluid Monitoring, Operations, and Contingency Plan (see Appendix 1F of Resource Report 1). The plan will describe measures to prevent, detect, and respond to inadvertent returns, including but not limited to, monitoring during drilling operations, the types of equipment and materials that must be readily available to contain and clean up drilling mud, containment and mitigation measures, notification requirements, and guidelines for abandoning the directional drill, if necessary. 2-40 Resource Report 2 Water Use and Quality Once construction is complete, the pipeline will be buried below the ground surface and, therefore, will not impact water retention or floodplain storage within riparian corridors. Atlantic and DTI are routing the proposed pipelines to avoid sharp angle crossings or crossing streams where high stream energy could result in bank erosion. Atlantic and DTI will implement measures outlined in the Procedures to minimize impacts on the waterbodies crossed, including the installation of trench plugs to prevent water from flowing along the trenchline during and after construction. These measures will minimize potential impacts on surface and below ground hydrology. All waterbody crossings will be in accordance with the requirements identified in the Federal or State/Commonwealth waterbody crossing permits obtained for the Projects. During operations, the proposed pipelines will transport natural gas, which primarily is methane. Methane is buoyant at atmospheric temperatures and pressure, and disperses rapidly in air. The proposed pipelines will not carry liquids. Therefore, in the unlikely event of a leak, impacts on surface waters or groundwater from methane are not anticipated. Moreover, Atlantic and DTI will utilize a rigorous Integrity Management Plan, as discussed in Section 11.2.3 of draft Resource Report 11, to prevent leaks on the system. 17 2.2.11 Facility Operations In some cases, construction of aboveground facilities and access roads will require permanent impacts on waterbodies. Where permanent access roads cross perennial streams within USFS lands, the access road and associated drainage structures (i.e., culverts) will be designed and constructed in accordance with USFS requirements. These permanent impacts could include the placement of a culvert or bridge across the waterbody to accommodate a permanent access road or the relocation of a watercourse to allow for the siting of an aboveground facility. Atlantic and DTI will continue to adjust the footprint and/or location of the aboveground facilities and access roads in order to reduce or eliminate impacts on waterbodies. Where pennanent impacts are required, Atlantic and Dominion will comply with all Federal and State/Commonwealth permit requirements. To stabilize improved access roads, Atlantic and DTI will implement erosion and sediment controls according to the Plan and Procedures and allow stabilization of access road slopes adjacent to waterbodies. Impacts during operation of the proposed facilities will be limited to instances where maintenance activities require excavation or repair in the vicinity of a waterbody. In such a case, the impacts and mitigation will be similar to those described above for construction activities. As part of the POD and/or the COM Plan for a Right -of -Way Grant to cross Federal lands, Atlantic will consult with the USFS and applicable Federal agencies to develop a stream crossing monitoring plan and a water quality monitoring plan. Under the FERC requirements for construction and operation of a new interstate natural gas transmission pipeline, Atlantic will be required to comply with the Procedures that provide strict requirements associated with natural gas pipeline construction and restoration of streams and rivers. The FERC staff has developed these Procedures over the past 27 years in conjunction 17 In comments filed with the Commission, several individuals said that leaks in the pipeline could contaminate groundwater and surface water over time. 2-41 Resource Report 2 Water Use and Quality with numerous Federal and State/Commonwealth agencies, including the USFS, to ensure that interstate natural gas pipeline construction and mitigation, including restoration, in the United States is conducted while implementing the most environmentally protective and acceptable best management practices. Atlantic will be required to utilize environmental inspectors during construction to ensure compliance with the environmental requirements of not only the FERC authorization, but also of all other Federal and State/Commonwealth permits, as well as the requirements of federal and state land managers. During operations, line patrols will ensure that the integrity of the pipeline is maintained and leaks are rapidly detected and repaired. Atlantic will inspect the transmission pipeline and associated aboveground facilities monthly via aircraft. The aircraft patrols provide information on erosion, exposed pipe, possible encroachment, possible leaks, and other conditions that could affect the safety and operation of the pipeline systems. Atlantic and DTI will incorporate an aerial patrol -based mechanical leak detection system capable of measuring methane, total hydrocarbons, and carbon dioxide at sub -parts -per -million concentrations. The system uses a monitoring rate of 50 samples per second to immediately pinpoint gas leaks, which are then logged via Global Positioning System (GPS). Ground-based surveillance activities will also be conducted on an annual basis and additional periodic patrols will be conducted on an as needed basis. Both the stream crossing and water quality monitoring plans will include monitoring requirements to be implemented in the MNF and GWNF. For the stream crossing monitoring plan, Atlantic will conduct an examination of the waterbody crossings on USFS lands annually as part of its ground-based surveillance program to ensure stream stability and maintenance of river banks. Atlantic will report the results of these inspections to the relevant Federal