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Home My WebLink About19940203 Ver 1_Complete File_19950613COMPENSATORY MITIGATION PLAN N.C. DEPARTMENT OF TRANSPORTATION US 17 WIDENING, EDENTON TO HERTFORD TRAFFIC IMPROVEMENT PROJECT (TIP): R-2208A CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA Prepared for: The North Carolina Department of Transportation Raleigh, North Carolina Prepared by: Environmental Services, Inc. 1318 Dale Street, Suite 220 Raleigh, North Carolina 27605 APRIL 1995 State of North Carolina Department of Environment, Health and Natural Resources r4**A Division of Environmental Management James B. Hunt, Jr., Governor E H N Jonathan B. Howes, , Secretary A. Preston Howard, Jr., P.E., Director June 13, 1995 Mr. H. Franklin Vick, P.E., Manager Planning and Environmental Branch NCDOT-Division of Highways P.O. Box 25201 Raleigh, NC 27611-5201 Dear Mr. Vick: Subject: Certification for U.S. 17 Widening, Edenton to Hertford DEM Project # 94203, TIP # R-2208A Chowan and Perquimans Counties The purpose of this letter is to clarify Condition 2 of Water Quality Certification # 2998 which was issued for the subject project on May 25, 1995. The intent of Condition 2 was to acknowledge that there are sufficient credits in the proposed Dismal Swamp Mitigation Bank as described in the mitigation proposal dated April, 1995 to compensate for the loss of 21.76 acres of wetlands impact associated with the subject project. The Division has not made a determination of the number of credits that exist in the proposed bank nor the number of credits that will be debited for the subject project. The Division will submit comments on the mitigation proposal by June 23, 1995. The determination of the number of credits in the bank and the number or credits to be debited for the subject project will be coordinated with the U.S. Army Corps of Engineers and other review agencies. If you have any questions concerning this matter please contact Mr. Ron Ferrell at 919- 733-0026. Sincerely, Jo .ney cc: Ron Ferrell Gordon Cashion Corps of Engineers, Washington Field Office P.O. Box 29535, Raleigh, North Carolina 27626-0535 Telephone 919-733-7015 FAX 919-733-2496 An Equal Opportunity Affirmative Action Employer 50% recycled/ 10% post-consumer paper hJC DDI Wu EVNSCI Fax :919-777-9959 Jun 95 9 P. 02'x`02 NORTH CAROLINA Perguimans, Hertford and Chowan Counties CERTIFICATION THIS CERTIFICATION is issued in conformity with the requirements of Section 401 Public Laws 92-500 and 95-217 of the United States and subject to the North -Carolina Division of Environmental Management Regulations in 15 NCAC 2H, Section .0500 to N.C. Department of Transportation resulting in 21.76 acres of wetland impact pursuant to an application filed on the 3rd day of March, 1994 and 15 May 1995 to widen US 17 from Hertford to Edenton. The Application provides adequate assurance that the discharge of fill material into the waters of Burnt Mill. Bethel and Raccoon Creeks in conjunction with the proposed road improvement will not result in a violation of applicable Water Quality Standards and discharge guidelines. Therefore, the State of North Carolina certifies that this activity will not violate Sections 301, 302, 303, 306, 307 of PL 9?-S00 and PL 95-217 if conducted in accordance with the application and conditions hereinafter set forth. Condition(s) of Certification: That the activity be conducted in such a manner as to prevent significant increase in turbidity outside the area of construction or construction related discharge (SO NTUs in streams and rivers not designated as trout waters by DEM; 25 NTUs in all saltwater classes, and all lakes and reservoirs; 10 NTUs in trout waters). 2_ Compensatory mitigation for impacts to these wetlands will be accomplished by the restoration or approximately 483 acres of prior converted wetlands as described in the draft compensatory mitigation plan for the Dismal Swamp Mitigation site in Gates and Perquimans Counties dated April 1995 and as amended in the final plan. The final plan, as-built reports and all monitoring reports shall be submitted in duplicate to the Division of Environmental Management at the time of submittal to the US Army Corps of Engineers. Violations of any condition herein set forth shall result in revocation of this Certification. This Certification shall become null and void unless the above conditions are made conditions of the Federal 404 and/or Coastal Area Management Act Permit. This Certification shall expire upon expiration of the 404 or CAMA permit. If this Certification is unacceptable to you, you have the right to an adjudicatory hearing upon written request within sixty (60) days following receipt of this Certification. This request must be in the form of a written petition conforming to Chapter 150B of the North Carolina General Statutes and filed with the Office of Administrative Hearings, P.O. Box 27447, Raleigh, N.C. 27611-7447. Unless such demands are made, this Certification shall be final and binding. This the 25th day of May, 1995. ONMENTAL MANAGEMENT WQC# 2998 NC DELI WO ENVSCI Fax: 919-X15:;-99 9 Jun r '95 9:6-) F. u1/U2 State of North Carolina Department of Environment, Health and Natural Resources / • • Division of Environmental Management James B. Hunt, Jr., Governor p Jonathan B. Howes, Secretary F1. A. Preston Howard, Jr., P.E., Director Mr. Barney O'Quinn Planning and Environmental Branch N.C. Department of Transportation P.O. BOX 25201 Raleigh, N.C. 27611-5201 May 25, 1995 Post-it' Fax Note 7671 Date Ipages To ? From Co.roePC. Ca. Phone x Phone n -7 Fax it Fax 8 Dear Mr. O'Quinn: Subject: Certification Pursuant to Section 401 of the Federal Clean Water Act, Proposed widening of US 17 from Hertford to Edenton project # 94203, COE # 199401492, TIP # R-2209A, State Project No. 6.039001T Perquimans, Hertford and Chowan Counties Attached hereto is a copy of Certification No. 2998 issued to N.C. Department of Transportation dated 25 May 1995. If we can be of further assistance, do not hesitate to contact us. Attachments 2998.1tr Sin re , eston Howard, Jr. cc: Wilmington District Corps of Engineers Corps of Engineers Washington Field Office Washington DEM Regional Office Mr. John Dorney Mr. John Parker, Division of Coastal Management Central Files P.O. Box 29535, Rdelgh, North Carolina 27626-0535 Telephone 919-733-7015 FAX 919-733-2496 An Equal opportunely Affirmative Action Employer 50% recycled/ 10% post-c onsumer paper i l ! s, fic, W Cr Guo?? _ZZ ' St its- ? if- -_ _--- -_--------?-_- ?---?____._.? ?__?-------?_-__?------sue -- ----.____?-____---- l ------ f cri I G f. i t P--A-- ---- ?1?? _p l?dZ oGY. -d _1 s__ Az / 3/" M?oNU Z i i Sys ?, "J?l?S __..______.____.___._,__.__._..___.__._._??__..___.__ _____...a...___.... ? __,_?__._.?._.___.?_._,.._,m...?...__.?.._.?,,.w,........... `` _.?_..____.. .?: ,; - - - £,' li _ ___. ._.__ _? ?-_- .__..._________..,.._._._ - ___.?..._.w. ,?_...??_?.___.__.._. - ,. ._._,___v_.?___.?_ ___.__..._?.... ,_w._,..?__,____,..?, - - __.t.w.,.??.M....m...?..._...___._._ _____. .._..a? _._.?__, .._.._..?..._._..,.,_.._._.?.._?.,_.r._.,._.____...._.N.?,._?.____._.._.??,.?.._ ?! - . ? ;,+ .. .? ., ?. r_-_? ?....__,_._?.? _._.?._w .?,._r t ?., tf atti r p Cu,r STATE OF NORTH CAROLINA DEPARTMENT OF TRANSPORTATION JAMES B. HUNT, JR. DIVISION OF HIGHWAYS GOVERNOR P.O. BOX 25201, RALEIGH. N.C. 27611-5201 April 24, 1995 Dr. G. Wayne Wright Chief, Regulatory Branch Department of the Army Wilmington District, Corps of Engineers Post Office Box 1890 Wilmington, North Carolina 28402-1890 Dear Dr. Wright: R. SAMUEL HUNT III SECRETARY SUBJECT: Dismal Swamp Mitigation Site, Gates and Perquimans Counties, TIP No. R-2208A, State Project No. 6.039001T, Widening of U. S. 17, from Hertford to Edenton, Perquimans and Chowan Counties. Please find enclosed three copies of the Wetland Mitigation Plan for the Dismal Swamp Mitigation Site in Gates and Perquimans Counties. This document, which is contained in a loose-leaf binder, was prepared by for the North Carolina Department of Transportation by our consultant, Environmental Services, Inc. We are submitting this document to outline our plans for compehsatory mitigation for R-2208A, and are proposing that the impacts from R-2208A be debited from the Dismal Swamp Site. Remaining credits in the Dismal Swamp Site are anticipated as "up- front" mitigation for future projects. R-2208A will impact 2.9 acres of riverine wetlands and 8.8 acres of nonriverine/interstream wetlands. In addition, there will be impacts caused by the effects of associated ditches in wetlands adjacent to R-2208A. These latter impacts are as yet unquantified; a separate report very near completion by Environmental Services, Inc. will address these impacts and the acreage is proposed to also be debited from the Dismal Swamp Site. We request that a permit for R-2208A be issued at the earliest possible date on the strength of our permit application of February 7, 1994, the enclosed Dismal Swamp Mitigation Plan, and the NCDOT's commitment to debit appropriate acreage for all three types of impacts described above. 9 l 2 Thank you for your assistance in reviewing the work that went into the development of this plan. Sincerely,, H. Franklin Vick, P. E., Manager Planning and Environmental Branch HFV/ds Enclosures (3) cc: (with one copy of enclosure) Mr. Mike Bell, COE Mr. Lee Pelej, USEPA Mr. David Cox, NCWRC Mr. David Dell, USFWS Mr. Ron Ferrell, NCDEHNR Mr. Eric Galamb, NCDEHNR Mr. Ron Sechler, NMFS Mr. N. L. Graf, P. E., FHWA; Attn.: Mr. Roy Shelton Mr. D. R. Morton, P. E., NCDOT, State Highway Engineer - Design Mr. W. D. Johnson, P. E., NCDOT, State Roadside Environmental Engineer Mr. A. L. Hankins, P. E., NCDOT, State Hydraulics Engineer COMPENSATORY MITIGATION PLAN N.C. DEPARTMENT OF TRANSPORTATION US 17 WIDENING, EDENTON TO HERTFORD TRAFFIC IMPROVEMENT PROJECT (TIP): R-2208A CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA Prepared for: The North Carolina Department of Transportation Raleigh, North Carolina Prepared by: Environmental Services, Inc. 1318 Dale Street, Suite 220 Raleigh, North Carolina 27605 APRIL 1995 11 TABLE OF CONTENTS LIST OF FIGURES .................................................. iii LIST OF TABLES .................................................. iii EXECUTIVE SUMMARY ............................................. iv 1.0 INTRODUCTION ...............................................1 2.0 RATIONALE .................................................3 3.0 AFFECTED ENVIRONMENT .......................................4 3.1 Impacted Wetlands ........................................ 4 4.0 MITIGATION GUIDELINES ........................................ 9 4.1 Mitigation Policy ......................................... 9 4.2 Mitigation Sequencing .................................... 10 5.0 MITIGATION SITE .................... 11 5.1 Project Overview ........................................ 11 5.2 Dismal Swamp Mitigation Site History ......................... 11 5.3 Existing Conditions ....................................... 14 5.3.1 Physiography, Topography, and Land Use .................. 14 5.3.2 Soils ............................................14 5.3.3 Hydrogeology ..................................... 18 5.3.4 Plant Communities .................................. 19 5.3.5 Wildlife Communities ................................ 19 5.3.6 Jurisdictional Wetlands ............................... 20 6.0 MITIGATION PLAN ............................................ 22 6.1 Wetland Restoration Modeling ............................... 22 6.1.1 Hydrological Modeling ................................ 22 6.1.2 Reference Forest Ecosystem Modeling .................... 25 6.2 Wetland Restoration Methodology ............................ 30 6.2.1 Hydrological Restoration .............................. 30 6.2.2 Plant Community Restoration ........................... 32 6.2.3 Wetland Soil Restoration .............................. 41 TABLE OF CONTENTS 7.0 MONITORING PLAN ........................................... 43 7.1 Hydrology Monitoring ..................................... 43 7.2 Hydrology Success Criteria ................................. 43 7.3 Vegetation ............................................44 7.4 Vegetation Success Criteria ................................. 44 7.5 Report Submittal ........................................ 45 7.6 Contingency ...........................................45 8.0 MITIGATION CREDIT DETERMINATION ............................. 46 8.1 Wetland Functional Evaluations .............................. 46 8.2 Mitigation Credit Determination .............................. 52 9.0 DISPENSATION OF PROPERTY ................................... 54 10.0 REFERENCES CITED ...........................................55 11.0 APPENDIX 1.1 Hydrogeological Site Assessment for the Great Dismal Swamp Mitigation Site ...................................... 46 LIST OF FIGURES Figure 1 - Site Location Map ........................................... 2 Figure 2 - Dismal Swamp Mitigation Site in relation to the Dismal Swamp National Wildlife Refuge ........................... 12 Figure 3 - Aerial Photograph, Dismal Swamp Mitigation Site .................... 13 Figure 4 - Natural Resource Conservation Service (NRCS) Dismal Swamp Mitigation Site .................................. 15 Figure 5 - Hydric/Nonhydric Soil Boundaries ............................... 17 Figure 6 - Jurisdictional Wetlands, Jurisdictional Open Waters and Prior Converted Farmland ..................:............... 21 Figure 7 - DRAINMOD - Estimated Percent of the Growing Season Wetland Hydrology will Persist ................................. 26 Figure 8 - Estimated Riverine/Floodplain Restoration Area ...................... 33 Figure 9 - Conceptual Model of Target Community Patterns .................... 34 Figure 10 - Community Restoration Map Units ............................ 35 Figure 11 - Wetland Mitigation Design Units ............................... 47 LIST OF TABLES Table 1 - Wetland Impacts by Type ...................................... 4 Table 2 - Results of DRAINMOD Simulations for Saturation within 12 inches of surface for Selected Percentages of the Growing Season (Surface Storage = 10 cm) . 24 Table 3 - Reference Forest Ecosystems, Nonriverine Swamp Forest Plots Summary (Canopy Species) ................................ 28 Table 4 - Inventory of Shrubs and Herbs in Reference Nonriverine Swamp Forests .... 29 Table 5 - Planting Regime - Dismal Swamp Mitigation Site ..................... 38 Table 6 - Expected Functions in Impacted Wetland Classes ..................... 48 COMPENSATORY MITIGATION PLAN N.C. DEPARTMENT OF TRANSPORTATION US 17 WIDENING, EDENTON TO HERTFORD TRAFFIC IMPROVEMENT PROJECT (TIP): R-2208A CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA EXECUTIVE SUMMARY The N.C. Department of Transportation (NCDOT) proposes widening of approximately 8.2 miles of US Highway 17 from immediately north of Edenton to south of Hertford, in Chowan and Perquimans Counties, North Carolina. The current two-lane roadway will be widened into a four-lane thoroughfare. Approximately 12 acres of palustrine forested wetlands may be impacted by road widening. In addition, potential indirect impacts to wetlands associated with planned ditch construction adjacent to the new roadway are currently being studied. If wetland impacts are predicted from the ditch impact study, additional impact acreages will be incorporated into this mitigation plan as a supplemental document. A wetland restoration area within the Great Dismal Swamp complex of North Carolina has been selected to provide compensatory mitigation for this project. The mitigation site encompasses approximately 612 acres of farm and forest land approximately 1.2 miles east of the town of Sandy Cross and SR 1002 (Folly Road) along the Gates County/Perquimans County line. This mitigation site provides a contiguous restoration area that is connected to an eve s Vw d ref fge d r# ?t t r ;• This document is targeted towards outlining a plan for compensation of wetlands impacted as a result of construction. However, additional mitigation credit' generated by the project will serve:as-an-NCD07 regional wetland mitigation bank. A number of wetland restoration studies and models were performed to ensure success in wetland restoration efforts. Models include site hydrogeological modeling, generation of an available water budget, reference forest ecosystem characterizations, analyses of soil-site relations, and a subjective wetland functional assessment using hydrogeomorphic (HGM) parameters (Brinson 1993, ESI 1994a, ESI 1994b). Hydrological restoration and community restoration designs and procedures are outlined in detail with monitoring plans, success criteria, and reporting programs clearly defined in order to promote wetland restoration success. IV The Dismal Swamp bank site includes approximately 428:<acreFl of etland-,restofatior within prior converted farmlands. Of this 428 acres, approximately 3,4, ,y will occur within a former floodplain area situated behind a large dike on the property. The floodplain area to be restored comprises part of a historical stream corridor that constitutes channelized upper reaches of the Perquimans River. An additionallom -riverin4'A'inrad enhancement will be facilitated through restoration of overbank flooding within forested wetlands on the mitigation site. Two upland ridges/knolls totaling approximately 12 acres will also be restored to promote establishment of coastal fringe sandhill forest communities. These upland restoration areas provide the opportunity to create eland/wetla d ecotones whi C1 are con'sWe--wd, amo k',M-est-.div0se and p dive 2 ei i i lii a9 ',for wildlife (Brinson et a/. 1981). Other components of the mitigation plan include the establishment of fsledwa>ffers adjacent to perimeter canals outside of the mitigation property 4 res? 'and pne "'I anagement of forested remnants on the acres). Proposed improvements to the subject segment of US 17 (R-2208A) will impact approximately 12 acres of wetlands within the same wetland classes as the mitigation site. Based on the mitigation strategy, modeling results, wetland functional evaluations, and current research, this mitigation project will provide adequate compensatory mitigation credit for wetland impacts associated with US 17 widening. Substantial mitigation credit remains from wetland mitigation activities for projects in the region which impact wetlands of comparable function. t-m-itisamiewn - it' credit -units for use as a. regional mitigation- bank-,will-.be determh- e`d' dtiting deutlephitft1 "bf mitigation bank protocol and debiting procedures. t N tlAw'LahQNF 3I4 _ ;LL?E*Anl'E 94 - L c veLk"'rt s i- 'te- v COMPENSATORY MITIGATION PLAN N.C. DEPARTMENT OF TRANSPORTATION US 17 WIDENING, EDENTON TO HERTFORD TRAFFIC IMPROVEMENT PROJECT (TIP): R-2208A CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA 1.0 INTRODUCTION North Carolina General Assembly House Bill 399, ratified in 1989, provides for the establishment of the North Carolina Highway Trust Fund. Portions of the Highway Trust Fund are allocated to the intrastate system. This system was established to provided free-flowing, safe inter-city travel for motorists, and to support statewide growth and development objectives. The General Assembly recognized the importance of US Highway 17 (hereafter US 17) to travel and economic development along the coast of eastern North Carolina, and included this route in the intrastate system. As part of the North Carolina Department of Transportation (NCDOT) Intrastate Corridor Program, over 250 miles of a multi-laned US 17 will extend from the South Carolina border to Virginia. NCDOT proposes to widen an 8.2 mile segment of US 17 in Chowan and Perquimans County from Business 17 north of Edenton to Business 17 south of Hertford (Figure 1). Proposed improvements will be accomplished by constructing a new two-lane section immediately adjacent to the existing roadway. The environmental impacts of this project were studied in a State Environmental Assessment (dated 4/25/91) and a Finding of No Significant Impact (dated 1/6/92). These documents evaluated several alternatives, including a no-build option, widening to the north, widening to the south, and new location alternatives. Subsequently, the preferred alternative was selected to avoid and minimize wetland impacts while ensuring travel safety. This report examines the wetland encroachment and mitigation strategy for dealing with anticipated wetland losses associated with development of R-2208A. Information contained in this report is intended to supplement and support NCDOT's Section 404 permit application and request for 401 Water Quality Certification. The Section 404 permit application was submitted on February 7, 1994. This mitigation plan outlines a method to replace wetland functions lost as a result of road widening, through compensatory mitigation. 