agencies. Regarding water quality monitoring, as part of its aerial and ground-based surveillance activities, Atlantic will identify pipeline integrity issues (erosion, leaks, etc.) and institute immediate corrective action. As such, no long-term effects to water quality are anticipated as a result of pipeline operations. Atlantic will report the results of pipeline inspections to the relevant Federal agencies and will work with them as needed to implement the water quality monitoring plan. 2.3 WETLANDS The USACE and EPA jointly define wetlands as "those areas that are inundated or saturated by surface or groundwater at a frequency and duration sufficient to support, and that under normal circumstances do support, a prevalence of vegetation typically adapted for life in saturated soil conditions." The FERC defines wetlands as "any area that is not actively cultivated or rotated cropland and that satisfies the requirements of the current Federal methodology for identifying and delineating wetlands." Wetland delineations for the ACP and SHP were conducted using a definition of "waters of the U.S." that is consistent with, and at least as stringent as, the final Clean Water Rule: Definition of "Waters of the United States, " 80 Federal Register 37054 (June 29, 2015). Atlantic 2-42 Resource Report 2 Water Use and Quality and DTI will obtain preliminary jurisdictional determinations from the USACE for these delineations. The ACP will cross four USACE Districts: Pittsburgh, Huntington, Norfolk, and Wilmington. ACP facilities in Harrison, Lewis, Upshur, and Randolph Counties, West Virginia are in the Pittsburgh District. ACP facilities in Pocahontas County, West Virginia are in the Huntington District. ACP facilities in Virginia are in the Norfolk District. ACP facilities in North Carolina are in the Wilmington District. The SHP will cross two USACE Districts: Pittsburgh and Huntington. SHP facilities in Pennsylvania and in Harrison and Marshall Counties, West Virginia are in the Pittsburg District. SHP facilities in Wetzel, Tyler, and Doddridge Counties, West Virginia are in the Huntington District. 2.3.1 Wetland Types The proposed ACP Project area contains palustrine and estuarine wetlands, while the proposed SHP Project area only contains palustrine and riverine wetlands. Palustrine wetlands include all non -tidal wetlands dominated by lichens, emergent mosses, persistent emergents, shrubs, or trees. Salinity in these wetlands is below 0.5 percent. Estuarine wetlands are deepwater tidal habitats and adjacent tidal wetlands which are at least occasionally diluted by freshwater runoff. Salinity gradients can range from hyperhaline to oligohaline. Riverine wetlands include all wetlands and deepwater habitats contained within a channel, with the exception of wetlands dominated by trees, shrubs, persistent emergents, emergent mosses, or lichens and habitats with water containing ocean -derived salts in excess of 0.5 percent (Cowardin et al., 1979). Based on field survey data augmented by FWS National Wetland Inventory (NWI) data, the proposed ACP facilities will cross palustrine emergent (PEM), palustrine scrub -shrub (PSS), palustrine forested (PFO), palustrine aquatic bed (PAB), palustrine unconsolidated bottom (PUB), and estuarine intertidal emergent (E2E) wetland types. Based on the same data sources, the proposed SHP pipeline facilities will cross PEM, PSS, and PFO wetlands. NWI maps for the ACP and SHP are provided in Appendix 2G. 2.3.2 Existing Wetland Resources During the routing phase of the Projects, NWI data was used to provide a preliminary analysis of wetland resources and to assess where wetland impacts could be avoided or minimized. NWI data was also used to estimate the number, size, and locations of wetlands along the proposed pipeline routes prior to conducting wetland delineations in the fi6ld. Atlantic and DTI began conducting field surveys during the 2014 field season, on properties where survey permission was granted by the landowner, to identify and delineate wetlands within the ACP and SHP pipeline construction corridors and other work areas. The wetland delineation study area for the ACP and SHP consisted of a 300 -foot -wide corridor centered on the proposed pipeline centerlines, a 50 -foot -wide corridor centered over access roads, and the construction footprints at aboveground facility sites. The wetland delineation for the Projects encompassed all areas required for installation of the proposed pipelines (i.e., the construction right-of-way, additional temporary workspace, staging areas, and access roads) and 2-43 Resource Report 2 Water Use and Quality the aboveground facilities (i.e., compressor and M&R stations and other facilities). Table 2.3.2- I summarizes the survey progress for the ACP and SHP pipeline and aboveground facilities. In addition, approximately 135 miles of access roads have been surveyed on ACP, and 33 miles of access roads have been surveyed on SHP. Wetlands were delineated in accordance with the 1987 Corps of Engineers Wetlands Delineation Manual and the Regional Supplement to the Corps of Engineers Wetland Delineation Manual: Eastern Mountains and Piedmont Region (Version 2.0) or the Regional Supplement to the Corps of Engineers Wetlands Delineation Manual: Atlantic and Gulf Coastal Plain Region (Version 2.0) (USACE, 1987, 2010, 2012), as appropriate. All wetlands within the survey corridors were delineated regardless of the delineator's opinion regarding its jurisdictional status. Observations of vegetation, hydrology, and soils were recorded, and photographs were taken at each wetland. A more detailed description of the methodology used for wetland delineations is included in the wetland and waterbody delineation reports for the Projects (see Appendices 2D and 2E). Where field surveys were not able to be completed due to lack of access to properties, a desktop assessment was completed to delineate wetlands and waterbodies using a combination of NWI data, USGS topographic maps, Soil Survey Geographic Database (SSURGO) data, and high resolution aerial photography. Field surveys in these areas will be completed as access to properties is obtained. 2.3.3 Wetland Reserve Program The Wetland Reserve Program was a program in which the U.S. Department of Agriculture (USDA) Natural Resource Conservation Service (NRCS) provided technical and financial support to private landowners who wanted to restore wetlands on their property. The program offered landowners a means to establish long-term conservation practices while achieving the greatest wetland functions and values for every acre enrolled in the program. Conservation easement options included 30 -year easements and permanent easements (USDA NRCS, 2008). The WRP program was repealed in the Agricultural Act of 2014 with the establishment of a new program, the Agricultural Conservation Easement Program (ACEP). However, the change does not affect the validity or terms of the conservation easements established through the WRP (USDA NRCS, 2014a). Based on a review of NRCS conservation easement data, no VV`RP or ACEP conservation easements will be crossed by the proposed ACP or SHP facilities (USDA NRCS, 2014b). 2-44 TABLE 2.3.2-1 wetland and waterbody Survey Status — Percentage Complete Project/Facility Type West Virginia Virginia North Carolina Pennsylvania Total ATLANTIC COAST PIPELINE Mainline Pipeline 94 62 98 N/A 79 Compressor Stations 100 100 100 N/A 100 M&R and Pig Launcher/Receiver Sites 50 50 100 NIA 78 Contractor Yards 0 0 0 N/A 0 SUPPLY HEADER PROJECT Mainline Pipeline 92 N/A N/A 100 93 Compressor Stations 100 N/A N/A 100 100 Pig Launcher/Receiver Sites 100 N/A N/A 100 100 Contractor Yards 100 N/A N/A 100 100 Wetlands were delineated in accordance with the 1987 Corps of Engineers Wetlands Delineation Manual and the Regional Supplement to the Corps of Engineers Wetland Delineation Manual: Eastern Mountains and Piedmont Region (Version 2.0) or the Regional Supplement to the Corps of Engineers Wetlands Delineation Manual: Atlantic and Gulf Coastal Plain Region (Version 2.0) (USACE, 1987, 2010, 2012), as appropriate. All wetlands within the survey corridors were delineated regardless of the delineator's opinion regarding its jurisdictional status. Observations of vegetation, hydrology, and soils were recorded, and photographs were taken at each wetland. A more detailed description of the methodology used for wetland delineations is included in the wetland and waterbody delineation reports for the Projects (see Appendices 2D and 2E). Where field surveys were not able to be completed due to lack of access to properties, a desktop assessment was completed to delineate wetlands and waterbodies using a combination of NWI data, USGS topographic maps, Soil Survey Geographic Database (SSURGO) data, and high resolution aerial photography. Field surveys in these areas will be completed as access to properties is obtained. 2.3.3 Wetland Reserve Program The Wetland Reserve Program was a program in which the U.S. Department of Agriculture (USDA) Natural Resource Conservation Service (NRCS) provided technical and financial support to private landowners who wanted to restore wetlands on their property. The program offered landowners a means to establish long-term conservation practices while achieving the greatest wetland functions and values for every acre enrolled in the program. Conservation easement options included 30 -year easements and permanent easements (USDA NRCS, 2008). The WRP program was repealed in the Agricultural Act of 2014 with the establishment of a new program, the Agricultural Conservation Easement Program (ACEP). However, the change does not affect the validity or terms of the conservation easements established through the WRP (USDA NRCS, 2014a). Based on a review of NRCS conservation easement data, no VV`RP or ACEP conservation easements will be crossed by the proposed ACP or SHP facilities (USDA NRCS, 2014b). 2-44 Resource Report 2 Water Use and Quality 2.3.4 Wetland Crossings 2.3.4.1 Pipeline Facilities Based on field and NWI data, there will be a total of 1,068 wetland crossings by the proposed ACP pipeline routes. Where the route crosses a single wetland more than once, each separate crossing was counted. The proposed ACP mainline facilities will have 406 wetland crossings along AP -1 (125 wetland crossings in West Virginia and 281 wetland crossings in Virginia), and 421 wetland crossings along AP -2 in North Carolina. The proposed ACP lateral pipeline facilities will have 239 wetland crossings along AP -3 (44 in North Carolina and 195 in Virginia), no wetland crossings along AP -4 in Virginia, and two wetland crossings along AP -5 in Virginia. The combined linear crossing distance of all wetlands is 69.9 miles, accounting for approximately 12.4 percent of the combined length of the pipeline routes. Approximately 9.6 percent (6.7 miles) of the wetlands crossed by the ACP pipeline facilities are characterized as PEM, 76.1 percent (53.2 miles) are characterized as PFO, and 14.2 percent (9.9 miles) are characterized as P S S. The remaining less than 0. 1 percent (0. 1 mile) of wetlands consists of estuarine, and unconsolidated bottom wetland types. Based on a combination of survey data and land use data for unsurveyed areas, 12 wetlands crossed by the ACP mainlines are characterized as farmed wetlands (two on AP -1 in West Virginia; nine on AP -1 in Virginia; and one on AP -2 in North Carolina). In total, approximately 656.7 acres of wetlands will be temporarily impacted by construction of the ACP pipeline facilities. Maintenance activities along the pipeline right-of- way will impact approximately 204.4 acres of wetlands due to the conversion of PFO and PSS wetlands to PEM wetland types. The proposed Project will result in the conversion of approximately 192.4 acres of PFO wetlands and 12.0 acres of PSS wetlands. Based on field and NWI data, there will be a total of 24 wetland crossings by the proposed SHP pipeline loops. The TL -635 pipeline loop in West Virginia will have five PFO, six PEM, and one PSS wetland crossings. The TL -636 pipeline loop in Pennsylvania will have seven PEM and five PFO wetland crossings. The combined linear crossing distance of all wetlands is 0.3 mile, accounting for approximately 0.8 percent of the combined length of the pipeline loops. Approximately 2.6 acres of wetlands will be temporarily disturbed during construction of the SHP pipeline facilities. Maintenance activities along the pipeline right-of- way will impact approximately 0.3 acre of wetlands due to the conversion of PFO and PSS wetlands to PEM wetland types. Table 2.3.4-1 provides a summary of wetland impacts by wetland type along the proposed ACP and SHP pipeline routes. Tables 2H-1 and 2H-2 in Appendix 2H provide a complete list of wetlands identified along the proposed pipeline routes with their MP locations, classification, crossing length, and area affected by construction and operation of the Projects. 