1 r Dismal Swamp L Mitigation Site • 32 poY r `: ? .d. .w. aw+ ?- ??' € ' ;/A?_ \?p I r i I ? P F F a'4-. , % 37 _?a - ? rr d a •? o ° F 37 S - -•ecd ? "--- a 4' l i d 8 4 0 I ! , ? a _ ` F. /' 4? ; ? - r ? e rrra, 'I _ - 37 it ? ? I ? Cia •? aF. '? ?.9 ` . ?e ; O _ ! .? •a b?? Ewa' ?' 4 I t ,f qty .•>F I \C• -, - , • V •4, ?.?1 ypA, 1, /eYi:`l'Y:1%;• .°S. o I \ J4 `I. , C 1 •" ar.,y 'y H pnr av? I Y ,, ? • -u+u ' I I_ 7 1 ?? s ? ? 4 a' / -1 pl "'nOi'd`F?/,° ..?''tir'°° r 1? . ? ?\4 US 17 Edenton to Hertford (R-2208A b 7 y\ MYCyF;4{. • Fp ,?? 1 ? ° Ise=,.??•? ?? ° r Il? cr •e? ? -ba`j'•?uia'%•-.x'r; ?? ?r? _c? • I ``_} !: , - \??,'q'-war„ f © D,,L a 18 324y.?(1 1 £ g • \?a I(\\\ f °4 ?... or+p ,y' . . 1 ? 11 "•y ? ' • \?._m..- .u r H.IIy ''?. , a'e R 4- -`, rl '? r I -?I .LR?'L.,;;? `.. p 1.. 2 3 MILES b Edento '? ?- """o" . d y:f. - / • '.I ,pe'•• ' ; ji Y c"'° ^ ° ro"'.? source: DeLorme Mappl?9r 1993 •R0. M1roHat r4 i- • ?' ?f? ? $ ? r' ara ? `\ >aYw I ' a"d'Y I J 77 P\ a\ Environmental Site Location Figure: 1 ?' s US 17 Edenton to Hertford, Se Inr- (R-2208A), and 8ce Street I Selected Mitigation Site Project: ER94018.7 IL Suite 220 Gates, Perquimans, and Raleigh, NC 27605 Chowan Counties, NC Date: 5 April 1995 7 2.0 RATIONALE Section 404 of the Clean Water Act (CWA) requires regulation of discharges into "waters of the United States." Although the principal administrative agency of the CWA is the U.S. Environmental Protection Agency (EPA), the U.S. Army Corps of Engineers (COE) has major responsibilities for implementation, permitting, and enforcement of provisions of the CWA. The COE regulatory program is defined in 33 CFR 320-330. Water bodies such as rivers, lakes, and streams are subject to jurisdictional consideration under the Section 404 program. However, by regulation, wetlands are also considered "waters of the United States" (33 CFR 328.3). Wetlands are described as: those areas that are inundated or saturated by 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. Wetlands generally include swamps, marshes, bogs, and similar areas (33 CFR 328.3(b), (1986)). The COE requires the presence of three parameters (hydrophytic vegetation, hydric soils, and evidence of hydrology) in support of a jurisdictional determination (DOA 1987). Wetlands within the project corridor were initially mapped and classified in the spring of 1990 by NCDOT personnel as part of the State Environmental Assessment process. Wetlands were identified based upon parameters outlined in the "Federal Manual for Identifying - and Delineating Jurisdictional Wetlands (89 Manual)"(FICWD 1989). Subsequently, wetlands were revisited in 1992 by NCDOT personnel to conform jurisdictional mapping to wetland parameters enumerated in the "Corps of Engineers Wetland Delineation Manual (87 Manual)" (DOA 1987). Wetlands were classified using the U.S. Fish and Wildlife Service (USFWS) manual, Classification of Wetlands and Deegwater Habitats of the United States" (Cowardin et a/. 1979), and current trends in the classification system. A Section 404 permit application for this project was submitted to the Wilmington District Corps of Engineers on February 7, 1994. Design specifications and avoidance/minimization issues were addressed in this permit application and in the State Environmental Assessment (EA). Subsequently, this compensatory mitigation strategy has been developed to provide compensation for impacts to unavoidable wetland resources. 3 3.0 AFFECTED ENVIRONMENT 3,1 Impacted Wetlands Approximately 12 acres of wetlands may be directly impacted by US 17 widening. Potential indirect impacts to wetlands associated with planned ditch construction adjacent to the new roadway are currently being studied. If indirect wetland impacts are predicted from the ditch impact analysis, additional impact acreages will be incorporated into this plan as a supplemental document. Wetland types within the project corridor have been grouped into riverine/bottomland wetlands and nonriverine/interstream wetlands for descriptive purposes. Wetland types and associated acreage within the construction limits are listed in Table 1. TABLE 1: Wetland Impacts by Type Palustrine forested Palustrine forested Palustrine forested needle-leaved evergreen broad-leaved deciduous/ broad-leaved deciduous/ Wetland temporarily flooded (needle-leaved evergreen) (needle-leaved deciduous) Type ditched and bedded temporarily flooded seasonally flooded TOTAL PF04Ad PF01 A (PF01 /4A) PFO1 C (PFO1 /2C) Nonriverine/Interstream Nonriverine/Interatream Rivedne/Bottomiand Area Impacted 3.3 5.5 2.9 11.702) (Acres) Although Wt}uantitative methodology was, employed. to .determine functional values of „m- s, general wetland functions were evaluated based on best professional judgement using parameters described in hydrogeomorphic (HGM) functional assessment technology (Brinson 1993, ESI 1994b). A summary of HGM functions and functional performance variables considered is presented in Section 8 (Mitigation Credit Determination). Wetland functions are subdivided into hydrodynamic, biogeochemical, and biotic components for descriptive purposes. The following wetland types have been identified: Palustrine forested, broad-leaved deciduous/(needle-leaved evergreen), temporarily flooded wetlands (PF01 A, (PF01 /4A)) Impacts to npnriverine pine/hardwooW-.,fdfeeted-wetlands;4,5z.5-eefes) represent a majority of wetland impacts associated with widening of US 17. For descriptive purposes, interstream wetland types include all nonriverine wet hardwood forests and wet hardwood/pine mixed forest intergrades. These wetlands are positioned along the center of interstream tracts which 4 are temporarily saturated or inundated during early portions of the growing season. Interstream wetlands are typically fragmented within farmed landscapes or road networks and exhibit negligible forest connectivity with riverine/bottomland corridors. Interstream wetlands exhibit indications of long-term disturbance such as antecedent farming, affected hydrology, or systematic logging. Included within this wetland class is minimal acreage of palustrine, shrub scrub, broad leaved deciduous/needle-leaved evergreen, temporarily flooded wetlands (PSS1 /4A). This community represents woodland or pine plantation which has been clear cut in the last 10 years. Due to limited impact acreage, PSS1 /4A wetlands do not warrant separation as a distinct wetland type. S ithin interstream wetlands include th ans (Typic Ochraquults), Portsmouth sms (Typic umbraquults), and Fanpke (Typic Ochraquults) series (USDA 1986). These soils are nearly level, poorly drained, with the seasonal high water table at or near the surface. Silty clays of limited permeability lie a few inches to a few feet below the ground surface. Relatively low permeability of subsoils may contribute to the presence of wetland hydrology in these areas. When drained, these soils are well suited for agriculture. Dominant tree species occurring within these interstream communities include water oak (Quercus nigra), willow oak (Quercus phe/%s.), swamp chestnut oak (Quercus michauxii), laurel oak (Quercus laurifolia), sweet gum (Liquidambar styraciflua), black gum (Nyssa bif/ora), and loblolly pine Onus taeda?. Swamp red bay (Persea palustris), sweet bay (Magnolia virginiana), U L red maple (Acer rubrum), and sweet pepperbush (Clethra alnifolia) are common understory/shrub components. Characteristic ground cover species include partridge berry (Mitchella repens), switch cane (Arundinaria gigantea), netted chain fern (Woodwardia areolata), false nettle (Boehmeria cylindrica), and infrequent dog hobble (Leucothoe axillaris). Nonriverine forested wetlands, when compared to riverine systems, appear to exhibit relatively low value for performance of most physical wetland functions. Expected physical functions dra 9' ? i t itian of° include long-t?ertri water storage during periods' of grou?Wr graun-d tPa `flow/movement within the watershed, and attenuation ofi Surface runoff into streams a ':agricultural (slppe) areas of lower landscape ;position (Adamus et al. 1991). Because these wetland functions occur primarily below ground surface, indirect visual observations of functional performance are required. For instance, the presence of natural, first order stream corridors extending from interstream wetlands towards bottomland systems would indicate that near surface groundwater is serving to recharge larger bottomland systems in downstream areas. Conversion of these surface water outlets into inter-field ditches alters the effectiveness of interstream wetlands to attenuate stream recharge in the lower 5 watershed. In essence, relatively undisturbed (reference) nonriverine wetlands often act as "sumps" or collectors of rainfall and possibly groundwater. Stored water is then released in moderation through subsurface flow or first order stream flow towards downslope areas. The ability of impacted interstream wetland resources to perform physical wetland functions appears to be degraded by adjacent land use practices. Extensive ditching and fragmentation in farm fields surrounding interstream wetlands has accelerated the transport of stored water and rainfall from these interstream flats, through inter-field ditches, and into area streams. Ditching has also lowered the seasonal high water table to marginal wetland levels in some areas. Evidence of above ground hydrology within these systems is limited to isolated, very small pockets which fill with water during winter and early spring. Therefore, pith fbncti.e , ," ' ' Cream wetland areas y? b`e a_ i Oo byo Yd es r t i h are depdorested,etlar?de.iiFsval. In Chowan and Perquimans Counties, interstream wetlands often provide a large majority of remaining forested habitat for native wildlife (Adamus and Stockwell 1983). Most uplands and historical wetland areas in the region are currently farmed. Therefore, the maintenance of species distributions and abundance is dependent, in part, upon these nonriverine wetlands. Habitat value of interstream wetlands, when interspersed and connected with bottomland systems, is considered important to maintenance of characteristic wildlife guilds (USFWS 1981). No net loss of interstream wetland function and connectivity for wildlife in the region should assist in maintaining species distributions and abundance. Field evaluations suggest that the wetland fringes potentially impacted by road widening exhibit relatively low value for wildlife. These areas exhibit negligible connectivity with riverine corridors and have sustained long-term degradation from human activity. These wetland fringes immediately adjacent to the existing roadway often serve as household trash, dump areas for local residents. In addition, the wetland/roadway edge provides an ecotonal fringe that is considered common habitat throughout eastern North Carolina. As expected, road widening tends to avoid significant impacts to high value wildlife habitat in nonriverine.systems as compared to likely impacts associated with new alignment corridors. Palustrine forested, needle-leaved evergreen, temporarily flooded wetlands, ditched and bedded (PF04Ad) Approximately 3L3;_acres. of pine=plantat*o?> within partially drained wetlands may be impacted by widening of the US 17 corridor. These systems are nonriverine in function and occur along the center of interstream flats and depressional slopes. Soils consist primarily of the poorly drained Ptcq> hs ands-Roan t series. Canopy elements are composed entirely of loblolly pine. Understory elements often form an impenetrable thicket or are periodically maintained 6 through prescribed fire. Characteristic understory elements include red maple, sweet gum, switch cane, and other disturbance adapted species. These pine plantations appear to;be rna _)a ,i? lpy ,od n. The relatively short rotation (approximately 20 years) and the lack of habitat heterogeneity may diminish wildlife habitat for certain characteristic guilds. Mature wet pine stands (greater than 30 years of age), which may provide important habitat for certain species, are not located within the potential impact area. Physical and biotic wetland functions, in general, are considered similar in nature to the PF01 and PFO 1 /4A wetlands described above. Palustrine forested, broad-leaved deciduous/(needle leaved deciduous), seasonally flooded wetlands (PF01 C,( PF01 /2C)) Impacted riverine/bottomland wetlands are concentrated within the Iil kekyandmse r1(di3r=tFbutaries. Approximately 2.9 acres of bottomland wetlands may be impacted at these stream crossings. Hydric soil types occurring in these alluvial systems consist primarily of z :_silt loams (Thapto-Histic F/uvaquents) (USDA 1986). These are very poorly drained, floodplain soils characteristic of small streams in the region. Character canopy species include sweet gum (Liquidambar. styraciflua), red maple (Acer rubrum), willow oak (Quercus phe/%s), laurel oak (Quercus? t laurifolia), river birch (Betula nigra), American sycamore (P/atanus occidentalis), with inclusions of bald cypress (Taxodium distichum), and tupelo gum (Nyssa aquatica). PF01 C and PF01 /2C wetlands are functionally valuable ecosystems. Because of their position in the landscape (i.e. interspersed between agricultural fields and stream channels), these bd ri raACf c unities act as major -receptorg,of, upland runoff (Cooper et aL 1986, Peterjohn and Correll 1984)). As such, important biogeochemical functions performed by floodplains which dissect agricultural regions include removal of elements=`ar?d r ds, reamo of" pa?tcpvfa ediments), and rir?CT f g (Brinson et al. 1994). Bottomiand wetlands immediately adjacent to the existing roadway are typically channelized to varying extent to improve drainage. In many cases, channelization has allowed for conversion of surrounding floodplains to agricultural land. Hydrodynamic functions within a large majority of impacted bottomland systems have been jeopardized by stream channelization, encroachment into the floodplain by agriculture, and logging impacts. The frequency and duration of overbank flooding in most bottomland impact areas has been reduced with consequent reductions in short-term and long-term surface water storage capacity. Conversion of wetland/upland ecotones for agriculture has also reduced the 7 wetlands' ability to attenuate groundwater flow or discharge and the ability to reduce the deleterious impacts of overland runoff from adjacent fields (Karr and Schlosser 1978). In addition, energy dissipation functions have been jeopardized by reductions in large woody debris from encroachment and clear-cutting along with changes in surface microtopraphy as a result of periodic timber harvests. Bottomland ecosystems provide valuable habitat for biotic resources in the region. Habitat value of bottomland forests, especially for migration and wintering species, is considered important to maintenance of characteristic wildlife guilds and migratory species. Vegetational diversity and aquatic affiliation offers all the necessary components (food, water, cover) needed to support a variety of mammals and birds. In addition, seasonal inundation provides ideal habitat opportunities for waterfowl, such as wood ducks, as well as a variety of reptiles and amphibians. Field evaluations suggest that the diversity and abundance of aquatic organisms within bottomland impact areas has been jeopardized through channelization, floodplain reduction, sediment/nutrient loading, and riparian canopy removal. However, aquatic species adapted to disturbance in stream corridors are expected to persist in these areas. A large majority of impacts to bottomland wetlands will occur in relatively degraded systems described above. However, encroachment within floodplain forests of Bethel Creek will impact limited bottomlands (:r acres) which appear to approach maximum sustainable performance for a number of wetland functions. At the 1_. cre eigbetfe.Edin:.is cotrr _ er y of pe.?o gum_With some scattered red maple. Adjacent to existing US 17 at the Bethel Creek crossing, power transmission lines parallel the roadway. These cleared easements are composed of successional vegetation including red maple, winged sumac (Rhus copaiiina), and blackberry (Rubus). Bethel Creek flows in a north/south direction, passing to the west of the town of Bethel before emptying into the Yeopim River. Near the point of discharge into the Yeopim River, Bethel Creek is under tidal influence. Coordination with the North Carolina Division of Marine Fisheries indicates the occurrence of ffo t ected :fishes,. tl a $looback : -4A4b96 ' aestivaiis) am slew fe (A%ap gus} ` within the Bethel Creek system. Both anadromous fish species are listed by the state of North Carolina as "vulnerable" (Category 3). Upstream migrations of anadromous populations take place between February 15 and May 15 of each year (pers. comm., WRC, 4/12/95). As stated in the State EA, a part of compensatory mitigation will include a construction moratorium at the Bethel Creek crossing during this period. 8 4.0 MITIGATION GUIDELINES 4.1 Mitigation Policy Mitigation for wetland losses from the proposed project is recommended in accordance with Section 404(b)(1) Guidelines of the Clean Water Act (40 CFR 230), mitigation policy mandates articulated in the COE/EPA Memorandum of Agreement (MOA; Page and Wilcher 1990), Executive Order 11990 (42 FR 26961 (1977)), FWS mitigation policy directives (46 FR 7644- 7663 (1981)), and Federal Highway Administration (FHWA) stepdown procedures (23 CFR 777.1-777.11). Mitigation has been defined in National Environmental Policy Act (NEPA) regulations to include efforts which: a) avoid; b) minimize; c) rectify; d) reduce or eliminate; or e) compensate for adverse impacts to the environment (40 CFR 1508.22 (a-e)). Section 404(b)(1) Guidelines, the COE/EPA MOA, and Executive Order 11990, stress avoidance and minimization as primary considerations for protection of "waters of the United States." Practicable alternatives must be fully evaluated before compensatory mitigation can be discussed. USFWS policy also emphasizes avoidance and minimization. However, for unavoidable losses, the FWS recommends that mitigation efforts be correlated with value and scarcity of the habitat at risk. Habitat is classified into four Resource Categories based on decreasing importance and value, with subsequent decreases in mitigation planning objectives (46 FR 7657-7658). The forested wetlands in the project corridor would be considered Resource Category 2 (riverine systems) or 3 (nonriverine systems) (high to moderate value), requiring a mitigation goal of no net loss of habitat (compensation through replacement of lost habitat function). Methods used to achieve this goal include: the physical modification of replacement habitat to convert it to the type that is lost, restoration or rehabilitation of previously altered habitat, increased management of similar replacement habitat so that in-kind value of the lost habitat is replaced, or a combination of these measures. FHWA policy stresses that all practicable measures should be taken to avoid or minimize harm to wetlands which will be affected by federally funded highway construction. A sequencing (stepdown) procedure is recommended in the event that avoidance is impossible. First, consideration must be given to providing for mitigation within highway right-of-way limits, generally through enhancement, restoration, or creation. Mitigation employed outside of the highway right-of-way must be reviewed and approved on a case-by-case basis. Measures should be designed "to reestablish, to the extent reasonable, a condition similar to that which would have existed if the project were not built" (23 CFR 777.9(b)). 9 4 .2 Mitigation Seauencina Existing policy guidelines on mitigation sequencing have been employed for this project. Measures to avoid, minimize, reduce, and eliminate wetland impacts have been employed where feasible. NCDOT's efforts at impact avoidance and minimization are more fully addressed in the February 7, 1994 permit application. Avoidance -Total avoidance is not always feasible in eliminating impacts associated with a proposed project. Road widening cannot be achieved while avoiding all wetland areas. In addition, the economic and social costs associated with a "no action" alternative are prohibitive. Current and future traffic problems are not resolved by avoiding needed improvements. Although proposed construction may impact approximately 12 acres of wetlands, every effort has been made to avoid wetland communities whenever possible. Alignment shifts to the north or south of the existing roadway were designed, in part, to avoid extensive wetland fringe areas. Minimization - Impacts on wetlands adjacent to the roadway will be minimized by implementing erosion control measures such as seeding slopes, installation of silt fences, and the proper use of sediment basins. Fill slopes through wetland areas have been steepened to the maximum practical, and lateral drainage ditches will be eliminated where feasible in order to reduce wetland impacts. Canopy removal will be restricted outside of right-of-way limits in wetland areas. Bottomland communities will not be used as staging sites. In addition, median widths have been reduced to 46 feet (14 m ) at wetland crossings, which is the minimum necessary at this location to provide adequate drainage. Compensatory mitigation is proposed for all unavoidable impacts resulting from roadway widening and improvements to the subject segment of US 17. In all cases, replacement of lost wetland functions is considered paramount. Mitigation banking - Mvtigation bankibols c?onsid"eyed an integral partof project. After debiting for R-2208A impacts, remaining credits from the Dismal Swamp site are expected to be "banked" for future use by NCDOT. Although formalization of a mitigation bank is beyond the perview of this project, this plan has been formulated under recent guidance for the use and operation of mitigation banks (60 FR 12286-12293, 1995) in order to facilitate the banking process. Mitigation banking is recognized as a potential benefit in facilitating the permit process and providing more effective mitigation for impacted wetlands. 