2-45 Resource Report 2 Water Use and Quality TABLE 2.3.4-1 Summary of Wetland Types Affected by Construction and Operation of the Atlantic Coast Pipeline and Supply Header Project Temporary Cowardin. Crossing Construction Permanent Operational Pipeline Facility/State or Commonwealth Classification Length (feet) Impact (acres) b Easement (acres)' Impact (acres) d ATLANTIC COAST PIPELINE AP -1 West Virginia PEM 6,091 11.8 10.2 0.0 PFO 685 1.5 1.2 0.5 PSS 80 0.2 0.2 <0 I West Virginia Total 6,856 13.4 11.6 0.5 Virginia PEM 6,029 12.6 9.3 0.0 PFO 23,506 52.0 39.3 15.7 PSS 8,077 170 13.7 1.8 PUB 0.0 0.0 0.0 0.0 Virginia Total 37,611 81.6 62.3 17.5 AP -2 North Carolina PEM 5,572 9.8 69 0.0 PFO 178,806 3103 2054 122.9 PSS 33,015 57.1 37.7 7.6 PUB 85 0.1 0.1 0.0 North Carolina Total 217,477 377.4 250.0 130.5 AP -3 North Carolina PEM 3,426 4.1 3.4 0.0 PFO 5,746 120 7.1 4.1 PSS 235 0.6 03 0.1 North Carolina Total 9,406 16.7 10.8 4.2 Virgima E2E 48 0.2 0.1 0.0 PEM 14,394 26.7 16.9 0.0 PFO 72,073 121.7 818 49.0 PSS 11,008 18.8 12.5 2.5 Virginia Total 97,522 167.3 111.3 51.5 AP4 No wetlands identified AP -5 Virginia PFO 171. 0.3 0.2 0.1 Virginia Total 171 0.3 0.2 0.1 ACP PROJECT TOTAL 369,044 656.7 446.3 204.4 SUPPLY HEADER PROJECT TL -635 West Virginia PEM 880.3 0.9 0.7 00 PFO 299.6 05 0.3 0.2 PSS 64.5 01 0.1 <0.1 West Virginia Subtotal 1244.4 1.5 1.1 0.2 2-46 Resource Report 2 Water Use and Quality TABLE 2.3.4-1 (cont'd) Summary of Wetland Types Affected by Construction and Operation of the Atlantic Coast Pipeline and Supply Header Project Temporary Cowardin Crossing Construction Permanent Operational Pipeline Facility/State or Commonwealth Classification a Length (feet) Impact (acres) b Easement (acres) impact (acres) d TL -636 Pennsylvania PEM 391.0 0.7 04 0.0 PFO 198.3 0.4 0.2 0.1 Pennsylvania Subtotal 589.3 1.1 0.6 0.1 SHP PROJECT TOTAL 1,833.7 2.6 1.7 0.3 a Wetland types according to Cowardin et al. (1979). PFO = palustrine forested PSS = palustrine scrub -shrub PEM = palustrine emergent PUB = palustrine unconsolidated bottom E = estuarine b Temporary wetland impacts associated with the construction right-of-way. C Includes acres of wetlands within the permanent pipeline easement. d Operational impacts are associated with scrub -shrub and forested wetlands. Operational requirements allow a 10 -foot -wide corridor centered over the pipeline to be maintained in an herbaceous state, and for the removal of trees within 15 feet on either side of the pipeline To determine conversion impacts on scrub -shrub wetlands, a 10 -foot -wide corridor centered over the pipeline was assessed A 30 -foot -wide corridor centered over the pipeline was assessed for forested wetlands. Because the easement will be maintained in an herbaceous state, there will be no operational impacts on emergent wetlands. Note: The totals shown in this table may not equal the sum of addends due to rounding. The data summarizing wetland crossings in Table 2.3.4-1 and the tables located in Appendix 2H are based on field surveys conducted to date. In areas where survey has not yet been completed, NWI data was used to estimate the size and location of wetlands along the proposed ACP and SHP pipeline routes. For these wetlands, the Wetland ID shown in the tables in Appendix 2H is identified as NWI. Maps showing the proposed ACP and SHP pipeline routes and field surveyed wetlands are provided in the ACP and SHP wetland delineation reports located in Appendix 2D and 2E, respectively. NWI wetlands are shown on maps provided in Appendix 2G. Federal Lands The ACP crosses four areas of federally managed land: the Monongahela National Forest; George Washington National Forest (which includes the Appalachian National Scenic Trail); Blue Ridge Parkway; and Great Dismal Swamp National Wildlife Refuge (GDS-NWR). Additional inforination about these lands is provided in Section 8.7.1 of Resource Report 8. Table 2.3.4-2 provides a summary of wetlands crossed within each of these Federal land units. The SHP does not cross Federal Lands. 2.3.4.2 Aboveground Facifities Aboveground facilities (i.e., compressor stations, M&R stations, and valves) have been sited such that impacts on wetlands will be avoided and minimized to the maximum extent practicable. 2-47 Resource Report 2 Water Use and Quality TABLE 2.3.4-2 Summary of wetland Types Affected by Construction and Operation of the Atlantic Coast Pipeline on Federal Lands Temporary Lewis County, YVV PEM Federal Land Cowardin Wetland Crossing Construction impact Operational Federal Land Unit Crossed (miles) Classification a Length (Feet) (acres) b Impact (acres)' Monongahela NF 18.6 PEM/PFO/PSS 2,919/365/56 5.2/0.7/0.1 0.0/0.1/<O.l George Washington NF 12.2 PFO 12 <0. 