10 5.0 MITIGATION SITE 5.1 Proaect Overview A portion of fWr *FZ amp in Gates an 1 ?ans Counties, North Carolina, has been selected for consolidation of wetland impacts from US 17 widening (R-2208A). The Dismal Swamp wetland restoration, e'eo[`=appFlttiEafi;c?f#arm and forest land approximately 1.2 miles east of the town of Sandy Cross and SR 1002 (Folly Road), along the Gates County/Perquimans County line (Figure 1). The Dismal Swamp site provides a contiguous mitigation area of relatively high potential wetland value. The Dismal Swamp wetland restoration and enhancement area will provide for full replacement of wetland function lost as a result of proposed US 17 improvements. In addition, a Dismal Swamp mitigation bank will subsequently be developed to allow for consolidation of minor wetland impacts from other roadway/bridge construction projects in the region. Mitigation banking within Dismal Swamp is considered an important means to restore prior converted wetlands of regional significance. The location of the mitigation site in relation to the Dismal Swamp National Wildlife Refuge and natural areas is depicted in Figure 2. Figure 3 illustrates a 1994 aerial photograph of the mitigation area. Environmental Services, Inc. (ESI) personnel visited the mitigation site in December 1994 to evaluate existing conditions, ground truth Natural Resource Conservation Service (NRCS) soil mapping, and to model site hydrology. Adjacent, relatively undisturbed forested areas were surveyed, sampled, and described to establish a reference forest ecosystem (FIFE) for restoration planning. Soil samples were evaluated to correlate reference soil systems to the wetland restoration area. In addition, the USFWS Dismal Swamp National Wildlife Refuge office and the N.C. Natural Heritage Program (NCNHP) were visited to collect information pertaining to wetland community-landscape patterns, including Atlantic white cedar (Chamaecyparis thyoides) distributions, in the Dismal Swamp complex. Mitigation site hydrology was modeled for pre-mitigation and post-mitigation hydrologic inputs and outputs to generate an available water budget. Subsequently, conditions were modeled with DRAINMOD to predict the influence of various site interventions to restore wetland hydrology. 2 Dismal Swamn Mitigation Site History The Dismal Swamp mitigation site was originally _ d before Section 404 of the Clean Water Act was implemented in, %. The drainage system was originally installed by Weyerhauser to facilitate the commercial growth and harvest of pine trees. The 612 acre tract has been utilized primarily for tree plantations in the past, as well as agriculture activities through 1995. 11 !• .r ice. s 1 t .lr _ _? -?? ? -- -_- I?? ` r o' 'w -- N+ __ _? _ ? ?Q - _ _ V 43 LIL ' .-- _ - - 7 y'_ A.. .., It \.6 r: Environmental Dismal Swamp Mitigation Site Figure: 2 Dismal Swamp Wildlife 0 Services, Inc. in relation to the Refuge and Natural Areas 1318 Dale Street Suite 220 Dismal Swamp National Wildlife Refuge Project: ER94018.7 Mitigation Site Raleigh, NC 27605 and Natural Areas Date: 7 Apr 1995 0 1 2 3 4 Mlles 12 13 The site is bordered on the north by artificially drained pine plantation owned by Weyerhauser. The southern and eastern boundaries abut former cultivated lands or active farmfields which have also sustained impacts from drainage structures. The mitigation bank site is bordered on the west by upper reaches of the Perquimans River and relatively undisturbed forested' wetlands which constitute part of the Great Dismal Swamp refuge (Figure 2). 5.3 Existing Conditions 5.3.1 Physiography, Topography, and Land Use The subject property is located in the Atlantic Coastal Plain Physiographic Province of North Carolina. The Coastal Plain is comprised of sediments deposited since the Cretaceous Period during a series of transgressions and regressions of the Atlantic Ocean. The Dismal Swamp site is situated on the Outer Coastal Plain which extends from the Suffolk Scarp, a paleo- shoreline, to the Atlantic Ocean. The mitigation site is located approximately 1 mile east of the western edge of the primary Suffolk Scarp formation (DNR 1985). Current land use consists of agriculture including 1994 harvests of corn and soybean. A forested area persists in the southwest section of the site. This stand appears to have been selectively cut over the last 20 years. Hunting club leases are currently applied in forested areas. Numerous commercial hunts were observed during field studies. 5.3.2 Soils The site is located within the southern portion of the Great Dismal Swamp complex. The gA qF W9 W-04 ItISOIS, surficial soils encountered were orq ?stosols) and or Inceptisols?, with two small inclusions of nonhydric soils (Spodosols) in the southern portion of the tract. Soils have been mapped by the Natural Resource Conservation Service (NRCS) (USDA 1986, USDA 1994). Figure 4 depicts NRCS soil map units overlaid upon recent aerial photography. Soil phases include the Scuppernong/Belhaven series (Terric Medisaprists), the Arapahoe series (Typic Humaquepts), the Icaria series (Typic umbraquults), the Leon/Lynn Haven series (Aeric to Typic Haplaquods), and the Echaw series (Entic Haplohumods). Series represented by two names are typically similar soil map units that occur on either side of the county line. 14 15 Soil texture within most of the site ranges from loam to loamy sand of slow to moderate permeability. Upland soils include a highly permeable upper soil solum. In undrained condition, the seasonal high water table varies along the topographic gradient from surface flooding to more than 4 feet 0.2 m) below the soil surface. NRCS mapping (Figure 4) identifies low-lying flats associated with upper reaches of the Perquimans River, which support very poorly drained, organic soils (Medisaprists, Scuppernong/Belhaven Series). A portion of this map unit exhibits indications of fluvial deposits from infrequent overbank flooding within the adjacent tributary. Areas further east of the channelized tributary support poorly drained, mineral soils (Umbraquu/ts, Icaria Series; Hap/aquods, Leon Series). An isolated knoll maintaining non-hydric soils is situated in the southeastern corner of the property (Hap/ohumods, Echaw Series). The soil and landform gradient suggests that several natural forested communities existed on the site prior to farming and forestry practices. Soil-site relations indicate that riverine/bottomland swamp forest, nonriverine swamp/peatland Atlantic white cedar forest (organic soil subtypes), nonriverine swamp hardwood forest (mineral soil subtypes), limited nonriverine wet hardwood forest edges, and a coastal fringe sandhill forest inclusion may have occurred on the site prior to farming (soil-forest site classifications are introduced in Schaf ale and Weakley (1990) and Van Lear and Jones (1987). Hydric soils are defined as "soils that are saturated, flooded, or ponded long enough during the growing season to develop anaerobic conditions in the upper soil layer" (USDA, 1987). Hydric soil boundaries on the site were flagged in December 1994, by the N.C. Department of Environment, Health, and Natural Resources (NCDEHNR); Division of Soil and Water. Subsequently, NCDOT personnel mapped hydric soil limits using GPS technology. Figure 5 depicts the hydric/nonhydric soil boundaries identified on the site. Hydric soils include the Scuppernog/Belhaven, Arapahoe, Icaria , and Leon series. Organic matter content ranges from a potential maximum of 90% in the control section of Scuppernog/Belhaven soils to a minimum of 0.5% in the Leon series (USDA 1986, USDA 1994). era rainage are inWaded by relatively slow pe eabi#i ir_ soils coupled with the presence of clayey subse atizons of moderate organic content and the lack of topographic slope in the area. The construction of large canals and feeder ditches has drained most of these soil units to the extent that hydric conditions in upper soil horizons are currently limited. In addition, artificial drainage and agricultural production most.likely promoted a reduction in organic matter content through accelerated decomposition and harvesting. In order to reestablish wetland hydrology within hydric soil areas, drainage canals require modification to recreate natural subsurface drainage patterns. Organic matter relations in the soil environment are expected to return to relict condition over time, once wetland hydrology is restored. 16 i I t 1 I 1 1 ! I I I 1 I I + 1 1 I I I ! 1 1 I I 1 I 1 1 1 I ?? t I ! I ?? ; I ! I i i I 1 1 I 1 ! I ? 1 1 I 1 j OrM-PZ4 ? ' 1 1 1 I I 1 I ! I 1 1 ( I I I 1 1 1 1 1 ! ! 1 1 1 1 1 i j 1 1 I 1 1 1 ? 1 I ? ( ! ? I 1 I ? I 1 1 I ! ! I 1 1 1 1 ! t I I 1 I ? 1 I 1 I 1 ! 1 i I I 1 1 I 1 I I I ! ( ! I ??? I 1 1 ! I I 1 I 1 i OI?Zt 1 1 I ? I I ! 1 I I I - 1 1 i I 1 I 1 ; ; ; I I I I I I 1 1 1 1 I I I ! I 1 I 1 I I 1 I ! 1 ? 1 I ! ! I I I I 1 1 1 ! I 1 1 I 1 1 1 1 1 1 I 1 1 ! 1 1 1 I ! I 1 1 I 1 1 I 1 ! I I 1 ! ? I 1 1 I I I I ! I I I ! i 1 y_p}y ; 1 I 1 ! ! OI01-dZlt I ! I 1 1 1 1 I ! I I 1 ! 1 ! j 1 e*-PZ10 I 1 ! I I I ! I I 1 1 ; 1 I i 1 1 1 ! 1 I ! I 1 1 1 1 1 1 1 I 1 ! I ?1LI I 1 I I 1 1 I 1 1 1 I I i 1 j ! ! 0tjll-PZ141 ! 1 I I 1 ! I I j j ? ? ! 1 ! ? 1 ? } ? ? i icM'?zla OI'Y-PZIC , i 1 Q? ` ?'• S 7 ! Mas- '7`__ 1 r •? ! I I I !ONY-P:1! ! i j ; ? •? N i Nonhydric Soil Areas -12 Acres Hydric Soil Areas - 600 Acres 1 inch = 800 feet Figure: 5 Environmental Hydric/Nonhydric Services, Inc. Soil Boundaries 1318 Dale Street Dismal Swamp Mitigation Site Project: ER94018.7 Suite 220 Gates and Perquimans Raleigh, NC 27605 Counties, NC Dare: 10 Apr 1995 17 The only non-hydric soil on the mitigation site comprises the moderately well drained, Echaw Series (Entic Haplohumods). This non-hydric map unit occupies a small area in southern portions of the site (Figure 4) (USDA 1986). The area supports an elevated, sandy knoll with the seasonal high water table at approximately 3 feet (0.9 m) below the surface. This area lacks wetland hydrology (as is historically the case). However, this upland inclusion in the mitigation landscape provides the potential for restoration of an upland/wetland ecotone into native forest communities. Wetland/upland ecotones are among the most diverse and productive environments for wildlife (Brinson et al 1981). In addition, a number of physical wetland parameters are also enhanced by the presence of wetland/upland ecotones on the mitigation site (ESI 1994a). 5.3.3 Hydrogeology A detailed hydrogeomorphic site assessment and hydrological restoration report are included in Section 11.0 (Appendices). A summary of existing hydrogeological conditions discerned from these studies is provided below. Regional Hvdrogeolocav Regional groundwater flow in the Coastal Plain is generally in a down dip direction, which trends southeast in this area of North Carolina. Rivers flow from northwest to southeast in the Coastal Plain, roughly paralleling the dip direction. The southern portion of the Great Dismal Swamp also drains south to southeast into the Perquimans and Pasquotank Rivers, which drain into the Albemarle Sound. Shallow groundwater usually occurs under unconfined, water table conditions within 5 feet 0.5 m) of the surface in the region, as evidenced by the large expanses of hydric soils, and the extensive use of drainage systems. Local Hvdrogeologv r A grcm -.d-v%Vr'f-aae wateilr c i a %> ` 1 Ind on the subject property to lower near surface hydrology for agricultural production. Systematic ditching has lowered the groundwater table and redirected groundwater flow towards feeder canals and upper reaches of the Perquimans River. This below headwater tributary runs from north to south along the western property boundary. The dr the, ' . *fTINM E approximately. ewart and drain south towards a large canal which transects central portions of the site. The drainage ditches in the so prox mateFy' 50 feet (76 m) apart, and flow either north or south into canals along both sides of the property boundary. Ditches and canals range from 1 foot deep in elevated, central portions of the site t*' ti;' J in plMmO . Site modeling indicates that groundwatep-f#ee w.estwar mass the mitigation area before entering the channelized Perquimans River tributary. 18 The results of the slug tests indicate that the hydric soils on the site have a moderately low hydraulic conductivity ranging from a low of 0.017 inches/hour (4.33x10'2 cm/hr) to a high of 1.02 inches/hour (2.58 cm/hr). Groundwater modeling identified two localized high points in the water table, one is in the southeastern portion of the site in the non-hydric Echaw soils which is represented as a topographic high. The knoll of non-hydric soils and the access road function as a drainage divide in the southern tract. Another localized high point is in the northern tract and appears to be less related to topography. 5.3.4 Plant Communities A large majority of the Dismal Swamp mitigation site consists of active agricultural fields. Of the total 612 acres, ap %) have been cone ??,?'e and ?k support seasonal crops such as corn (Zea mays) and soybeans (Glycine max), along with intermittent early successional vegetation. Within agricultural areas, numerous in-field ditches support some hydrophytic plants, and intra-field dirt road berms are invaded by various upland and invasive species. VfiA q LoG In the southwestern portion of the site, a; disturbed swamp forest community persists (Schafale and Weakly, 1990). This fo urea comprises approximate) s- of the total 612 acre mitigation site. This forested area is similar to a large portion of the adjacent Great Dismal Swamp. Originally, the Great Dismal Swamp was thought to be primarily Atlantic white cedar forests (Chamaecyparis thyoides) from which cedar populations have been declining or eliminated (Schafale and Weakley 1990). Past logging of the cedar and altered fire regimes may have resulted in a forest now -rubrum), ar styraciflua), sw r = (Nyssa bifiora), and b Tess (Taxodium distichum) among infrequent stems of Atlantic white cedar. A number of Atlantic white cedar stumps to 20 inches (51 cm) in diameter-breast-high (DBH) and standing trees to 10 inches (25 cm) DBH have been documented within forested areas on the mitigation site. Signs of reproduction such as cedar seedlings or saplings near the cedar population are also apparent. 5.3.5 Wildlife Communities Although the original forest tracts on this site have been utilized for large-scale agricultural purposes, the adjacent swamp forests of Dismal Swamp and associated field edges provide food, water, and cover for various species of wildlife. In spite of area-wide changes in the original swamp forest, the Great Dismal Swamp and State Natural Area are still known to support large mammals such as black bear (Ursus americanus), bobcat (Felis rufus), and white- tailed deer (Odocoileus virginianus). In addition, the swamp and surrounding lands support many smaller mammals in a complex food chain of predator and prey elements. 19 Extensive areas of standing water and seasonal wetlands within the refuge provide favorable conditions for many species of reptiles and amphibians. Character species include red-bellied water snake (Natrix erythrogaster), eastern cottonmouth (Aglistrodon piscivorus), yellow- bellied turtle (Chrysemys scripta), spotted turtle (Clemmys guttata), southern leopard frog (Rana sphenocephala) and marbled salamander (Ambystoma opacum). These and numerous other reptiles and amphibians are integral components of the wetland food chain. Seasonal use of the Dismal Swamp refuge can be expected by wading birds and waterfowl, including great blue heron (Ardea herodias), black-crowned night heron (Nycticorax nycticorax), mallard (Arras p/atyrhynchos), and wood duck (Aix sponsa). In addition, a high number of passerine birds, both permanent and summer resident species, nest in hardwood swamp forest. Among these are several neotropical migrants such as Swainson's warbler (Limnothlypis swainsonii) and prothonotary warbler (Protonotaria citrea), or forest interior species such as the wood thrush (Hy/ocich/a mustelina) and Acadian flycatcher (Empidonax virescens), that require large tracts of contiguous forest (Keller et al. 1993). Extensive agricultural land on the mitigation site, considered prevalent in the region, provides limited habitat opportunities for these character species. The restoration of forested wetlands immediately adjacent to the Dismal Swamp provides the opportunity to restore forested habitat for these unique wildlife guilds. 5.3.6 Jurisdictional Wetlands Jurisdictional wetlands were flagged in the field to facilitate restoration planning. Jurisdictional areas were defined using the criteria set forth in the COE Wetlands Delineation Manual (DOA 1987). Approximately mss,.: ters and f juri - I wetlands were identified. Figure 6 depicts the location of existing wetland/open water systems. The COE Special Coordinator for NCDOT projects, Mr. Mike Bell, confirmed jurisdictional determinations on 9 February 1995. Jurisdictional wetlands (115 acres) reside within a forested area in the southwestern corner of the property. These wetlands areas are palustrine in nature, characterized by early to mid- successional growth of nonriverine swamp forest cover. Dominant species include sweet gum and red maple, which commonly compose up to 90% of the forest canopy. Infrequent stems of swamp black gum, cypress, laurel oak, and an inclusion of several Atlantic white cedar stems are also present. An additional two acres of jurisdictional open waters reside in a large drainage canal which extends from east to west through the center of the mitigation site. This drainage canal will be eliminated during hydrological restoration activities. The remaining acreage on the site ( 495 acres) consists of approximately 483 acres of prior converted farmland on hydric soils and approximately 12 acres of farmland on non-hydric soils (Figure 6). 20 ® Jurisdictional Open Waters - 2 Acres ® Converted Farmlands on Nonhydric Soils -12 Acres Figure: g Environmental Jurisdictional Wetlands, Jurisdictional Services, Inc Open Waters, and Prior Converted Farmland 1318 Dale Street Dismal Swamp Mitigation Site Project: ER94018.7 Suite 220 Gates and Perquimans Ralelgh, NC 27605 Counties, NC Date: 11 Apr 1995 21 Jurisdictional Wetlands - 115 Acres Prior Converted Farmlands on Hydric Soils - 482 Acres 6.0 MITIGATION PLAN 6.1 Wetland Restoration Modeling A number of mitigation design studies have been utilized for restoration planning. These include hydrogeological modeling, development of available water budgets, soil-site studies, Reference Forest Ecosystem (RFE) characterizations (EPA 1990), and wetland functional evaluations. 6.1.1 Hydrogeological Modeling A hydrogeological site assessment was conducted to determine the existing conditions and wetland restoration potential of the subject property. A detailed report of hydrogeological modeling procedures and results is included in Section 11.0 (Appendix). The assessment included the installation of a series of exploratory soil borings, the conversion of the soil borings into observation wells, and water level measurements over an approximately two month period. Hydraulic conductivity testing of the saturated zone and review of existing data for the region were also performed and incorporated into the hydrological model. The groundwater modeling software selected as most appropriate for simulating shallow subsurface conditions and groundwater behavior was DRAINMOD. This model was developed by Dr. R.W. Skaggs of North Carolina State University (NCSU). The model was originally developed to simulate the performance of agricultural drainage and water table control systems on sites with shallow water table conditions. DRAINMOD was subsequently modified for application to wetland studies by adding a counter that accumulated the number of times that the water table rose above a specified depth and remained there for a given duration during the growing season. The model results can then be analyzed to determine if wetland criteria are satisfied during the growing season, on average, more than half of the years modeled (usually 30 years). Dr. George Chescheir of NCSU also participated in the current study by reviewing the site characterization data and setting up the DRAINMOD model for the study area. Dr. Chescheir provided input parameters required by DRAINMOD and supplied model results for the study area. Output from the DRAINMOD model was then applied to the study area to determine which areas would not achieve wetland hydrology criteria. W s µr?bgth s latn tai .