1 <0. I Blue Ridge Parkway 0.1 None 0 00 0.0 Great Dismal Swamp NWR d 17 PEM/PFO 586/5,046 0.6/9.7 0.0/3.4 ACP Project Total <0.1 Mockingbird Hill Compressor Station 8,984 16.4 3.5 a Wetland types according to Cowardin et al. (1979). PFO palustrme forested PEM palustrine emergent b Temporary wetland impacts associated with the construction right-of-way. c Operational impacts are associated with scrub -shrub and forested wetlands. Operational requirements allow a 10 -foot -wide corridor centered over the pipeline to be maintained in an herbaceous state, and for the removal of trees within 15 feet on either side of the pipeline. To determine conversion impacts on scrub -shrub wetlands, a 10 -foot -wide corridor centered over the pipeline was assessed. A 30 -foot -wide corridor centered over the pipeline was assessed for forested wetlands d Except for approximately 1,000 feet, the entire proposed line will be located within 300 feet of existing pipelines or electric transmission lines. Note: The totals shown in this table may not equal the sum of addends due to rounding. Construction of ACP Compressor Stations I and 2, two of the M&R stations, and one of the pig launcher sites will impact 3.0 acres of wetlands, of which 0.4 acre will be permanently filled for operation of the facility (see Table 2.3.4-3). The construction and operation of the remaining aboveground facilities will not impact wetlands. Modification and expansions at the existing SHP compressor stations and construction of one of the pig launchers will impact 0.2 acre of wetlands, of which 0. 1 acre will be permanently filled for operation the facilities. The construction and operation of the remaining aboveground facilities for the ACP and SHP will not impact wetlands. TABLE 2.3.4-3 Summary of Wetlands Affected by Aboveground Facilities for the Atlantic Coast Pipeline County or City/ State or Cowardin Construction Permanent Impacts Facility Commonwealth Classification a Impacts (acres) (acres) ATLANTIC COAST PIPELINE Compressor Station I Lewis County, YVV PEM <0. 1 00 Compressor Station 2 Buckingham County, VA PFO/PSS/PEM/ 05/1.3/0.8 0.0 Long Run M&R Station Randolph County, WV PEM <0. I <0. I Elizabeth River M&R Station City of Chesapeake, VA PFO 0.3 0.3 Site I Pig Launcher Harrison County, WV PSS/PEM <0. 1 /0. 1 <0.1/0 I ACPTOTAL 3.0 0.4 SUPPLY HEADER PROJECT JB Tonkin Compressor Station Westmoreland County, PA PEM <0.1 <0.1 Mockingbird Hill Compressor Station Wetzel County, WV PFO/PEM <0. 1/<O. 1 0.0 Marts Junction Pig Receiver Harrison County, WV PEM 0.1 0.1 SHPTOTAL 0.2 0.1 a Wetland types according to Cowardin et al. (1979) - PFO palustrine forested PEM palustrine emergent 2-48 I �J Resource Report 2 2.3.4.3 Access Roads Water Use and Quality Atlantic and DTI have worked to identify existing roads to the maximum extent feasible for use as access roads during project construction and operation. Approximately 87 percent of the access roads identified at the time of filing are located on existing roads (private and/or public). Approximately 7 percent of access roads are extensions of existing roads and approximately 6 percent are new roads proposed where insufficient access is provided through existing roads. Improvements for access roads will be identified during the refinement phase of the Projects. Iinprovements to roads will be identified based on the need; not all roads will require improvements for full size truck and trailers. Typical improvements will involve adding gravel and grading existing roads. Those roads identified for larger trucks and trailers will be evaluated on a case-by-case basis. Based on NWI maps and field surveys, access roads for the ACP will cross a total of 20,648 feet of wetlands and will result in 14.2 acres of impacts. Access roads for the SHP Project will cross a total of 560 feet of wetlands and will result in 0.4 acre of impacts. A summary of impacts associated with access roads is included in Table 2.3.4-4. Additional information is provided in Appendix 2H. 2.3.4.4 Pipe Storage and Contractor Yards The pipe storage and contractor yards identified for the ACP and SHP will not impact wetlands. 2.3.5 Wetland Crossing Methods In general, Atlantic and DTI will minimize impacts on wetlands by following the Procedures, site-specific modifications to the Procedures requested by Atlantic and DTI and approved by the FERC, and additional requirements identified in Federal or State/Commonwealth wetland crossing permits. Atlantic and DTI will prepare a POD or COM Plan, which will identify construction procedures and mitigation measures to be implemented on federally managed lands. Atlantic and DTI will submit preliminary draft PODs or COM Plans to the Bureau of Land Management, USFS, and FWS in September 2015. Both Projects will be constructed using a 75 -foot wide construction right-of-way for pipelines where they cross wetlands, with ATWS on both sides of the upland border to stage construction equipment, fabricate the pipelines, and store materials and excavated spoil. ATWS will be located in upland areas a minimum of 50 feet from the wetland edge (with the exception of site-specific modifications requested by Atlantic and DTI and approved by the FERC; see Appendix 1E of Resource Report 1). Detailed descriptions of wetland crossing methods (e.g., the open cut and push-pull methods) are provided in Section 1.5.2.2 of Resource Report 1. These crossing methods are consistent with the requirements of the Procedures. The crossing method for each wetland during construction will depend on site-specific weather conditions, soil saturation, and soil stability. Tables 2H- I and 2H-2 in Appendix 2H identify the proposed crossing method for each wetland along the proposed ACP and SHP pipeline routes and in other work areas. 2-49 Resource Report 2 Water Use and Quality TABLE 2.3.44 Summary of Wetlands Affected by Access Road Construction for the Atlantic Coast Pipeline Cowardin Crossing Permanent Impacts Facility/State or Commonwealth County/City Classification a Length (feet) (acres) ATLANTIC COAST PIPELINE AP -1 West Virginia Lewis County PUB 184 0.1 PEM 611 0.4 Upshur County PEM 234 0.2 Randolph County PEM 592 0.3 PFO 67 <0.1 Pocahontas County PEM 331 02 PSS 0 <0. I PFO 284 0.2 West Virginia Total 2,303 1.5 Virginia Highland County PEM 37 0.1 PSS 0 <0 I Buckingham County PEM 17 <0.1 PSS 22 <0.1 PFO 840 0.6 Cumberland County PFO 32 <0.1 Brunswick County PFO 126 0.1 Greensville County PEM 210 01 PFO 661 0.5 Virginia Total 1,944 1.4 AP -2 North Carolina Halifax County PFO 1,145 0.8 Nash County PFO 110 0.1 Johnston County PEM 176 0.1 PFO 2,700 2.1 Cumberland County PFO 1,759 1.2 North Carolina Total 5,890 4.3 AP -3 North Carolina Northampton County PEM 141 0.1 PFO 20 <0. 