`1cinfae :`_: 1 # tC e d ys (5°% of :thee °'9row? a ` and:r3'I nc TS v.e oa is { 12 5r°1? If :the groves err): For the purposes of this study, the growing season was defined as the period between 21 March and 19 November (USDA 1986, USDA 1994). Simulations were also conducted to forecast whether saturation within 12 inches (30 cm) of the surface could be achieved for 49 and 61 consecutive days ( 20%, and 25% of the growing season, 22 respectively) using conservative model estimates. These additional simulations were conducted to provide information concerning the expected influence of prolonged soil saturation on various target plant species populations. Model Description DRAINMOD predicts water balances in the soil-water regime at the midpoint between two drains of equal elevation. The model is capable of calculating hourly values for water table depth, surface runoff, subsurface drainage, infiltration, and actual evapotranspiration over long periods of climatological data. The reliability of DRAINMOD has been tested for a wide range of soil, crop, and climatological conditions. Results of tests in North Carolina (Skaggs, 1982), Ohio (Skaggs et a/., 1981), Louisiana (Gayle et a/., 1985; Fouss et a/., 1987), Florida (Rogers, 1985), Michigan (Belcher and Merva, 1987), and Belgium (Susanto et a/., 1987) indicate that the model can be used to reliably predict water table elevations and drain flow rates. DRAINMOD has been used to evaluate wetland hydrology by Skaggs et a/. (1993). Model Calibration The hydrology of various soil-water conditions applicable to the site was simulated using DRAINMOD. The simulation used the hydric mineral Icaria series, a fine sandy loam, for portions of the site consisting of prior converted farmlands. Icaria soils represent the most common series of most intermediate character on the site. Soil input parameters for DRAINMOD were calculated by the NRCS model, DMSOIL (Baumer and Rice, 1988) using soil texture data from soil samples collected on site. Soil hydraulic conductivity values were determined from the slug test data. Simulations were conducted for the time periods from 1951 to 1980 using climatological record from Plymouth, Washington County,.North Carolina. DRAINMOD simulations were conducted for the range of ditch depths and for the distances of a midpoint between ditches. Simulations were then run to determine the distance between ditches predicted for the establishment of wetland hydrology for 5%, 12.5%, 20%, and 25% of the growing season. T e j.. . , Mby the process of below ground plant growth, interception of rainfall, and litter accumulation. An irnperrneable4daye a as,?.,Lp-be present at a depth 9A i° rtr). A detailed description of model calibration parameters is provided in Section 11.0 (Appendices; Hydrogeological Site Assessment Report). The depth of depressional storage used in initial DRAINMOD simulations was 1.96 inches (5 cm) assuming no provisions for amelioration of surface storage on farmed land. Based upon the input data, saturation to within 12 inches (30 cm) of the surface for 25% of the growing season (61 consecutive days) could not be achieved. The simulations were repeated using a 23 surface storage of 3.9 inches (10 cm), assuming that surface roughing would be used on the site to increase surface storage. Based on 3.9 inches (10 cm) of surface storage, saturation for 25 % of the growing season was achieved. The rooting depth function used in the simulation was a constant depth of 17.7 inches (45 cm), which is typically used for forested conditions. Model Results The DRAINMOD simulations predicted that a very high percentage of the cultivated land would achieve wetland hydrology criteria. The model predicted that at a maximum of 330 feet (100 m) from the drainage canal, saturation for 12.5% of the growl season could be achieved by MWateral ditches and assuming surface sto _ge of 3 9 inches (10 c . Table 2 provides the results of the DRAINMOD modeling study presenting different ditch depths and distances from the perimeter canals that wetland hydrology would persist for 5%, 12.5%, 20%, and 25°x6 of the growing season. TABLE .2 Results of DRAINMOD Simulations for Saturation within 12 inches (30 cm) of surface for Selected Percentages of the Growing Season (Surface Storage = 10 cm) Ditch Depth Percentage of Growing Season Number of Days 30 cm (1 ft) 60 cm (2 ft) 90 cm (3 ft) 120 cm K ft) 150 cm (5 ft) Ditch Spacing (meters) 5 12 25 37.5 50 50 50 12.5 31 37.5 50 75 75 75 20 49 50 75 75 75 100 Wetland hydrology is defined as the conditions that resulted in the tha?a.i0122CI ifiears. As was expected, wetland hydrology was more likely to occur in the interior portion of the tract, away from the perimeter canals. Of 483 acres of farmed hydric soils, approximately p se ?yason, oe ditches and canals are eliminated. Based on DRAINMOD results,an 24 (_; additional 28 acres of prior converted farmland would meet the wetland criteria for between 5% and 12% of the growing season. The remaining 57 acres of prior converted farmland in close proximity to the perimeter canals will support wetland hydrology for less than 5% of the growing season. This narrow strip along the outer edge of the mitigation property will serve as a wetland hydrological buffer between canals and the restoration areas. Figure 7 identifies the location of modeled wetland hydrology map units on the site. The wetland hydrology results in Table 2 were also used to determine which portions of the tract would not meet wetland criteria, on average, more than half the time. The issue of determining if a specific portion of the site will support wetland hydrology was predicted by comparing the ground elevation at the simulated midpoint to the elevation of the water in the nearest perimeter canal. Those areas which would not meet wetland criteria include two small elevated upland islands, comprising approximately 12 acres, in the southern portion of the site. Wetland hydrology map units presented in Figure 7 were utilized, in part, to model community restoration potential. 6.1.2 Reference Forest Ecosystem Modeling In order to restore or create a forested wetland for mitigation purposes, a reference community endpoint needs to be established. According to Mitigation Site Type Classification (MiST) guidelines (EPA 1990), the area of proposed restoration should attempt to emulate a Reference Forest Ecosystem (FIFE) in soils, hydrology, and vegetation. RFEs are composed of relatively undisturbed woodlands near the mitigation site which support soil, landform, and hydrological characteristics that restoration activities are attempting to emulate. Although selection of the RFEs is determined by soil, hydrologic, and landform parameters, there is much variation within local forested areas that may not be represented in the sample plots. Nearly all potential RFE sites have been impacted in the past by selective cutting or high-grading, and the species composition of the plots should be considered as a minimum starting point in restoration procedures. Therefore, FIFE information, when incorporated into a community restoration plan, should be modified based on community information obtained from other available resources. Reference forest data utilized in restoration planning have been modified, where appropriate, to emulate steady state community structure as described in Classification of the Natural Communities of North Carolina (Schafale and Weakley 1990). Information obtained from the USFWS Dismal Swamp National Wildlife Refuge office was also incorporated into community restoration procedures. In addition, forest ecosystem classification research developed for the southeastern United States was incorporated (Van Lear and Jones 1987, Jones 1989, Peet and Christensen 1980, Beals 1984). Based on soil and landform parameters on the mitigation site, four reference ecosystem types were considered for reference characterizations. These include riverine swamp forest on 25 I i _ fll II I IIIIII' I? ?? I Ill??l llllil f- ? . - -------------------- -OIIY••Pii. i p r --- -------- r- --•---- k -•-•---------------------------- F -•-•--•-i----- F ---+ ----- ---__;_ _i =r- -_ ! i ! ! ! air M4 i i I r ! I I 1 j 1 r ie"r-P I' i i o"16 L? S I 1 -_ 1 inch = 800 feet W0% - 5% (57 acres) 20% - 25% (44 acres) N 5% - 12.5% (28 acres) >25% (443 acres) 12.5% - 20% (26 acres) ® Nonhydric Soils (12 acres) Environmental DRAINMOD Figure: 7 Services, Inc. Estimated percent of the growing season 1318 Dale Street that wetland hydrology will persist project: ER94018.7 Suite 220 on the mitigation site Raleigh, NC 27605 (3.9 inches (10 CM) Surface Storage) Date: 13 Apr 1995 ItFLOY- 26 organic soils exhibiting fluvial interlayers, nonriverine swamp forest on organic soils (Scuppernong/Belhaven series), nonriverine swamp/wet hardwood forest on mineral hydric soils (Icaria series, Leon inclusions), and coastal fringe sandhill forest on moderately well drained, non-hydric, fine sandy soils (Echaw series). Systematic surveys were performed in forests surrounding the site to locate sample plot locations within the four reference vegetation/landform types. Variations in species composition between forests on the Scuppernong/Belhaven series and Icaria inclusions were minimal, and these two ecosystem types were combined into one type for reference characterization purposes. The primary purpose for differentiating between swamp forest soil subtypes is to target Atlantic white cedar restoration towards organic soil areas. T eas were identified to characterize thand'Atlantic white cedar forest restoration areas. These plot locations are situated approximately 15 d-2000 feet northwest of the mitigation property along an adjacent access road (Figure 2). These steady-state forest sites were sampled using 0.20-acre circular plots (standard forestry methodology). Plots were randomly established within forested areas supporting target landform, soil, and hydrological characteristics in an effort to characterize the expected steady- state composition of the mitigation site after restoration. Ecologists identified and counted all species of trees (greater than 20 feet (6.1 m) in height); the diameter breast height (DBH) of each tree was measured from which basal area coverage was calculated. Importance values (IV) (Brower et al. 1990) were later calculated for the dominants. Composition of shrub and ground cover strata were also recorded and plants identified to species. Sampling efforts were concentrated within canopy layers to identify tree species to be chosen for later restoration planting. Importance values for tree species within swamp forest sample plots is depicted in Table 3. In addition, Table 4 provides a complete inventory of shrubs and herbs identified in sample plots and adjacent areas during the study period (December 1994). Nonriverine swamp forest canopies on Belhaven/Scuppernong soils and Icaria inclusions are dominated by swamp black gum (IV = 38%), red maple (IV = 18%), and bald cypress (IV = 16%) (Table 3). To a lesser extent, a mixture of sweet gum (IV = 9%), sweet bay (Magnolia virginica)(IV = 5%), laurel oak (Quercus laurifolia)(IV = 5%), swamp red bay (Persea palustris), American holly (flex opaca), and ash (Fraxinus sp.) are also found. Infrequent stems of loblolly pine (Pinus taeda), willow oak (Quercus phellos), and yellow poplar (Liriodendron tulipifera), although not situated within sample plots, were noted in adjacent areas. Atlantic white cedar is known from nearby parts of the swamp forest ecosystem and several reproducing specimens were found within forested portions of the mitigation site. This area had apparently been cut over some time ago, but several Atlantic white cedar stems were spared. Disturbance seems to have increased the occurrence of yellow poplar (Liriodendron tulipifera), loblolly pine, and the maturation of several water oaks (Q. nigra) and American holly in this area. 27 VI d ?U W as u ? A o a3 z M ? Cal F M O (ON \0 ^? 00 O O Cf) CIF) O V) O W) O p y O CAE 6 dW) O N 00 i i i O O II O + M t7 aN M 00 ?'`? ,..? ('n 06 h M CA M Ci C) 0 0 " N d C) ^ it w v' Vn v' kn 00 0 0 0 00 II a w v ? 0 0 0 0 ?n v? v? V) v) ?d a r, r, r. ? 0 0 0 0 0 L w C ? ? p N N N N .-r ? ? ?--? ^? ? o ?? ? ? ? N O O O O O II aA a= 00 w zS rA W o u (U b n a v w C7 a? n O F CIO c i C 28 a• O 3 b O 3 0 a 0 0 a O «3 .s 0 a w 0 b 0 b a U TABLE 4 Inventory of Shrubs and Herbs in Reference Nonriverine Swamp Forests (December 1994) Shrubs Red Maple Acer rubrum Pawpaw Asimina triloba Sweet Pepperbush Clethra alnifolia American Holly Ilex opaca Virginia Willow Itea virginica Fetterbush Leucothoe racemosa Sweet Gum Liquidambar styraciflua Sweet Bay Magnolia virginica Laurel Oak Quercus laurifolia Willow Oak Quercus phellos Smooth Greenbrier Smilax glauca Laureleaf Greenbrier Smilax Iaurifolia Blueberry Vaccinium sp. Swamp Red Bay Persea palustris Herbs Switch Cane Arundinaria gigantea Fern Fern sp. Virginia Chainfern Woodwardia virginica Water Hyssop Bacopa sp. Poison Ivy Toxicodendron radicans Partridge Berry Mitchella repens Sedge Carex sp. 29 Based on available information, other species may have occurred within the system before long-term disturbance from logging. However, these species were not found in RIFE plots or adjacent areas. Other potential members of the swamp forest/Atlantic white cedar community include Carolina ash (Fraxinus caroiiniana), pond pine (Pious serotina), and swamp hickory (Carya aquatica). Overcup oak (Quercus iyrata), tupelo gum, and swamp cottonwood (Popuius heterophy//a) may have occurred in expected relict floodplains near the large channelized tributary which borders the western edge of the property. The upland forest restoration area and riverine swamp forest inclusion were not characterized by RFE sampling due to the lack of relatively undisturbed, representative sites in the project area. Upland areas near the mitigation site currently consist of farmlands and pine plantation. Based on available information concerning soil.and landform features, the upland areas may have supported coastal fringe sandhill species such as longleaf pine (Pins Pa/ustris), live oak (Quercus virginiana), turkey oak (Quercus iaevis), dwarf post oak (Quercus ste//ata), scarlet oak (Quercus coccinea), blackjack oak (Quercus mariiandica), and black gum (Nyssa syivadca) (Schafale and Weakley 1990, USDA 1994, USDA 1986). Lower positions on the knoll may have also included character species such as water oak (Quercus pagoda), swamp chestnut oak (Q. michauxii), and yellow poplar. 'Restoration of the natural forest community will be implemented along this upland/wetland ecotone to increase habitat diversity across the mitigation landscape. 6.2.1 Hydrological Restoration The results of the DRAINMOD modeling study indicate that well hr can be achieved within approximately . r1'nf prior converted farmland on hydric soils, 9e.. d NO "' 0emoved and the surface de - ted. The 427 acre area includes -acres at saturation for greater than 12.5% of the growing season and 28 acres at saturati n for between 5% and 12.5% of the growing season. V r dr ,#q"ithee=, a, ::effectily °be -achie+ ?l fly ,filling the lat"eral-;fieeder- ditt*hd ?'an-d thwl? wo° drCg* `eanaiw4et. ee}thy"rior?fi?an - sr?utfiern-?rae?s'`af the site. Increasing the depressional storage an be achieved by limited rowing and bedding when planting specimens and by scarifying the oils between beds. If bedding is performed, rows will be established roughly parallel to exi ting topographic contours with 1 foot (.30 m) high beds spaced at intervals to allow acces by a tractor. Tractor access will allow mowing of the area to prevent over-topping by pioneer vegetation and to scarify the soils between the beds during the first two years of restoration, if necessary. r 30 Recommendations For Filling Drainage Ditches Restoring wetland hydrology on the site will require the effective filling and sealing of the lateral feeder ditches and the canals between the northern and southern portions of the site. Subject ditches can be specifically identified on large scale figures in the detailed Hydrogeological Site Assessment (Section 11.0; Appendix). The large canals and lateral ditches will be backfilled in a manner to minimize the former canals serving as pathways of preferential migration for groundwater. Backfill will be deposited in lifts of 1 foot (0.30 cm) with each lift compacted to at least 90% of the maximum dry density determined by the standard proctor test (ASTM D-698). Failure to minimize preferential migration will allow the former canals to function as french drains and short circuit the groundwater flow at the site and jeopardize the restoration efforts. The relatively shallow, lateral ditches may be backfilled in one lift. However, if this method is selected for implementation, a series of clay dikes will be required across each lateral ditch to minimize preferential migration and drainage. The clay dikes will be required to extend to 1 foot (0.30 cm) below the existing bottom of the ditch. After implementation of the selected backfill method, the deposited material will have a hydraulic conductivity of 1.42x 10'8 inches/hour (3.6x104 cm/h) or less. Fill material is available on-site from the spoil ridge along the western site boundary. This spoil currently functions as a dike to prevent overbank flooding. Additional fill material is also available by removing the road between the two tracts and grading a smooth transition from the north to the south across the former canals and road. Fill material for the ditches and canal should be low permeability clays or silty clays. However, due to the relative scarcity of clays in spoil material, bentonite or montmorillonite clay will be mixed with fill material on-site prior to placement and compaction. Recommendations for Site Grading and Floodqlain Restoration Along with backfilling the existing drainage system, portions of the site will be graded to enhance hydrologic function. Spoil from dredging upper reaches of the Perquimans River is piled along the stream bank running the length of the western property boundary. This MWOIS?l has prevented or minimized overbank flooding within lower portions of the mitigation site. The • ?re?-a?i??#oc fill material. The western edge of the tract will then be gr e a ton? =feet ( f?lized tributary. A levee ??pr??cirateby-.t?e8 gym) tall w ,ec aJgrQ_th&-stream bank. This levee will reproduce the functions of a natural levee by delaying the recession of flood waters back into the channel, thus extending the period of water storage within the floodplain. An opening in the levee will be constructed near 31 the north end to facilitate the diversion of flood waters onto the site. 1'u0oiVfield o tions, elevations of flood waters in the field are expected to range between 10 and 11 feet (3.0 and 3.3 m) above msl. This grading and berm construction would facilitate the restoration of riverine floodplain conditions adjacent to the canal. Estimated area of flood plain restoration achieved using 11 feet (3.3 m) msl as the maximum elevation is approximately 34 acres. An additional 24 acres of floodplain enhancement would also be realized within low- lying forested portions of the site. The estimated floodplain restoration and enhancement area is presented in Figure 8. Acreage of floodplain resulting from restoration activities will be substantiated by Rlacing a,xeamgauge;irr the adjacent below headwater tributary. 