1 North Carolina Total 161 0.1 Virginia Southampton County PEM 0 <0.1 PSS 172 0.1 PFO 1,376 0.9 City of Suffolk PFO 1,790 1.2 City of Chesapeake PEM 2,776 18 PSS 0 <0 1 2-50 Q Resource Report 2 Water Use and Quality TABLE 2.3 4-4 (cont'd) Summary of Wetlands Affected by Access Road Construction for the Atlantic Coast Pipeline Cowardin Crossing Permanent impacts Facihty/State or Commonwealth County/City Classification Length (feet) (acres) PFO 4,184 2.8 Virginia Total 10,298 6.9 AP -5 Virginia Greensville County PFO 52 <0.1 Virginia Total 52 <0.1 ACP PROJECT TOTAL 20,648 14.2 SUPPLY HEADER PROJECT TL -635 Access Roads West Virginia Doddridge, County PFO 76 <0.1 Wetzel, County PEM 372 0.3 West Virginia Total 448 0.3 TL -636 Access Roads Pennsylvania Westmoreland, County PFO 65 <0.1 PEM 47 <0.1 SHP PROJECT TOTAL 560 0.4 a Wetland types according to Cowardin et al. (1979): PFO = palustrine forested PSS = palustrine scrub -shrub PEM = palustrine emergent PUB = palustrine unconsolidated bottom Notes: The totals shown in this table may not equal the sum of addends due to rounding. The area of impact for wetlands along access roads was based on the crossing length of wetlands and an assumed width of 30 feet for each access road Horizontal Directional Drill Several wetlands will be crossed as part of the proposed HDD river crossing discussed in Section 2.2.8 above. Utilization of the HDD method in these areas would avoid direct impacts on 3.9 acres of wetland, including 2.5 acres of PFO, 0.2 acre of PSS, and 1.2 acres of PEM wetlands. Blasting Blasting may be necessary along portions of the proposed ACP and SHP pipeline routes where bedrock is located at or near the ground surface (see Section 6.2 of Resource Report 6). As noted above, Atlantic and DTI have prepared and will implement a Blasting Plan which identifies procedures for the use, storage, and transportation of explosives consistent with safety requirements defined by Federal, State/Commonwealth, and local agency regulations. The Blasting Plan is provided in Appendix IF of Resource Report 1. 2.3.6 Wetland Impacts and Mitigation Construction activities can affect wetlands in several ways. Clearing and grading of wetlands, trenching, backfilling, and trench dewatering can affect wetlands through the alteration 2-51 Resource Report 2 Water Use and Quality of wetland vegetation and hydrology; loss or change to wildlife habitat (see Section 3.3.1.2 in Resource Report 3); erosion and sedimentation; and accidental spills of fuels and lubricants. Atlantic and DTI will minimize impacts on wetlands by following the wetland construction and restoration guidelines contained in the Plan and Procedures. The proposed wetland mitigation measures are intended to avoid wetland impacts to the greatest extent practicable; minimize the area and duration of disturbance; reduce soil disturbance; and enhance wetland revegetation after construction. Some of the measures proposed include: limiting the construction right-of-way width to 75 -feet through wetlands (unless alternative, site-specific measures are requested by Atlantic and DTI and approved by the FERC and other applicable agencies); locating ATWS at least 50 feet away from wetland boundaries (unless alternative, site-specific measures are requested by Atlantic and DTI and approved by the FERC and other applicable agencies); limiting the operation of construction equipment within wetlands to only equipment essential for clearing, excavation, pipe installation, backfilling, and restoration; preventing the compaction and ratting of wetland soils by operating equipment off of equipment mats or timber riprap in wetlands that are not excessively saturated; restricting grading in wetlands to the area directly over the trenchline, except where necessary to provide necessary safety; installing trench breakers or trench plugs at the boundaries of wetlands to prevent draining of wetlands; segregating topsoil from the trench in non -saturated wetlands and returning topsoil to its original location during backfilling to avoid changes in the subsurface hydrology and to promote re-establishment of the original plant community by replacing the seed bank found in the topsoil; installing temporary and permanent erosion and sediment control devices, and re- establishing vegetation on adjacent upland areas, to avoid erosion and sedimentation into wetlands; removing woody stumps only from areas directly above the trenchline, or where they will create a safety hazard, to facilitate the re-establishment of woody species by existing root structures; returning graded areas to their preconstruction contours to the greatest extent practicable, and returning excavated soil from the trench within the wetlands back to their original soil horizon to maintain hydrologic characteristics; prohibiting the storage of chemicals, fuels, hazardous materials, and lubricating oils within 100 feet of a wetland; 2-52 Resource Report 2 Water Use and Quality prohibiting parking and/or fueling of equipment within 100 feet of a wetland; unless the Environmental Inspector determines there is no reasonable alternative, and appropriate steps (such as secondary containment structure) are taken; dewatering the trench at a controlled rate into an energy dissipation/sediment filtration device, such as a geotextile filter bag or properly installed straw bale structure, to minimize the potential for erosion and sedimentation; preventing the invasion or spread of undesirable exotic vegetation as described in the Invasive Plant Species Management Plan (see Appendix IF of Resource Report 1); limiting post -construction maintenance of vegetation to removal of trees with roots that could compromise the integrity of the pipeline within 15 feet of the pipeline centerline, and the maintenance of a I 0 -foot wide corridor centered over the pipeline as herbaceous