6.2.2 Plant Community Restoration Restoration of wetland forested communities provides habitat for area wildlife and allows for development and expansion of characteristic wetland dependent species across the landscape. Ecotonal changes between community types developed through a landscape approach to community restoration contribute to area diversity and provide secondary benefits, such as enhanced feeding and nesting opportunities for mammals, birds, amphibians, and other wildlife. RFE data and on-site observations, coupled with experience in forest ecosystem classification and a review of the available literature, were used to develop the primary plant community associations that will be promoted during community restoration activities. These community associations include: 1) riverine swamp forest; 2) nonriverine swamp forest: organic soil variant; 3) nonriverine swamp forest: mineral soil variant; and 4) coastal fringe sandhill forest: non-hydric soil inclusions. Figure 9 provides a landscape portrayal of target vegetation communities that will be promoted in the restoration process. Figure 10 identifies the location of each community on the mitigation site. A summary of community restoration components is provided. Restoration of riverine swamp forest wetlands (34 acres) is designed to reestablish the major component species which facilitate development of the community. The riverine swamp forest community is targeted to support indicator species such as overcup oak (Quercus iyrata), swamp cottonwood (Popuius heterophy//a), tupelo gum (Nyssa aquatica), bald cypress (Taxodium distichum), Carolina ash (Fraxinus caroiiniana), and swamp hickory (Carya aquatica) The riverine swamp forest community is expected to sustain periodic overbank flooding. Nonriverine swamp forest community types have been subdivided into an organic soil variant and a mineral soil variant based on ecological features. The subdivision of swamp forest restoration areas into two planting regimes has been implemented primarily to target available stems of Atlantic white cedar to landscape areas which contain soils of high organic content and exhibit the potential for relatively long term soil saturation (Schafale and Weakley 1990; 32 ! i ?? Zl , 1 ? ! 1 ! 1 1 I I I I I i i o?-ne i i ! i pM-?}3 i i i ! I ; i i r i i i ? i i i i ? ? i i i e*-nlo L. ?_} ? j i ! 1 1 O?Zi41 ! 1 1 ??`?.?? ? I j dtY-P#13 I I I j 1 I I I 1 ! I 1 1 ? j ? ? 1 ! I 1 1 ; j ; ? 1 / ? ? ? •oMwzFs i i ap+us , ? ? ? i L ?\ ?? ?? I ! I I I 1 j 1 i ; i mos- t !o?-rz?s ! i oe-e \ \ t o i i ! ? i vM i 0 ?.•` ?\ ?.\ ?;` 1 finch =800 feet i N Estimated Floodplain Area - 58 Acres Figure: 8 Environmental Estimated Riverine/Floodplain Services, Inc. Restoration Area 1318 Dale Street Dismal Swamp Mitigation Site Project: ER94018.7 Suite 220 Gates and Perquimans Raleigh, NC 27605 Counties, NC Date: 13 Apr 1995 33 r r < Dn z ? m O cn z O m Cl) v E cn cn O v m F. C m D ccn 0 -DI CE r- Z M CD O? D? Z Z m? C 3 _0 ----- c? CD C/) ?. .: _. -n 0co m -n (D < 3 3 w oho 0 m W 2 Q °. n n? n C ?• CL < 0> C O '< O CD CD _ -a 0 Cl) =. (C) 0 Lo. CO) 0 :3 (D D CD 0 CL 0 (D cn CD P* 0 CD C: 3 (n CL T ? 4 l fit.. CD CA r-P y C CD Z 00 a r? cn. BCD On 032 00 CD C -0 0 CD r- 0 0 CD 0 -n 0 0 (n CD C) CD CL c t :? Q F) C7 ? m t ? Cl) (D O O "' cA CD CD CO) (D 0 CD (D< ZT 3 C _0 0- cr CD 0 C/) ?' p' (°D "d (D T • f 1? A) Cl) 2) m rh CL m co I 0 CD =3 5' Ch CD a O ° o + y t. 0- (D W n C a o ?• c Q. CD v < A) 00 0 =3 ;v CL ° CD d1' t' c '' 0 T1 3 Q ? 3 0 x ;v :3 O ? i • CD M O -o _n co f.. t . (D (U cn m F i L i i i i .w-_. A:. i i - - -? _ `\ 77, Forested--? area -`J ?t r-- - i - - - ._ -? W7 a i i i i i i i i i i i i i i i i i i i i i © Riverine Swamp Forest - 34 Acres ® Nonriverine Swamp/Atlantic White Cedar Forest - Organic Soil Subtype -136 Acres 14? - Environmental Services, Inc. 1318 Dale Street Suite 220 Raleigh, NC 27605 ? ? I I I i i i o+N-vzs ! i i i i i ! ! ! i• oajv-rzt i . - _ - _ _ ! - - - - - - - - - - - - - I ! ! ? i ? i ? i i I ? 1 pM I 1 inch = 800 feet l? Forested Area - 115 Acres N Nonriverine Swamp Forest - Mineral Soil Subtype - 315 Acres Coastal Fringe Sandhill Forest 12 Acres Figure: 10 Community Restoration Map Units Dismal Swamp Mitigation Site Project: ER94018.7 Gates and Perquimans Counties, NC Date: 13 Apr 1995 35 pers. comm. Brownlie, FWS Dismal Swamp National Refuge Office). The mineral soil variant of the swamp forest restoration area may also include intermittent stems of Atlantic white cedar, if planting sources are available. However, species such as laurel oak, swamp black gum, willow oak, yellow poplar, and cypress may exhibit higher affinity for these areas. The target community structure for nonriverine swamp forests is composed of swamp black gum, cypress and Atlantic white cedar. Intermittent stems or dominating inclusions of laurel oak, cherrybark oak (Quercus pagoda), green ash, yellow poplar, and willow oak are being facilitated. Infrequent plantings of swamp hickory, Carolina ash, overcup oak, and tupelo gum will also be encouraged in the target swamp forest canopy. Opportunistic species which typically dominate disturbed swamp forests have been excluded from initial community restoration efforts. Opportunistic species include loblolly pine, sweet gum, and red maple. In addition,. American sycamore (Platanus occidentalis) has been excluded due to the perceived low ecosystem value indicated by various natural resource personnel. Efforts to inhibit early site domination by opportunistic species may be required during the first several years of tree growth to encourage diversity. However, these species should also be considered important components-of steady-state swamp forest communities where species diversity has not been jeopardized. The survival rate of Atlantic white cedar seedlings has not been fully researched to determine survivability and causes of mortality. Therefore, this species should not be heavily relied upon to achieve the success criteria outlined in the Vegetation Monitoring Plan (Section VI). Evidence indicates that a major cause of mortality in planted seedlings is over-browsing by deer. Methods to control deer browsing, such as tree shelters, should be considered. The presence of dense successional thickets around planted seedlings may also limit deer browsing. However, in some instances, the substantial decrease in growth rates and the potential for over-topping by weedy species may reduce the benefits of this option. Regular shrub and herb maintenance coupled with selective use of tree shelters may encourage higher survival rates and more rapid growth. The restoration of a coastal fringe sandhill community isolated within the wetland complex has also been designed. Upland forest restoration plans are designed to enhance wetland functions and to restore a wetland/upland forest ecotone that is considered rare in the region. The target forest community is composed primarily of longleaf pine among intermittent stems of live oak, turkey oak, dwarf post oak, scarlet oak, blackjack oak, and black gum. Additional upland groundcover and understory elements such as black cherry (Prunus serotina), sassafras (Sassafras albidum), Vacciniums (Vaccinium spp.), and other species are expected to migrate from upland roadway edges and berms adjacent to the mitigation site. 36 For upland restoration areas, the planting regime can be modified to allow for maintenance of food plots or other wildlife management features. Upland restoration efforts will be coordinated with WRC, USFWS, or other management contingencies. The following planting plan serves as the blueprint for community restoration. The anticipated results stated in the Success Criteria are expected to reflect potential vegetative conditions which may be achieved after steady-state conditions prevail over time. Planting Plan A planting plan is proposed for the mitigation areas to reestablish wetland community patterns across the landscape. The plan consists of: 1) acquisition of available wetland species; 2) implementation of proposed surface topography improvements; and 3) planting of selected species on site. The COE bottomland hardwood forest mitigation guidelines (DOA 1993) were utilized in developing this plan. The species selected for planting will be dependent upon the availability ofocal seedling sources at the time of planting. Target planting densities and total sus needed by species are depicted in Table 5. Based on contacts with tree nurseries, the availability of Atlantic white cedar and other species is limited. Advance notification to nurseries (1 year) will facilitate availability of various non-commercial elements. An outline of planting groups is provided. 1. Riverine/Floodplain Swamp Forest' A. Overstory 1. Bald Cypress (Taxodium distichum) 2. Tupelo Gum (Nyssa aquatica) 3. Swamp Black Gum (Nyssa biflora) 4. Overcup Oak (Quercus lyrata) 5. Swamp Cottonwood (Populus heterophylla) 6. Green Ash (Fraxinus pennsylvanica) 7. Swamp Hickory (Carya aquatica) 8. Carolina Ash (Fraxinus caroliniana) 9. Laurel Oak (Quercus laurifolia) 'Certain characteristic canopy trees such as sweet gum (Liquidambar styraciflua), red maple (Acer rubrum), and loblolly pine (Pious taeda) have not been incorporated into this plan because these species are expected through natural recruitment. 37 Cl) O C. G E ca 3 cn H Q a E a a R a NN 0000 c qt 000000 00 O N 'It O O 0000 CO CO O? 000000000 O O N N N N N N 00 O to Va 0001" it I-or0M TTWLO TM CD a0 NNrM ? d• "t CO W dT't fl N 1 ! cn U a°i It wwNNNNNN000 w tm 0 = N *-Mf- f?-f-(-f-P- m 0 t c H a N 00 LL LL O? s CC o? U LO Lf)o00000LnLO N T T- T T r T O O Cry ° 0 0000000000C000d0 0 CO CL N r 00000 0000 0 000 0 N0)(M(D q* (D CO N Q) N Ci ^ c9 06 06 (flN0 .14rCV(6 4 ,L 0 H a r r T LO d• "t N CD MAO " 5 CZ - a ' L ? (n lA C? r co ? U - 00LO vLO CV C 00Ln V O o 3 o co ao 00NIt(D ItItIt•N 00 a. Dy+O+H ?? N ?00'd It00 co co co 00 co It Citd N^ I c? 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Understory and Groundcover Groundcover and understory elements are expected through natural recruitment from adjacent swamp forest areas and stream banks. II. Nonriverine Swamp Forest: Organic Soil Variant A. Overstory 1. Atlantic White Cedar (Chamaecyparis thyoides) 2. Bald Cypress (Taxodium distichum) 3. Swamp Black Gum (Nyssa bif/ora) 4. Laurel Oak (Quercus laurifolia) 5. Green Ash (Fraxinus pennsylvanica) 6. Cherrybark Oak (Quercus pagoda) 7. Willow Oak (Quercus phellos) 8. Carolina Ash (Fraxinus caroliniana) B. Understory and Groundcover Groundcover and understory elements are expected through natural recruitment from adjacent nonriverine swamp forest areas. Atlantic white cedar plantings will be concentrated within organic soil areas of the nonriverine swamp forest community as indicated appropriate by reference systems and available information. However, the survival rate of Atlantic white cedar seedlings has not been fully researched to determine survivability and causes of mortality. Therefore, this species should not be heavily relied upon to achieve the success criteria outlined in the Vegetation Monitoring Plan (Section VI). Ill. Nonriverine Swamp Forest: Mineral Soil Variant A. Overstory 1. Laurel Oak (Quercus laurifolia) 2. Willow Oak (Quercus phellos) 3. Cherrybark Oak (Quercus pagoda) 4. Swamp Black Gum (Nyssa biflora) 5. Bald Cypress (Taxodium distichum) 6. Green Ash (Fraxinus pennsylvanica) 7. Yellow Poplar (Liriodendron tulipifera) 39 8. Atlantic White Cedar (Chamaecyparis thyoides) 9. Swamp Chestnut Oak (Quercus michauxii) B. Understory and groundcover Groundcover and understory elements are expected through natural recruitment from adjacent nonriverine swamp forest. IV. Coastal Fringe Sandhill Forest A. Overstory 1. Longleaf Pine (Pious Palustris) 2. Live Oak (Quercus virginiana) 3. Water Oak (Quercus nigra) 4. Blackjack Oak (Quercus marilandica) 6. Dwarf Post Oak (Quercus stellata) 7. Scarlet Oak (Quercus coccinea) 8. Black Gum (Nyssa sylvatica) 9. Turkey Oak (Quercus laevis) 10. Mockernut Hickory (Carya tomemtosa) B. Understory and groundcover Additional upland groundcover and understory elements such as black cherry (Prunus serotina), sassafras (Sassafras albidum), vacciniums (Vaccinium spp.), and other species are expected to migrate from upland roadway edges and berms adjacent to the mitigation unit. Coastal sandhill/longleaf pine-oak forest areas represent a small portion of the acreage to be planted during restoration activities. This planting regime can be modified to allow for maintenance of food plots within forest interiors. Upland restoration efforts will be coordinated with the WRC, the FWS, or other management contingencies. Planting Program Bare root seedlings of tree species will be planted on 8-foot (2.4 m) centers (680 trees/acre) within the specified map areas. In restoration areas, species at the relative densities indicated in Table 5 will be alternated within adjacent centers whenever feasible. Planting will be performed between December 1 and March 15 to allow plants to stabilize during the dormant period and set root during the spring season. Standard tree tube shelters may also be used 40 on select stems to promote survival. Removal or control of competing nuisance vegetation will be implemented as necessary to ensure adequate survival of target wetland and upland plants. 6.2.3 Wetland Soil Restoration Land use practices have impacted soil characteristics on the mitigation site. Impacts include the minimization of hydric conditions in upper soil horizons, the reduction in organic matter content through accelerated decomposition, the placement of spoil ridges along the site, and the elimination of surface microtopography by farming activities. The filling of canals and ditches as proposed during hydrological restoration should-serve to reintroduce hydric soil conditions and halt the long-term reductions in organic matter content. Further soil remediation tasks include removal of spoil ridges, reestablishment of surface microtopography, and construction of a natural levee formation within former floodplains of headwaters to the Perquimans River. During hydrological restoration efforts, fill for ditches will be obtained, wherever feasible, from spoil ridges along the western property boundary and central portions of the tract. Any spoil ridges which remain after hydrological restoration is complete will be removed from the mitigation site. Spoil areas will be graded to the elevation of historic surface and landscaped to produce a smooth transition across the former spoil ridge and adjacent canal. Reference wetlands within relatively undisturbed portions of the Dismal Swamp exhibit complex surface microtopography. Small concavities, swales, exposed root systems, and hummocks associated with vegetative growth and hydrological patterns are scattered throughout the system. Large woody debris and partially decomposed litter provide additional complexity across the wetland soil surface. Efforts to advance the development of characteristic surface roughness will be implemented on the mitigation site. Limited bedding and rowing to be implemented during planting activities will promote the formation of hummocks and concavities that act to increase surface storage and provide micro-habitat for invertebrates, reptiles, and amphibians. Scarification of surface soils between planted trees will further promote surface microtopography on the mitigation site. Along the western edge of the property, a spoil ridge has been constructed to prevent or minimize overbank flooding from upper reaches of the Perquimans River. Soil subhorizons adjacent to the tributary indicate that deposition of fluvial sediments historically occurred in the low-lying area (Figure 8). In addition, back-water flooding of this area occurred in December 1994 as a result of drainage overflow from a perpendicular canal which feeds into the main channel. Therefore, removal of the spoil ridge should reestablish overbank flooding and back-water flooding within the soils unit. The western edge of the mitigation site will be graded down to an elevation of eight feet (2.4 m) at the bank of the canal. A levee 41 approximately 1 foot (.30 cm) tall will be constructed along the canal bank. This levee will reproduce the functions of a natural levee by delaying the recession of flood waters back into the channel, thus extending the period of water storage and fluvial deposition of sediments within the floodplain. An opening in the levee will be constructed near the north end to facilitate the diversion of flood waters onto the wetland soil unit. 42 7.0 MONITORING PLAN Monitoring of wetland restoration and enhancement efforts will be performed until success criteria are fulfilled. Monitoring is proposed for two wetland components, vegetation and hydrology. Wetland soils currently exist within restoration areas and monitoring is not considered necessary to verify hydric soil requirements for a jurisdictional determination. 7.1 Hydrology Monitoring While hydrological modifications are being performed on the site, surficial monitoring wells will be designed and placed in accordance with specifications in U.S. Corps of Engineers', Installing Monitoring Wells/Piezometers in Wetlands (WRP Technical Note HY-IA-3.1, August 1993). Monitoring wells will be set to a depth 24 inches below the soil surface. pproximate 24 surficial monitoring wells will be imbedded within vegetation sampling plots to provide representataive coverage within each of the three wetland ecosystem types. Ecosystem types are depicted as community restoration map units (Figure 10) which support similar soils, landform, and target community, structure. Hydrological sampling will be performed throughout the growing season at intervals necessary to satisfy the hydrology success criteria within each community restoration area (EPA 1990). In order to substantiate the extent of floodplain restoration along the Perquimans River, a stream gauge will be placed in the adjacent tributary. Stream gauge data will determine the elevational reach and frequency of overbank flooding events. 7.2 Hydrology Success Criteria Target hydrological characteristics include saturation or inundation for at least 12.5% of the growing season at lower landscape positions, during average climatic conditions. Upper landscape reaches and areas near perimeter canals may exhibit surface saturation/inundation for between 5% and 12.5% of the growing season based on well data. These 5%-12% areas are expected to support hydrophytic vegetation within organic soils of low permeability. If wetland parameters are marginal as indicated by vegetation and hydrology monitoring, consultation with COE personnel will be undertaken to determine jurisdictional extent in these I tranSlL %J"G areas. i?Stream gauge data will be utilized, by flood event frequency and the elevation of each flood event, to substantiate the area of floodplain restoration. Stream gauge monitoring and floodplain area calculations will require average climatic condition including an average distribution of peak storm events. 1 43 7 .3 Vegetation Restoration monitoring procedures for vegetation are designed in accordance with EPA guidelines enumerated in Mitigation Site Type (MiST) documentation (EPA 1990) and COE Compensatory Hardwood Mitigation Guidelines (DOA 1993). A general discussion of the restoration monitoring program is provided. After planting has been completed in winter or early spring, an initial evaluation will be performed to verify planting methods and to determine initial species composition and density. Supplemental planting and additional site modifications will be implemented, if necessary. During the first year, vegetation will receive cursory, visual evaluation on a periodic basis to ascertain the degree of overtopping of planted elements by nuisance species. Subsequently, quantitative sampling of vegetation will be performed between August 1 and September 31 after each growing season until the vegetation success criteria is achieved. During quantitative vegetation sampling in early fall of the first year, 0.05 acre plots will be randomly placed with' a ch restored ecosystem type. Due to the homogeneity of the Dismal Swamp landscape, proximat y 48 plots (2.4 acre total) will be established to provide a 0.5% sample of there ration area. Sample plot distributions will be correlated with hydrological monitoring locations to provide point-related data on hydrological and vegetation parameters. In each 0.05-acre sample plot, vegetation parameters to be monitored include average tree height, species composition, density, and basal area. Visual observations of the percent cover of shrub and herbaceous species will also be recorded. 7.4 Vegetation Success Criteria Success criteria have been established to verify that the wetland vegetation component supports community components necessary for a jurisdictional determination. Additional success criteria are dependent upon the density and growth of characteristic forest species. Specifically, a minimum mean density of 320 characteristic tree species/acre must be surviving for at least 3 years after initial planting. _ rats CO planting plan along with natural recruitment of sweet gum, red maple, American sycamore, and loblolly pine. Loblolly pine (softwood species) cannot comprise more than 10% of the 320 stem/acre requirement. In addition, at least five other character tree species must be present, and no species can comprise more than 20% of the 320 stem/acre total. Supplemental plantings will be performed as needed to achieve the vegetation success criteria. 44 No quantitative sampling requirements are proposed for herb and shrub assemblages as part of the vegetation success criteria. Development of a swamp forest canopy over several decades and restoration of wetland hydrology will dictate the success in migration and establishment of desired wetland understory and groundcover populations. Visual estimates of the percent cover of shrub and herbaceous species and photographic evidence will be reported for information purposes. 7.5 Report Submittal An "as built" plan drawing of the area, including initial species compositions by community type, and sample plot locations, will be provided after completion of planting. A discussion of the planting design, including what species were planted, the species densities and numbers planted will also be included. The report will be provided within 90 days of completion of planting. Subsequently, reports will be submitted yearly to appropriate permitting agencies following each assessment. Submitted reports will document the sample transect locations, along with photographs which illustrate site conditions. Surficial well data will be presented in tabular format. The duration of wetland hydrology during the growing season will also be calculated within each community restoration map unit (Figure 10). The survival and density of planted tree stock will be reported. In addition, character tree mean density and average height as formatted in the Vegetation Success Criteria will be calculated. A visual estimate and photographic evidence of the relative percent cover of understory and groundcover species will be generated. 7.6 Contingency In the event that vegetation or hydrology success criteria are not fulfilled, a mechanism for contingency will be implemented. For vegetation contingency, replanting and extended monitoring periods will be implemented if community restoration does not fulfill minimum species density and distribution requirements. Hydrological contingency will require consultation with hydrologists and regulatory agencies in the event that wetland hydrology restoration is not achieved during the monitoring period. Recommendations for contingency to establish wetland hydrology will be implemented and monitored until the Hydrology Success Criteria are achieved. 45 8.0 MITIGATION CREDIT EVALUATIONS Figure 11 depicts mitigation design units generated through integration of mitigation design studies. Mitigation units identified include riverine wetland restoration (34 acres), riverine wetland enhancement (24 acres), nonriverine wetland restoration (394 acres), nonriverine wetland preservation/management (91 acres), upland forest restoration (12 acres), and wetland buffer restoration/establishment (adjacent to perimeter canals; 57 acres). Potential mitigation credit for the various design strategies should be determined based on wetland functional evaluations and a review of available research and literature. A summary of evaluation techniques and comparison of wetland functions between impacted and mitigation wetlands is provided. 8.1 Wetland Functional Evaluations Mitigation planning has been oriented towards replacing wetland functions diminished or lost due to widening of the subject segment of US 17 (R-2208A). Wetland restoration and enhancement strategies have been designed to exceed those functions believed to be present (and eventually lost) within the intended road widening corridor. A subjective wetland functional evaluation was undertaken on the mitigation site and impact areas to evaluate functional replacement needs. The study involved visual evaluations of hydrogeomorphic (HGM) wetland functions outlined in various research and project literature (Brinson 1994, ESI 1994a, ESI 1994b). Specific wetland functions evaluated are presented in Table 6. This assessment has been expanded in an effort to categorize functions into three primary areas: a) hydrodynamics; b) biogeochemical processes; and c) maintenance of biotic resources. Proposed mitigation seeks both spatial and functional replacement for impacted wetland resources. An objective I unctional r ses.Sndh **hWTT40 perform> dinate, through multivariate analysis, the range of wetland functions that occur within subject wetland classes. Reference wetland data sets e p M _ ce" for characteristic wetland functions. In addition, the I d. In this study, reference wetland systems were evaluated in the field by ecologists to discern the features present within relatively undisturbed (reference) wetlands. Subsequently, impacted wetlands and mitigation activities were subjectively compared to reference conditions as an indicator of differences in existing or projected wetland functions. Projected performance of wetland functions on the mitigation site was in -m condit?ortis ewp'? fifer mitigation activities are completed. ppw 46 © Riverine Floodplain Restoration - Wetland Preservation/Management - N Wetland Restoration - 34 Acres 91 Acres etlan Restoration - Upland Restoration - 12 Acres Wetland d Enhancement - 24 Acres 0 Wetland Restoration - 394 Acres ® Wetland Buffer Restoration - 57 Acres i aPa- 41 xi? Environmental Wetland Mitigation Figure: 11 Services, Inc. Design Units 1318 Dale Street Dismal Swamp Mitigation Site Project: ER94018.7 Suite 220 Gates and Perquimans Raleigh, NC 27605 Counties, NC Date: 13 Apr 1995 47 AC W a A d w W ? H WV as A? O H z w W H U W a w Q ? 1) O O bQ 4. 0 ? 3 N U ? O G am ° ° y ., v i CA O 1y a+ • " " • ° O ? RC ? i ? i b N ? 3 bA • ? U .. RC i a :? o c c°, c? LZ, O a? y . 6 0 Cd a? N 0 m 03 1-i 'b Q ?. col 'b al o an ° on ° ? 3 y _ V o ? 'o w w ° clk4 G 3 ? -c' 3 a a8i o ? U U .? 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L., ?.+ CC i > t ? . e+ M M 49 Reference Forest Ecosystem (RFE) areas within the adjacent Great Dismal Swamp Refuge were utilized as an indicator of maximum sustainable performance for characteristic wetland functions. Target functions have been identified based on the types of wetlands to be impacted; primarily nonriverine/interstream, temporarily saturated wetlands (PFO 1 A, PF01 /4A, PF04Ad) and riverine/bottomland, seasonally flooded wetlands (PF01 C, PFOI/2C). Nonriverine/interstream, temporarily saturated wetlands are the dominant wetland type likely to be impacted by US 17 widening (8.4 acres; Section III, Table 1). These systems currently provide limited hydrodynamic functions such as subsurface storage of water, moderation of groundwater flow, and surface water discharge. Limitations are primarily due to adjacent agricultural practices and the positioning of nonriverine wetlands along broad interstream flats, with precipitation representing the principal water source entering these wetlands (limited connectivity with surface waters). Biogeochemical functions (nutrient cycling, removal of elements from cropland drainage, and particulate retention) are somewhat more important because these systems may act as sumps which collect overland runoff from adjacent agricultural fields. However, both functions may have been jeopardized by farmland encroachment, soil compaction through mechanized logging, extensive ditching, and surrounding site disturbances. Community maintenance (structural integrity, habitat for wildlife, interspersion and connectivity with larger systems) is typically an important function of nonriverine forested wetlands. However, many of the impacted interstream wetlands in the US 17 corridor exhibit reduced community maintenance functions due to fragmentation and other impacts from human use. Mitigation has been proposed to provide spatial and functional replacement - and enhancement - for these functions. Nonriverine swamp forests will be restored through reestablishment of area hydrology and active planting on converted farmland at the Dismal Swamp mitigation site. Due to adjacency and connectivity of nonriverine restoration areas to the Perquimans River, important hydrodynamic functions expected after mitigation include moderation of groundwater flow and subsurface storage of water. The transformation of farmland adjacent to the tributary into seasonally to semi-permanently inundated wetlands will also maximize biochemical functions such as retention of particulates, removal of elements and compounds, and nutrient cycling. Retention features in the restored wetlands result primarily from spatial elimination of agricultural land immediately adjacent to the tributary. Although restored physical functions exceed those in impacted nonriverine systems, maximum sustainable performance for hydrodynamic and biochemical functions on the mitigation site may never be fully realized. Functional performance may be limited due to the presence of large drainage systems and canals in managed pine plantations upslope of the mitigation area. Diversion of regional groundwater flow into drainage systems and shunting of resulting surface water into area streams may decrease the capability of wetlands to store, retain, and filter surface and 50 groundwater components. However, restoration activities are expected to induce substantial changes in lateral surface/subsurface flow in restored agricultural areas. Biotic functions in nonriverine wetland restoration areas will include maintenance of habitat for certain terrestrial and semi-aquatic wildlife guilds. Species populations promoted include those dependent upon interspersion and connectivity with bottomland areas along with the need for forest interior habitat. These interstream functions are considered degraded along interstream wetland fringes impacted by US 17 widening. Habitat value and community maintenance functions will also be improved by creation and interconnection of four plant community types along the wetland/upland environmental gradient. Cover will be expanded and species diversity may be promoted within southern portions of the Great Dismal Swamp complex. Riverine/bottomland, seasonally flooded wetlands (PF01 C) represent the second most impacted wetland type in the US 17 corridor (3.3 acres; Section III, Table 1). Because bottomiand systems are typically situated immediately adjacent to area streams, these wetlands have the potential to provide significant hydrodynamic, biochemical, and community maintenance functions. PF01 C wetlands have the potential to attenuate floodflow, provide for long-term surf ace/subsurf ace water storage, moderate riparian groundwater discharge, and retain sediments or other elements. Habitat diversity and resulting species diversity is generally higher in bottomland wetlands. In the impact area, bottomland functions may have been compromised by channelization (which has reduced frequency, depth, and extent of over bank flooding) and through encroachment from agriculture However, these wetlands continue to represent a valuable resource for the region. Functional replacement is considered paramount. Mitigation provides for restoration and enhancement of a contiguous wetland area situated immediately adjacent to headwaters of the Perquimans river. The entire wetland site will function as a stream-side management zone (SMZ) with resultant benefits to the riverine system. Provisions for overbank flooding into relict floodplain areas of the mitigation site will also be facilitated. Historical drainage patterns and resultant benefits to bottomland systems will result. Restoration of hydrodynamic and biogeochemical processes in riverine and nonriverine systems should result in improvements to water quality in the below headwater tributary. In addition, the presence of contiguous, restored natural communities from upland sandhill forests to bottomland swamp forests will provide wildlife habitat of greater area-wide function than the collective sum of narrow crossings of impacted PFO1 C systems in the US 17 widening corridor. 51 8 .2 Mitigation Credit Evaluations As planned, US 17 (R2208A) construction will affect approximately three acres of riverine/bottomland wetlands (PF01 C, PF01 /2C) and 9 acres of nonriverine/interstream wetlands (PF01 /4A, PF04Ad), for a total of 12 acres of expected impacts. Most of these impacted systems exhibit functional attributes which have been reduced or diminished through fragmentation, ditching, farm ing/silvicultural activities, or other land use practices. A ditch impact study is currently underway to determine the indirect affects associated with construction of drainage ditches along the US 17 alignment. If additional wetland impacts are found to occur, this additional acreage will also be mitigated at the proposed Dismal Swamp site under supplemental documentation. Approximately 612 acres are being offered for R-2208A mitigation needs and as a mitigation bank for future transportation projects. Restoration and enhancement strategies are designed to create riverine and nonriverine wetland ecosystems which support an array of native plant and wildlife communities. Site hydrology will be restored and native wetland communities will be reestablished. Connectivity with the Great Dismal Swamp complex and adjacency to the Perquimans River afford opportunities which go beyond enhancement of on-site wetland functions. Restoration and enhancement strategies will contribute to regional diversity as well. Integration of wetland and upland interfaces are an important part of this mitigation plan. Wetland buffers will be restored along remaining canals, offering an ecological gradient from uplands to wetlands and providing for ecotonal fringes. "gMeMsImemmemwill re *09 t df,dW car a'n'?iander it"thTag"nxo 1. of pliilIdik -80-4 'g rive"- anks and _. , ' ra,diths. Without upland restoration/enhancement and wetland „ -a- buffer establishment, intrinsic functions in adjacent, restored components may be diminished or lost. The acreages for each Dismal Swamp mitigation design/credit map unit (Figure 11) are summarized in the following table: Mitigation Strategy Nonriverine Wetland Restoration Riverine Wetland Restoration Riverine Wetland Enhancement Nonriverine Wetland Preservation/Management Wetland/Upland Ecotone Restoration Wetland Buffer Restoration (Adjacent to perimeter canals) TOTAL Acreage 394 34 24 91 12 57 612 52 Based on the proposed mitigation strategy, hydrogeological modeling results, subjective wetland functional evaluations, and current research, this mitigation project is expected to meet and exceed mitigation needs associated with US 17 widening. After debiting for the R- 2208A project, remaining credits will be available for projects in the region which impact wetlands of comparable type and function. It is expected that excess credits from the Dismal Swamp site will be developed into a regional mitigation bank, with appropriate protocols established for use and debiting of the bank. 53 9.0 DISPENSATION OF PROPERTY NCDOT is in the process of soliciting conservation groups and natural resource agencies for final dispensation of properties. Representatives from the N.C. Wildlife Resources Commission (WRC) and the U.S. Fish and Wildlife Services have visited the site. At present, WRC is considered the most appropriate recipient of the land for incorporation into the state gamelands program. Transfer of the property will occur upon implementation of the proposed mitigation strategy. The NCDOT will remain responsible for meeting success criteria established in the mitigation plan. Stipulations will be incorporated into the deed upon transfer to the accepting resource agency to insure that the property remains as conservation land in perpetuity. 54 10.0 REFERENCES CITED Adamus P.R., L.T. Stockwell, E.J. Clairain Jr., M.E. Morrow, L.P. Rozas, R.D. Smith. 1991. Wetland Evaluation Technique (WET), Volume 1: Literature Review and Evaluation Rationale. Wetlands Research Program Technical Report WRP-DE-2. U.S. Army Corps of Engineers Waterways Experiment Station. Vicksburg, MS. Adamus, P.R., E.J. Clairain, Jr., R.D. Smith, and R.E. Young. 1987. "Wetland Evaluation Technique (WET); Volume II: Methodology," Operation Draft Technical Report Y-87-_ U.S. Army Engineer Waterways Experiment Station, Vicksburg, Mississippi. Adamus P.R., L.T. Stockwell. 1983. A Method for Wetland Functional Assessment, Volume 1. Critical Review and Evaluation Concepts. Federal Highway Administration Report no. FHWA-IP-82-23. U.S. Department of Transportation, Washington, D.C. Baumer, 0. and J. Rice. 1988. Methods to predict soil input data for DRAINMOD ASAE Paper No. 88-2564. ASAE, St. Joseph, MI 49085. Beals, E.W. 1984. Bray-Curtis Ordination: an Effective Strategy for Analysis of Multivariate Ecological Data. Advances in Ecological Research, Volume 14. Academic Press, Inc. Belcher, H. W. and G. E. Merva, 1987, Results of DRAINMOD verification study for Zeigenfuss, soil and Michigan climate. ASAE Paper No. 87-2554. ASAE, St. Joseph, MI 49085. Brinson, M.M. 1993. A Hydrogeomorphic Classification for Wetlands. Wetlands Research Program Technical Report WRP-DE-4. U.S. Army Corps of Engineers, Washington, DC. Brinson, M.M., F.R. Hauer, L.C. Lee, R.P. Novitzki, W.L. Nutter, and D.F. Whingham. 1994. Guidebook for Application of Hydrogeomorphic Assessments to Riverine Wetlands. The National Wetlands Science Training Cooperative. Seattle, WA. Brinson M., B. Swift, R. Plantico, J. Barclay. 1981. Riparian Ecosystems: Their ecology and status. U.S. Fish and Wildlife Service FWS/OBS 81/17 Brower, J.E., J.H. Zar, and C. N. von Ende. 1990. Field and Laboratory Methods for General Ecology. William C. Brown Publishers, Debuque, IA. Brown, Philip M., et al, 1985, Geologic Map of North Carolina, North Carolina Department of Natural Resources and Community Development, 1-.500,000 scale. 55 Castelle, A.J. et a/. 1992. Wetland Mitigation Ratios: defining equivalency. Shorelands and Coastal Zone Management Program, Washington State Department of Ecology. Olympia, WA. U.S. Army Corps of Engineers (COE). 1993. Corps of Engineers (COE). WRP Technical Note HY-IA-3.1 August 1993, Waterways Experiment Station, COE, Vicksburg, Mississippi. Cooper, H. H., Jr., J. D. Bredehoft, and I. S. Papadopoulos. 1967. Response of a finite- diameter well to an instantaneous charge of water. Water Resources Research, 3, pp 263-269. Cowardin, L.M., V. Carter, F. C. Golet, and Edward T. Laroe. 1979. Classification of Wetland and Deepwater Habitats of the United States. Fish and Wildlife Service, U.S. Department of Interior. Department of the Army (DOA). 1993 (unpublished). Corps of Engineers Wilmington District. Compensatory Hardwood Mitigation Guidelines (12/8/93). Department of the Army (DOA). 1987. Corps of Engineers Wetland Delineation Manual. Tech. Rpt. Y-87-1, Waterways Experiment Station, COE, Vicksburg, Mississippi. Department of Natural Resources and Community Development (DNR). 1985. Geologic Map of North Carolina. NC Geological Survey. Environmental Protection Agency (EPA). 1990. Mitigation Site Type Classification (MIST). A methodology to classify pre-project mitigation sites and develop performance standards for construction and restoration of forested wetlands. EPA Workshop, August 13-15, 1989. EPA Region IV and Hardwood Research Cooperative, NCSU, Raleigh, North Carolina. Environmental Services, Inc. (ESI). 1994a; unpublished. Determination of applicable mitigation credit For restoration of wetland buffers and wetland/upland ecotones: US 64 wetland restoration and conservation management plan, US 64 relocation, Martin and Edgecombe Counties, North Carolina. Provided to the N.C. Department of Transportation. Environmental Services, Inc. (ESI). 1994b; unpublished. Mitigation Plan: Northeast Florida Wetland Mitigation Bank. Technical Report for St. Johns River Water Management District, Palatka Fla. 56 Federal Interagency Committee for Wetland Delineation (FICWD). 1989. Federal Manual for Identifying and Delineating Jurisdictional Wetlands. U.S. Army Corps of Engineers, U.S. Environmental Protection Agency, U.S. Fish and Wildlife Service, and U.S.D.A. Soil Conservation Service, Washington, D.C. Cooperative Technical Publication. 76 pp. plus appendices. Fouss, J. L., R. L. Bengtson and C. E. Carter, 1987, Simulating subsurface drainage in the lower Mississippi Valley with DRAINMOD. Transactions of the ASAE 30 (6)-. 1679 - 1688. Gantt, L.K. and D.A. Dell. 1992. Two Case Studies in Mitigation Banking: Can We Afford It? Pp. 180-187 in T.A. Kusler and C. Lassonde (eds). Proceedings from a National Wetland Symposium: Mitigation Banks and Joint Projects in the Context of Wetland Management Plans. Palm Beach Gardens, FL. June 24-27, 1992. Gayle, G., R. W. Skaggs and C. E. Carter, 1985, Evaluation of a water management model for a Louisiana sugar cane field. J. of Am. Soc. of Sugar Cane Technologists, 4: 18 - 28. Hvorslev, M. J. 1951. Time lag and soil permeability in groundwater observations. U.S. Army Corps of Engineers Waterways Experimental Station Bulletin 36, Vicksburg, MS. Jones, S.M. 1989. Application of Landscape Ecosystem Classification in Identifying Productive Potential of Pine-Hardwood Stands. (in) Pine-Hardwood Mixtures: a Symposium on Management and Ecology of the Type. Waldrop, T.E. (ed). Southeastern Forest Experiment Station, Asheville, NC. Karr, J.R., I.J. Schlosser. 