vegetation; and annual monitoring of the success of wetland revegetation following construction until wetland revegetation is successful. Restoration/revegetation of wetlands will be considered successful when the affected wetland satisfies the Federal definition of a wetland (i.e., soils, hydrology, and vegetation); the vegetation is at least 80 percent of the cover documented for the wetland prior to construction, or at least 80 percent of the cover in adjacent, undisturbed areas of the wetland; or the plant species composition is consistent with early successional wetland plant communities in the affected ecoregion (if natural rather than active revegetation is used); and invasive plant species are absent, unless they are abundant in adjacent areas that were not disturbed by construction. Applicable regional conditions associate with USACE permitting will also be complied with as they pertain to revegetation and monitoring requirements. Atlantic and DTI have evaluated numerous major route alternatives (greater than 5 miles in length), route variations (I to 5 miles in length) and minor route adjustments to optimize the baseline route as a result of ongoing routing, biological, cultural resources, and civil field surveys. The primary criterion for comparing major route alternatives and route variations to the baseline route was cumulative impact avoidance relative to the objective of the route alternative or variation. The route adjustments were adopted without a formal alternatives analysis, but the need for the adjustment was intuitive and practical (e.g., a slight shift in the centerline to avoid a wetland). Individually, the adjustments to the routes are small, but collectively they reduce impacts on environmental resources. Resource Report 10 documents the results of these routing alternatives, variations, and adjustments. In addition to the route alternatives, variations, and adjustments, Atlantic and DTI continue to optimize the route at a localized scale to further minimize impacts on wetlands and waterbodies where feasible. 2.3.6.1 Wetland Vegetation The alteration of wetland vegetation is the primary impact of pipeline construction and right-of-way maintenance activities on wetlands. Most impacts associated with construction activities are considered temporary, but long-term impacts on wetland vegetation may occur depending on the time required for reestablishment of wetland functions associated with 2-53 Resource Report 2 Water Use and Quality vegetation cover. Impacts on herbaceous wetlands (PEM) will be temporary as vegetation is expected to fully regenerate within one to three years. Impacts on PSS wetlands will take longer to reestablish to preconstruction conditions and may take five or more years depending on the age and complexity of the system. The impacts on PFO wetlands will be long-term due to the length of time required for a forest community to regenerate. However, many wetland functions such as surface water detention, nutrient recycling, particle retention, and some wildlife habitat will be restored prior to the full regeneration of the forest. Where necessary, wetlands will be planted with native vegetation and/or seeded with predetermined seed mixes (approved by the appropriate agencies) to promote the reestablishment of wetland vegetation. Atlantic and DTI will also restore wetlands according the conditions of applicable pen -nits, including the specific regional conditions specific to restoration and revegetation within each of the USACE Districts. An Invasive Plant Species Management Plan (see Appendix IF o ' f Resource Report 1) will be implemented to reduce and control the spread of invasive non-native species in the Project areas, including wetlands. Conversion of forested wetlands will be mitigated through compensatory mitigation as discussed in Section 2.3.7 below. Loss of forested cover and fragmentation concerns raised by the EPA are address in detail within Resource Report 3. Following pipeline construction, Atlantic and DTI will periodically remove woody species from wetlands to facilitate post -construction monitoring and inspections of the maintained pipeline right-of-way. In accordance with the Plan and Procedures, Atlantic and DTI will maintain a 1 0 -foot wide corridor centered over the pipeline in an herbaceous condition. Additionally, woody species within 15 feet of the pipeline with roots that could compromise the integrity of the pipeline will be removed. These maintenance activities will not allow PSS and PFO wetlands to fully reestablish within the maintained right-of-way, which will alter these wetlands by changing their structure and function. Based on a combination of field survey data and NWI data, approximately 204.4 acres of PFO and PSS wetlands will be converted to herbaceous wetlands by the ACP and less than approximately 0.3 acre of PFO and PSS wetlands will be converted to herbaceous wetlands by the SHP. In order to reduce impacts on wetlands, Atlantic and DTI will make minor route adjustments, where practicable, based on the results of biological field surveys to minimize or avoid impacts on wetlands. Additionally, as discussed above, Atlantic and DTI will reduce the construction right-of-way to 75 -feet in wetlands and will cross some wetlands using the HDD crossing method. Atlantic and DTI will allow the majority of wetlands impacted during construction to return to their preconstruction condition as described above. In addition, Atlantic and DTI will review vegetative contr ' ol measures at all collocation areas and ensure that restored areas will not be impacted by spraying activity. 2.3.6.2 Compaction and Topsoil Mixing During construction, heavy machinery used for construction and transport of pipe sections can cause compaction and rutting of soils. Soil compaction can inhibit seed germination and increase the potential for runoff and siltation. To reduce the risk of compaction and rutting, construction equipment will work off of equipment mats or timber riprap in wetlands that are not excessively saturated. 