1978. Water resources at the land-water interface. Science 201:229-234. Keller, M.E., C.S. Chandler, and J.S. Hatfield. 1993. Avian communities in riparian forests of different widths in Maryland and Delaware. Wetlands 13(2): 137-144, Special Issue, June 1993. The Society of Wetland Scientists. Laney, R.W., D.L. Stewart, G.R. McCrain, C. Mayer and V. Bruton. 1988. Final report on the North Carolina Department of Transportation Company Swamp Mitigation Bank, Bertie County, North Carolina. U.S. Department of the Interior, FWS, Raleigh, NC. 58 p. McCrain, G.R. 1992. Habitat Evaluation Procedures (HEP) applied to mitigation banking in North Carolina. Journal of Environmental Management. 35:153-162. 57 . 1994 Mitigation Ratios in the Southeast. Paper presented at the Annual Symposium. Society of Wetland Scientists, May 31-June 3, 1994. Portland Oregon. Neffsinger, R.E., R.W. Laney, A.M. Nichols, D.L. Stewart, D.W. Steffeck. 1984. Prulean Farms,lnc., Dare County, North Carolina. A Fish and Wildlife Coordination Act Report. U.S. Department of Interior, Fish and Wildlife Service, Raleigh, NC. 200 p. Page, R.W. and L.S. Wilcher. 1990. Memorandum of Agreement Between the EPA and the DOE Concerning the Determination of Mitigation Under the Clean Water Act, Section 404(b)(1) Guidelines. Washington, DC. Peet, R.K., Christensen, N.L. 1980. Hardwood Forest Vegetation of the North carolina Piedmont. Veroff. Geobot. Inst. ETH, Stiftung Rubel, Zurich 69. Heft (1980), 14-39. Rogers, J. S., 1985, Water management model evaluation for shallow sandy soils. Transactions of the ASAE 28 (3): 785-790. Sacco, J.B. 1990. Infaunal Community Development of Artificially Established Salt Marshes in North Carolina. Master's Thesis. N.C. State University, Raleigh, NC Schafale, M.P. and A.S. Weakley. 1990. Classification of the Natural Communities of North Carolina: Third Approximation. NC Natural Heritage Program, Division of Parks and Recreation, NC Department of Environment, Health, and Natural Resources, Raleigh, NC. Skaggs, R. W., 1980, A water management model for artificially drained soils. Tech. Bull. No. 267, North Carolina Agricultural Research Service, N.C. State University, Raleigh. 54 pp. Skaggs, R. W., 1982, Field evaluation of a water management simulation model. Transactions of the ASAE 25 (3): 666 - 674. Skaggs, R. W., N. R. Fausey and B. H. Nolte, 1981, Water management evaluation for North Central Ohio. Transactions of the ASAE 24 (4): 922 - 928. Skaggs, R. W., J. W. Gilliam and R. 0. Evans, 1991, A computer simulation study of pocosin hydrology. Wetlands (1 1): 399 - 416. Skaggs, R.W., et a[, 1993, Methods for Evaluating Wetland Hydrology. ASAE meeting presentation Paper No. 921590. 21 p. 58 Susanto, R. H., J. Feyen, W. Dierickx and G. Wyseure, 1987, The use of simulation models to evaluate the performance of subsurface drainage systems. Proc. of Third International Drainage Workshop, Ohio State Univ., pp. A67 - A76. U.S. Department of Agriculture (USDA). 1986. Soil Survey of Chowan and Perquimans Counties, North Carolina, USDA Natural Resource Conservation Service. U.S. Department of Agriculture (USDA). 1994 (unpublished). Soil Survey of Gates County, North Carolina, USDA Natural Resource Conservation Service. U.S. Department of Agriculture (USDA). 1987. Hydric Soils of the United States. In cooperation with the National Technical Committee for Hydric Soils, USDA Natural Resource Conservation Service. U.S. Department of Interior (USDI). 1980. Hbitat evaluation procedures. Fish and wildlife Service, Division of Ecological Services, Washington, DC. 102 ESM. U.S. Fish and Wildlife Service (USFWS). 1981. Habitat Evaluation Procedures Workbook. National Ecology Research Center. Van Lear D.H., Jones S.M. 1987. An example of site clasiification in the southern coastal plain based on vegetation and land type. Southern Journal of Applied Forestry. 11(1):23-28. Ward, L. W., Bailey, R. H., Carter, J. G., 1991, "Pliocene and Early Pleistocene Stratigraphy, Depositional History, and Molluscan Paleobiology of the Coastal Plain." in The Geology of the Carolinas, J. Wright Horton, Jr., and Victor A. Zullo, eds. The University of Tennessee Press, Knoxville TN. 59 11.0 APPENDICES HYDROGEOLOGICAL SITE ASSESSMENT FOR GREAT DISMAL SWAMP MITIGATION SITE GATES - PERQUIMANS COUNTIES ESI Job No.: ER94-018.2(8-2208A) Prepared for: N.C. Department of Transportation 1 South Wilmington St. Raleigh, NC 27601 Prepared by: ENVIRONMENTAL SERVICES, INC. 1318 Dale St., Suite 220 Raleigh, NC 27605 TEL (919) 833-0034 FAX (919) 833-0078 March, 1995 HYDROGEOLOGICAL SITE ASSESSMENT FOR GREAT DISMAL SWAMP MITIGATION SITE GATES - PERQUIMANS COUNTIES ESI Job No.: ER94-018.2 Prepared for: North Carolina Department of Transportation 1 South Wilmington St. Raleigh, North Carolina 27601 Issue Date: 31 March 1995 Gerald R. McCrain, Ph.D., CEP Vice President Brian L. Hayes, P.G. Senior Hydrogeologist Signature Signature ENVIRONMENTAL SERVICES, INC. 13 18 Dale St., Suite 220 Raleigh, North Carolina 27605 TEL (919) 833-0034 FAX (919) 833-0078 C:\ W PTEXT94\ESI\PROJECT\ER94.018.2\G WMOOL.REP iy. TABLE OF CONTENTS LIST OF FIGURES 1. EXECUTIVE SUMMARY ........................................ iii 1.0 INTRODUCTION ..............................................1 1.1 Background ............................................... 1 2.0 SITE CHARACTERIZATION ACTIVITIES .............................. 4 2.1 Exploratory Soil Borings and Observation Well Installation ............. 4 2.2 Hydraulic Conductivity Testing ................................ 4 2.3 Water Level Measurements .................................. 5 2.4 Surveying .............................................. 5 3.0 GEOLOGY AND HYDROGEOLOGY ................................. 7 3.1 Regional Geology ...................................... 7 3.2 Local Geology ........................................... 7 3.3 Regional Hydrogeology ..................................... 8 3.4 Local Hydrogeology ....................................... 8 4.0 GROUNDWATER MODELING & RESULTS ............................ 18 4.1 Groundwater Model ...................................... 18 4.2 Model Description ....................................... 19 4.3 Model Calibration ........................................ 19 4.4 Model Results .......................................... 21 5.0 RECOMMENDED SITE ALTERATIONS TO PROMOTE WETLAND HYDROLOGY .. 23 5.1 Recommendations For Filling Drainage Ditches ................... 23 5.2 Recommendations for Site Grading ............................ 23 6:0 REFERENCES CITED ........................................... 25 LIST OF FIGURES Figure 1 - Location map, Dismal Swamp proposed mitigation tract ............................................. 2 Figure 2 - Well location map ..................................... Attached Figure 3- Geologic cross sections fo selected transects .................. Attached Figure 4 - Groundwater flow, December 8, 1994 ............................. 9 Figure 5 - Groundwater flow, December 13, 1994 ...................... ..... 10 Figure 6 - Groundwater flow, December 20, 1994 ...................... ..... 11 Figure 7 - Groundwater flow, December 28, 1994 ...................... ..... 12 Figure 8 - Groundwater flow, January 5, 1995 ........................ ..... 13 Figure 9 - Groundwater flow, January 10, 1995 ....................... ..... 14 Figure 10 - Groundwater flow, January 18, 1995 ...................... ..... 15 Figure 11 - Groundwater flow, January 25, 1995 ...................... ..... 16 Figure 12 - Conceptualized grading of site for restoration ................. Attached Figure 13 - Estimated boundaries of wetland restoration (5 cm surface storage) ......................................... Attached Figure 14 - Estimated boundaries of wetland restoration (10 cm surface storage) ........................................ Attached Figure 15 - Estimated maximum extent of seasonal flooding ............... Attached LIST OF TABLES Table 1 - Groundwater measurement and water table elevations - Dismal Swamp mitigation site ................................. 6 Table 2 - Soil input parameters ........................................ 20 Table 3 - Results of DRAINMOD simulations for saturation within 30 cm of surface for selected percentages of the growing season (surface storage = 5 cm) ......... 22 Table 4 - Results of DRAINMOD simulations for saturation within 30 cm of surface for selected percentages of the growing season (surface storage = 10 cm) ........ 22 HYDROGEOLOGICAL SITE ASSESSMENT FOR GREAT DISMAL SWAMP MITIGATION SITE GATES - PERQUIMANS COUNTIES 1. EXECUTIVE SUMMARY Environmental Services Inc.(ESI), was contracted by North Carolina Department of Transportation (NCDOT) Planning and Environmental Branch to conduct a hydrogeological site assessment of two tracts of land in Gates and Perquimans Counties, North Carolina which NCDOT held an option to purchase and subsequently purchased . The two tracts are located adjacent to one another and cross the boundaries between the counties . The total acreage of the subject properties is 611 acres, of which approximately 115 acres consist of forested jurisdictional wetlands . The remainder of the properties are comprised of prior converted farmlands which have been drained by a series of ditches and canals. ESI conducted the hydrogeological assessment as part of the development of a comprehensive mitigation plan . In order to characterize existing conditions ESI performed a series of exploratory soil borings and installed a series of 26 shallow observation wells to obtain data on site stratigraphy and current depths to groundwater. Soil samples were collected from the soil borings. Selected samples were submitted for analysis to a soils laboratory to confirm field classification. Hydraulic conductivity tests were conducted on 20 of the wells to determine aquifer characteristics. Water level measurements were collected over an eight week period and were used to construct groundwater flow maps to determine current flow direction and hydraulic gradients on the site. The collected data was used to develop input parameters for DRAINMOD, a computer model developed for simulating the effect of drainage systems on soils with a shallow water table. The model can also be used to forecast the presence of wetland hydrology in these same soils. The input parameters were calibrated against existing data and a series of simulations were run to predict the occurrence and duration of saturation in the top 12 inches (30 cm) of soil under various conditions. The model outputs indicate that saturation for at least 12.5 % of the growing season would be achieved for all but approximately 80 acres of the prior converted farmlands by effectively filling the central drainage canals and lateral feeder ditches and scarifying the surface soils to increase surface storage on site. The data collected also indicates that a significant portion of the property should be subject to overbank flooding following the completion of restoration activities. HYDROGEOLOGICAL SITE ASSESSMENT FOR GREAT DISMAL SWAMPMITIGATION SITE GATES - PERQUIMANS COUNTIES 1.0 INTRODUCTION The North Carolina Department of Transportation (NCDOT), Planning and Environmental Branch obtained an option to purchase two tracts of land in Gates and Perquimans Counties for the purpose of creating a mitigation bank for wetlands. Environmental Services, Inc (ESI) was retained by NCDOT to conduct a preliminary site assessment (PSA) in October 1994. The PSA was conducted to determine if the site could be restored to wetland conditions through appropriate hydrological modification. The results of the PSA are presented in a letter report dated 4 November 1994. Based upon the results of the PSA, NCDOT retained ESI to conduct a detailed site assessment of the properties. This report documents ESI activities to characterize the hydrogeological site conditions, including soil boring and well installation, slug testing, water level measurements, and groundwater modeling. Based upon the data collected and the results of analysis, this report presents conclusions and makes recommendations. 1.1 Backaround The subject properties consist of two tracts of land comprised of 304 acres and 307 acres for a total of 611 acres. The land is located in southern Gates and northern Perquimans County, as shown in Figure 1. The northern tract (Tract 1) consists of 304 acres which has been cleared, ditched, drained, and used primarily for tree plantations in the past, and various agriculture activities through 1994. The southern tract (Tract 2) consists of 307 acres which has been cleared, ditched and drained on the eastern two-thirds of the tract. The tracts are divided by a road trending east-west with drainage canals on either side of the road. The ditched portion of the tract has also been used for tree plantations in the past as well as agriculture activities through 1994. The drainage system was originally installed by Weyerhauser to facilitate the commercial growth and harvest of pine trees. The subject property is bordered on the north by land owned by Weyerhauser, as a pine plantation. The property is bordered on the east by formerly cultivated lands leased by a hunt club at the time of the assessment. The property is bordered on the south by agricultural lands owned by D. T. Hurdle. The property is bordered on the west by forested lands owned by Clyde Stallings which are part of the Great Dismal Swamp. The cleared and cultivated portions of the tracts are considered Prior Converted (PC) farmlands and currently are not under jurisdictional control of the U.S. Army Corp of Engineers at this time. The property was selected by NCDOT to serve as a mitigation bank for offsetting the impact of road construction on other wetlands. The primary impetus was the need for mitigation for project R-2208A, an improvement of US -17, with the expectation of excess credits to apply to subsequent projects in the region. 1.2 Scone of Work Based upon EST's proposal dated 18 November 1994, the scope of work for this project is as follows: 158 3 -7- _ E \ ?t _ 7C1 a 6- ! . it f? // -- __?? ,%? ?) ?? • a ``?? Mitigation Site ',1 1:. ? - ? ~. 1 G?.SfSj - _? . _{ ]' ?_.. i_. i 11 eN+ I I 1 ...11.; f: r •11 iZ ? `I dr `? Y ?`• G.rww ar G•.?. ? ? • P ? ? a \? ? i / ' 1 1 1 i . \ ' '•1- 1 . p X7\ __? roar - O rl <_ 1w? ; ? ?__- -- 4 rF I ' ? ?'? ? , V ??„ car • ?q ?•?? ' • ?\` ?`il ? 10 gg / _ ? ? t ? ? rY? i ? / ?w / ? 1 11 10 W,? I It i M _T._. kft .r ?? „.. I ? 'k Tom- ? 1 _ - f i N Study Area ,. 0 I 2 3 MILES L ? Source: DeLortne MappiM 1992 1 ?' F 40, _ J4••.N /( RF`I ?,?? Figure: Environmental Location Map Services, Em Dismal Swamp y tiwf 1318 Dale Street Proposed Mitigation Tract Project: ER94018.2 C :: Mt Suite 220 Gates and Perquimans Counties, Raleigh, NC 27605 North Carolina Date: 24 Jan 95 2 • Delineate the boundaries of jurisdictional wetlands. This determination will be confirmed with the U.S. Army Corps of Engineers • Install a series of soil borings and a network of observation wells to characterize subsurface conditions, including aquifer tests at each well. • Collect groundwater elevation data from the wells on a weekly basis for a two month period in order to evaluate fluctuations in the water table at the site. • Model current groundwater conditions on site, using DRAINMOD and project conditions on the site for various interventions to restore the prior converted portions of the tract to wetland conditions. Dr. George Chescheir of North Carolina State University in Raleigh, NC, was consulted to assist with modelling and to verify results. • Characterize existing vegetation on adjacent forested wetlands by means of field analysis, botanical surveys, biological reports, or aerial/ground photography. Target vegetation species and densities for the proposed mitigation shall be developed. • Prepare a report documenting site conditions the results of the modeling effort, and recommendations for the most cost effective methods for hydrological restoration. The report will specify target conditions for the site for both hydrological and vegetative restoration. The report will also contain a monitoring plan to evaluate achievement of the target conditions. NCDOT arranged for the soil mapping conducted, through the North Carolina Department of Health, Environment, and Natural Resources (DEHNR) Division of Soil and Water to determine the hydric/non-hydric soils boundaries. NCDOT was also responsible for all surveying aspects related to the project, and obtaining access to adjoining properties, and scheduling the mapping and surveying efforts within the time constraints of the project 2.0 SITE CHARACTERIZATION ACTIVITIES To fully understand existing conditions at the subject property, ESI personnel conducted the following activities. ESI installed a series of soil borings and converted the borings into observation wells. Following completion of the wells, slug tests were performed to determine hydrological properties. Water level measurements were collected over an eight week period in order to evaluate fluctuations of the water table. The site was surveyed by another consulting firm, as a subcontractor to NCDOT and a topographic map was prepared by NCDOT Photogrammetry. These activities are more fully discussed in the following sections. 2.1 Exaloratory Soil Borings and Observation Well Installation A series of 26 observation wells were installed on the subject property between 21 November and 8 December 1994. The locations of which are shown on Figure 2 (attached). Wells PZ-1 through PZ-12 were installed by means of an all-terrain vehicle mounted Geoprobe rig. Wells PZ-13 through PZ-21, and WP-1, EP-1 through EP-3, and HP-1 were installed using a hand auger. The locations were chosen to provide full coverage of the site, and to install at least one observation well in each soil type represented. PZ-1 through PZ-21 were installed on the subject property. The remaining wells were installed to collect data from locations beyond the boundaries of the tract subsequent to NCDOT obtaining access from the owners. The Geoprobe borings were sampled continuously from the surface on two-foot centers to a depth of 12 feet except for PZ-9 and PZ-12, which were sampled to a depth of 20 feet. The remaining borings were installed to a depth where caving prevented advancing the boring deeper The hand auger borings were sampled at each observed change in color, texture, and consistency. The boring logs are presented in Appendix A. Nine soil samples were submitted for particle-size analysis, and three were also tested for plasticity index to confirm the field classification with the Unified Soil Classification (USC) System. The results are presented in Appendix B. Following the completion of the soil boring, an observation well was installed in each well. The well consisted of a five foot section of one-inch inner diameter (ID) flush threaded machine-slotted schedule 40 PVC screen, and one-inch inner diameter (ID) flush threaded schedule 40 PVC riser, except at PZ-1 where a 10 foot section of screen was installed. Following the installation of the PVC screen and riser a filter pack consisting of clean coarse sand(#2 DOT or equivalent) was emplaced in the annulus. A six-inch bentonite seal was emplaced above the filter pack. The details of the well construction are presented on the boring logs in Appendix A. 2.2 Hydraulic Conductivity Testing Following the completion of well installation, the wells were tested to determine the hydraulic conductivity of the soils at the site. The tests were conducted using a slug test method, which measures the response of the saturated zone to a localized, induced stress. The tests were conducted in the following manner: the static depth to water was measured in the well, a quantity of distilled water was then added to the well to bring the water level in the PVC up to the top of the riser, the resulting fall in water level with time were recorded . The time- recovery data was then analyzed using methods given by Hvorslev0 951) and Cooper, Bredehoeft, and Papadapoulos(1967). Slug tests were conducted on wells PZ-1 through PZ- 20. The data and calculations from the slug testing are presented in Appendix C. 4 2.3 Water Level Measurements Water level measurements were taken in the observation wells during a period from 8 December 1994 to 25 January 1995, weekly. The ground water data is summarized in Table 1. The water level measurements were collected by use of an SINCO, Model 51453 Water Level Indicator graduated to 0.01 feet. 2.4 Surveying The North Carolina Department of Transportation (NCDOT) was responsible for having the site surveyed and preparing a topographic base map. NCDOT was also responsible for having the hydric/non-hydric soil boundaries delineated and located by means of the Global Positioning Satellite (GPS) System. A boundary and topographic survey were conducted by another consulting firm in December 1994. An aerial photography mission was flown by NCDOT Photogrammetry on 8 December 1994. The hydric soils boundaries were flagged by North Carolina Department of Environment, Health and Natural Resources (NCDEHNR) Division of Soil and Water. Using the data from these sources, NCDOT Photogrammetry produced a topographic base map and accompanying files on diskettes on 15 February 1995. These files were used to generate the figures presented in this report. 