2-54 Resource Report 2 Water Use and Quality Topsoil mixing in non -saturated wetlands without construction mats can result in the mixing of topsoil with subsoil where topsoil is not segregated (topsoil is only segregated over the trenchline). This can result in changes to biological activities and chemical conditions in the wetland soils. Mixing of soil layers can also impede the reestablishment and natural recruitment of native vegetation following restoration. To reduce mixing in unsaturated wetlands, topsoil will be removed from the trench, segregated, and stored within the wetland adjacent to the trench. Upon completion of the work, subsoil will be returned to the trench, followed by topsoil. 2.3.6.3 Wetland Hydrology The type and quality of a wetland may change if permanent surface and/or subsurface hydrology alterations occur due to construction activities. To minimize impacts on wetlands from changes in surface hydrology, disturbed areas will be returned to their preconstruction elevations and contours. To minimize impacts on subsurface hydrology in unsaturated wetlands, subsoil will be backfilled first, followed by topsoil. Where necessary, trench plugs will also be installed at the wetland/upland interface to maintain wetland hydrology. 2.3.6.4 Erosion and Sediment Control The clearing of the construction right-of-way adjacent to and within -a wetland, and grading in adjacent upland areas, can cause erosion of soil and the deposition of sediment into the wetland. Compaction of soil by construction equipment can affect runoff and may contribute to more erosion and sedimentation. To minimize impacts during clearing activities, Atlantic and DTI will cut the existing wetland vegetation to ground level, leaving existing root systems intact. Erosion and soil compaction will be minimized by the use of timber mats, timber riprap, or straw mats within a wetland, if wetland soils are not excessively saturated at the time of construction and can support construction equipment. Erosion will further be minimized by the installation of temporary erosion control devices, according to the Plan and Procedures and stormwater pennitting requirements, between the upland construction areas and the wetland to limit the potential for soil to leave the right-of-way or enter a wetland. hi addition, permanent erosion controls will be installed, such as slope breakers, to aid long-term stabilization along with the restored vegetation adjacent to wetlands. Additional details regarding restoration of upland vegetation adjacent to wetlands on USFS lands are provided in Resource Report 3. 18 When excavating the trench, trench spoil will be placed a minimum of 50 feet away from wetland boundaries wherever possible. If dewatering of the trench is necessary, silt -laden trench water will be discharged into an energy dissipation/sedimentation filtration device, such as a geotextile filter bag or straw bale structure, to minimize the potential for erosion and sedimentation. Dewatering structures will be removed as soon as practicable after completion of dewatering activities. In comments filed with the FERC, the USFS expressed concerns about sedimentation to streams due to exposed slopes subsequent to construction. 2-55 Resource Report 2 Water Use and Quality 2.3.6.5 Hazardous Material Spills The use of heavy equipment to complete pipeline installation across wetlands increases the potential for accidental releases of fuels, lubricants, and coolants. The accidental release of these materials could contaminate wetland soils and vegetation. Atlantic and DTI will minimize the potential impact of spills of hazardous materials by adhering to the SPCC Plan (see Appendix 1F of Resource Report 1). Some examples of preventive measures include regular inspection of storage areas for leaks, replacement of deteriorating containers, and construction of containment systems around hazardous liquids storage facilities. The SPCC Plan also will restrict refueling or other liquid transfer areas within 100 feet of wetlands. 2.3.6.6 Blasting Resource Report 6 identifies areas along the proposed pipeline routes where hard shallow bedrock is anticipated and blasting could be required. Where bedrock is encountered in wetland trenches, the type of bedrock will determine the method of excavation. Blasting could impact wetlands by causing a fissure in the rock that would drain the wetland. Blasting could also result in a wetland conversion through the introduction of a new water source. Wetlands will be monitored after blasting to determine that no fissures are created. Impacts on wetlands due to blasting will be addressed as part of the compensatory mitigation for the Projects. 2.3.6.7 Permanent Wetland Fill In some cases, construction of aboveground facilities and access roads will require the permanent filling of wetlands. A total of 0.5 acres of wetlands will be filled for construction of aboveground facilities and 14.5 acres of impacts will be required for construction of access roads. Where permanent impacts are required, Atlantic and Dominion will comply with all applicable Federal and State/Commonwealth pen -nit requirements. 2.3.7 Compensatory Mitigation Atlantic and DT1 will prepare a compensatory wetland mitigation plan for impacts on each single and complete crossing of Waters of the U.S. and Waters of the State for the Projects with assistance from each of the USACE District offices. Ratios for unavoidable impacts to Waters of the U.S. and Waters of the State will be determined by the USACE and applied as necessary to calculate the amount of compensatory mitigation credits needed to compensate for both forested and shrub wetlands conversions and permanent losses of Waters of the U.S. Where available, mitigation bank credits will be utilized to mitigate impacts as a preferred option. In the event that mitigation bank credits are unavailable for purchase, or to make up the balance of credits needed, participation in an In -lieu Fee Program will be used to satisfy remaining compensatory mitigation requirements. 2-56