3W N C O W Q) N 4) H N t0 J t0 m p C. ~ E 3 a? N N is c0 E 01 y O c 0 0 V . 4 46 n M 4 4t6 to W v W M ' M 4 4 W 4 4 W SO ui loo W I W I W II 0 I't 10, I-M I- Im I l l 1?! Ico 10, IN I Ic, IN I 1 Io I 1., Io IF II W CO LO M Lo co I* LO I I a?Iv w(^I M I'I'I W I W I W I'tI W M 'IM I'I't W.I'I'IW IW I0 mIW I'D II F- ? 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( LI a > .- w O N M It w W n CO M O N M u) tp ^ W W N N N M a N N N N N N N N N fV N N N N N N N N fV N N w w w 3 = m a a a a a o. a a. a a a n, o. a a a a a. a s a. N E Z m t0 m N C cc m E m > O 0 N m C C O t0 > w 6 3.0 GEOLOGY AND HYDROGEOLOGY 3.1 Regional Geology The subject property is located in the Atlantic Coastal Plain Physiographic Province of North Carolina. The Coastal Plain extends from the Fall Zone located near Roanoke Rapids, North Carolina, which forms the boundary with the Piedmont Plateau in the west, to the Outer Banks in the east. The Coastal Plain is comprised of sediments deposited since the Cretaceous Period, 138 million years before present(m.y.B.P.), to the present. The sediments were deposited during a series of transgressions and regressions of the Atlantic Ocean. The subject property is located within a portion of the Coastal Plain referred to as the Lower or Outer Coastal Plain. The Outer Coastal Plain extends from Suffolk Scarp, a paleo-shoreline, to the Atlantic Ocean. The North Carolina Geological Map (Brown et al., 1985) describes the primary geologic unit as Quaternary Age (from 2 m.y.B.P. to the present) surficiai deposits. These deposits consist of sand, clay, gravel, and peat deposited in marine, fluvial, eolian and lacustrian environments. Generally these sediments are not present at elevations greater than 25 feet above mean sea level, which is the approximate elevation of the Suffolk Scarp. The Surficial Deposits are rarely more than 25 feet deep and are most likely underlain by sediments of Miocene Age (Stuckey, 1958). The Quaternary Deposits are underlain by the Yorktown Formation of Miocene age ( 5 to 24 m.y.B.P.), which is described as a bluish gray fossiliferous clay with varying amounts of fine grained sand, and shell material commonly concentrated in lenses (Brown et al., 1985). In North Carolina the sediments of the Atlantic Coastal Plain generally dip to the east or southeast, and the thickness increases from west to east (Stuckey, 1958). 3.2 Local Geology The subject property is located within the southern portion of the Great Dismal Swamp. The surficial soils encountered were organic soils (Histosols) and organic mineral 'soils (Umbraquults), with two small inclusions of nonhydric soils in the southern portion of the tract. The classification was conducted by the Natural Resources Conservation Service (NRCS), and a summary of their description is given below. Soil phases mapped by the NRCS as occurring on the site include the Scuppernong/Belhaven series (Terric Medisaprists), the Arapahoe series (Typic Humaquepts), the Icaria series (Typic umbraquu/ts), the Leon/Lynn Haven series (Aeric to Typic Haplaquods), and the Echaw series (Entic Hap/ohumods). Series represented by two names are typically similar soil map units that occur on either side of the county line. Hydric soil series consist primarily of poorly drained to very poorly drained mucks or loamy sands with high to very high organic content, strongly to extremely acidic conditions, and moderate to low permeability. The only non-hydric map unit observed on the site is the Echaw Series, situated primarily within the southern portions of the site. This area consists of a minor, slightly elevated sand rim with a seasonable high water table at approximately three feet below the surface. Map units identified by the NRCS were evaluated during preliminary field surveys. NRCS mapping of hydric/non-hydric soil boundaries appears to be fairly accurate. The organic content, and subsurface texture of hydric soil areas varies considerably between sample points 7 3.0 GEOLOGY AND HYDROGEOLOGY 3.1 Regional Geology The subject property is located in the Atlantic Coastal Plain Physiographic Province of North Carolina. The Coastal Plain extends from the Fall Zone located near Roanoke Rapids, North Carolina, which forms the boundary with the Piedmont Plateau in the west, to the Outer Banks in the east. The Coastal Plain is comprised of sediments deposited since the Cretaceous Period, 138 million years before present(m.y.B.P.), to the present. The sediments were deposited during a series of transgressions and regressions of the Atlantic Ocean. The subject property is located within a portion of the Coastal Plain referred to as the Lower or Outer Coastal Plain. The Outer Coastal Plain extends from Suffolk Scarp, a paleo-shoreline, to the Atlantic Ocean. The North Carolina Geological Map (Brown et at, 1985) describes the primary geologic unit as Quaternary Age (from 2 m.y.B.P. to the present) surficial deposits. These deposits consist of sand, clay, gravel, and peat deposited in marine, fluvial, eolian and lacustrian environments. Generally these sediments are not present at elevations greater than 25 feet above mean sea level, which is the approximate elevation of the Suffolk Scarp. The Surficial Deposits are rarely more than 25 feet deep and are most likely underlain by sediments of Miocene Age (Stuckey, 1958). The Quaternary Deposits are underlain by the Yorktown Formation of Miocene age ( 5 to 24 m.y.B.P.), which is described as a bluish gray fossiliferous clay with varying amounts of fine grained sand, and shell material commonly concentrated in lenses (Brown et at, 1985). In North Carolina the sediments of the Atlantic Coastal Plain generally dip to the east or southeast, and the thickness increases from west to east (Stuckey, 1958). 3.2 Local Geology The subject property is located within the southern portion of the Great Dismal Swamp. The surficial soils encountered were organic soils (Histosols) and organic mineral 'soils (Umbraquults), with two small inclusions of nonhydric soils in the southern portion of the tract. The classification was conducted by the Natural Resources Conservation Service (NRCS), and a summary of their description is given below. Soil phases mapped by the NRCS as occurring on the site include the Scuppernong/Belhaven series (Terric Medisaprists), the Arapahoe series (Typic Humaquepts), the Icaria series (Typic umbraquults), the Leon/Lynn Haven series (Aeric to Typic Haplaquods), and the Echaw series (Entic Haplohumods). Series represented by two names are typically similar soil map units that occur on either side of the county line. Hydric soil series consist primarily of poorly drained to very poorly drained mucks or loamy sands with high to very high organic content, strongly to extremely acidic conditions, and moderate to low permeability. The only non-hydric map unit observed on the site is the Echaw Series, situated primarily within the southern portions of the site. This area consists of a minor, slightly elevated sand rim with a seasonable high water table at approximately three feet below the surface. Map units identified by the NRCS were evaluated during preliminary field surveys. NRCS mapping of hydric/non-hydric soil boundaries appears to be fairly accurate. The organic content, and subsurface texture of hydric soil areas varies considerably between sample points 7 within hydric map units. Diversity may be partially due to the influences of artificial drainage and agriculture on the site. The removal of semi-permanent anaerobic soil conditions has accelerated the rate of decomposition and subsequently decreased the content of organic matter in surface soil horizons. The surficial soils were generally underlain by fine sands with layers of clayey fine sands. The clayey sands ranged in thickness from just under one foot thick to at least seven feet thick at PZ-10. In the two borings extended to 20 feet , a fine sand was encountered from a depth of one foot to a depth of 19 feet where a clay seam was encountered extending to the bottom of the hole at PZ-9, while at PZ-12, two seams of clayey sand were encountered at seven to nine feet, and 12 to 14 feet. Saturated soils were encountered at depths ranging from one to three feet below land surface. The soils encountered below the organic-rich surficial soils appear to be of marine origin. Using the data from the boring logs and the survey a series of cross-sections were prepared to illustrate the subsurface conditions, the cross-sections are presented in Figure 3 (attached). 3.3 Regional HydroQeology Regional groundwater flow in the Coastal Plain generally flows in a down dip direction, which generally trends southeast in North Carolina. The rivers generally flow from northwest to southeast in the Coastal Plain, roughly paralleling the dip direction. The southern portion of the Great Dismal Swamp also drains south to southeast into the Perquimans and Pasquotank Rivers, which drain into the Albemarle Sound. Shallow groundwater generally occurs under unconfined (water table ) conditions within five feet of the surface in the region, as evidenced by the large expanses of hydric soils, and the extensive use of drainage systems in agricultural fields. 3.4 Local HydroQeology The extensive ditching of the subject property and surrounding areas has altered the hydrogeology of the site. The primary changes include the lowering of the water table in the cleared portion of the field and the concentration of groundwater flow towards the channelized headwaters of the Perquimans River on the western boundary of the subject property. The results of the slug tests indicate that the soils on the site have a moderately low hydraulic conductivity ranging from a low of 3.41 x1 G' Ft/day (1.04x1 (y2 meters/day (m/d), 4.33x1 G2 cm/hr) to a high of 2.0 Ft/day (6.2x1(?' m/d, 2.58 cm/hr). The water level measurements presented in Table 1 were used to construct a series of water table maps presented as Figures 4 through 11. The maps all indicate that groundwater flow on the site is westward towards the channelized headwaters of the Perquimans River. The maps also show two localized high points in the water table, one is in the southeastern portion of the site in the non-hydric Echaw soils which is represented as a topographic high, the other is in the northern tract in the vicinity of PZ-3, PZ-7, and PZ-1 1 which appears to be less related to topography. Surface drainage at the subject property is controlled by the canals and drainage ditches. The drainage ditches in the northern tract are approximately 335 feet (102 m) apart and drain towards the southern edge of the field into a large canal which drains into the canals running north-south on the eastern and western boundaries of the tract. 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Skaggs of North Carolina State University (NCSU) to simulate the performance of water table management systems. The model was originally developed to simulate the performance of agricultural drainage and water table control systems on sites with shallow water table conditions. DRAINMOD was subsequently modified for application to wetland studies by adding a counter that accumulated the number of times that the water table rose above a specified depth and remained there for a given duration during the growing season. The model results can then be analyzed to determine if wetland criteria are satisfied during the growing season, on average, more than half of the years modeled. Required model inputs include the threshold water table depth, required duration of high water tables, and beginning and ending dates of the growing season. Dr. George (Chip) Chescheir of NCSU also participated in the current study by reviewing the site characterization data and setting up the DRAINMOD model for the study area. Dr. Chescheir provided input parameters required by DRAINMOD and supplied model results for the study area. Output from the DRAINMOD model was then applied to the study area to determine which areas would not achieve wetland hydrology criteria. Wetland hydrology criteria was defined in the model as having groundwater within 12 inches (30 cm) of the surface for both 12 consecutive days (5% of the growing season) and 31 consecutive days (12.5% of the growing season). For the purposes of this study the growing season was defined as the period between 21 March and 19 November( USDA-NRCS, 1986 & 1994). Simulations were also conducted to forecast whether saturation within 30 cm of the surface could be achieved for 49, and 61 consecutive days ( 20%, and 25% respectively) at the study area under conservative, cost-effective site modifications. These additional simulations were conducted to characterize the extent and duration of anaerobic soil environments and forecasts the expected influence of flooding on various plant species populations. 4.2 Model Description DRAINMOD performs water balances in the soil-water regime at the midpoint between two drains of equal elevation. The model is capable of calculating hourly values for water table depth, surface runoff, subsurface drainage, infiltration, and actual evapotranspiration over long period of climatological data. The reliability of DRAINMOD has been tested for a wide range of soil, crop, and climatological conditions. Results of tests in North Carolina (Skaggs, 1982), Ohio (Skaggs et al., 1981), Louisiana (Gayle et a/., 1985; Fouss et aL, 1987), Florida (Rogers, 1985), Michigan (Belcher and Marva, 1987), and Belgium (Susanto et aL, 1987) indicate that the model can be used to reliably predict water table elevations and drain flow rates. DRAINMOD has been used to evaluate wetland hydrology by Skaggs et al (1993). Water Balance The water balance in DRAINMOD involve two basic equations. The first equation is a water balance in the soil profile: OVa=D+ET+DS-F (1) 17 Where: AV. = change in air volume D = drainage from the profile ET = actual evapotranspiration from the profile DS = deep seepage from the profile F = infiltration into the profile The second equation is a water balance at the soil surface: AS = P-F-RO Where: AS = change in volume of water stored at the soil surface P = precipitation F = infiltration volume RO = surface runoff (2) Methods for evaluating equation variables are discussed in detail in Skaggs 0 980). The hydrology of various soil water conditions applicable to the study area was simulated using DRAINMOD. The simulations were conducted for the time periods from 1951 to 1980 using climatological data from Plymouth, North Carolina. Table 2 summarizes the soil parameters used in the DRAINMOD simulations. Appendices B and C contain the results of the slug testing, grain size analyses, and attaberg limit tests conducted on soils at the site. 4.3 Model Results The hydrology of various soil water conditions applicable to the study site was simulated using DRAINMOD. The simulation used the hydric organic-mineral Icaria soil, a fine sandy loam, and the most prevalent soil onsite to conservatively represent the soil conditions for the portion of the site consisting of prior converted wetlands. soil input parameters for DRAINMOD were calculated by the NRCS model, DMSOIL (Baumer and Rice, 1988) using soil texture data from soil samples collected on site. Soil hydraulic conductivity values used in DRAINMOD simulations were determined from the on-site slug test data. Table 2 summarizes the soil parameters used in the DRAINMOD simulations. The simulations were conducted for the time periods from 1951 to 1980 using climatological record from Plymouth, North Carolina. DRAINMOD simulations were conducted for the range of ditch depths and distances of a midpoint to the ditch. Due to the very low relief of the site, of approximately six feetO.8 m) over the approximately 5000 feetO 500 m) length of the tract east to west, it was assumed that after filling and grading the ditches would be at the same grade as the adjacent existing surface. Drain depth was taken as the depth from the ground surface to the surface of the water in the remaining large perimeter canals. Simulations were then run to determine the distance between ditches for the establishment of wetland hydrology at the midpoint for 5%, 12.5%, 20%, and 25% of the growing season for drain depths of one ft.(30 cm), two ft.(60 cm), three ft.(90 cm), four ft.0 20 cm), and five ft.0 50 cm). The simulation also assumed that after 20 + years of forest growth the hydraulic conductivity of the top 60 cm of soil had 18 Table 2 Soil Input Parameters Volume drained, Up flux, Green- mpt Parameters, and Hydraulic Conductivity for Icaria Soil Water Table Depth (cm) Volume Drained (cm) Upflux (cm/hr) 0.0 0.00 0.1000 10.0 0.25 0.0800 20.0 0.40 0.0600 30.0 0.65 0.0500 40.0 0.92 0.0400 50.0 1.35 0.0200 60.0 1.85 0.0063 70.0 2.53 0.0025 80.0 3.40 0.0016 90.0 4.45 0.0014 100.0 5.50 0.0011 120.0 7.50 0.0005 140.0 10.45 0.0003 160.0 13.40 0.0000 200,0 19.30 0.0000 250.0 27.23 0.0000 300.0 35.40 0.0000 Green-Ampt Parameters Water Table Depth (cm) A B 0.0 0.0 0.00 60.0 4.0 0.25 120.0 12.0 1.00 500.0 12.0 1.00 100.0 12.0 1.0 Saturated Hyd raulic Conductivity Depth to Bottom of Layer K (cm/hr) 60.0 25.0 240.0 2.0 19 ft.). The simulation also assumed that after 20 + years of forest growth the hydraulic conductivity of the top 60 cm of soil had been increased to 25 cm/hr by the process of plant growth. An impermeable layer was assumed to be present at a depth of 240 cm, since seven to nine feet was the shallowest depth at which clayey sands were encountered. The depth of depressional storage used in the in the initial DRAINMOD simulations was five cm assuming that surface roughing would be used on the site to increase surface storage. Based upon the input data saturation to within 30 cm of the surface for 25% of the growing season (61 consecutive days) could not be achieved with a surface storage of five cm. The simulations were repeated using a surface storage of 10 cm, and saturation for 25 % of the growing season was achieved. The rooting depth function used in the simulation was a constant depth of 45 cm, which is typically used for forested conditions. 4.4 Model Results The DRAINMOD simulations predicted that a very high percentage of the cultivated land would achieve wetland hydrology criteria. The model predicted that at a maximum of 100 meters (330 ft) from the drainage canal, assuming a 150 cm (5 ft). depth to water in the canals, saturation for 12.5 % of the growing season could be achieved by filling lateral ditches and assuming surface storage of 10 cm. Tables 3 and 4 provide the results of the DRAINMOD modeling study presenting different ditch depths and distances from the perimeter canals that saturation would be present in the top 30 cm for*'5%, 12.5%, 20%, and 25% of the growing season. Table 3 summarizes the results for five cm of surface storage, and Table 4 summarizes the results for 10 cm of surface storage. The relative depth of the canals was determined from Figure 12, a conceptualized topography of the site following filling the lateral ditches and central canals. Wetland hydrology was defined as the conditions that resulted in the criteria being met in more than 15 out of 30 years. As was expected, wetland hydrology was more likely to occur in the interior portion of the tract at a distance from the perimeter canals. Based upon the DRAINMOD simulations, between 377 acres and 401 acres of the PC farmlands would meet the criteria of saturation in the top 30 cm (1 ft) for at least 12.5 % of the growing season for surface storages of 5 cm and 10 cm respectively. The wetland hydrology results observed in Tables 3 and 4 were then used to determine which portions of the tract would not meet wetland criteria, on average, more than half the time. The issue of whether or not a specific portion of the site will have wetland hydrology was determined using the ground elevation at the simulated midpoint relative to the elevation of the water in the nearest perimeter canal. Areas that would not achieve the wetland criteria were mapped on the site according to the ground elevation and the values in Tables 3 and 4. Those areas which would not meet wet land criteria are illustrated in Figures 13 and 14. In general the interior portion of the tract would meet wetland hydrology criteria with the exception of the two small Knolls of upland soils, comprising approximately 12 acres, in the southern portion of the site. Based upon the DRAINMOD simulations another 83 acres would meet the criteria 5 % of the time or less and 24 acres would meet the criteria for between 5 to 12.5 % of the time for surface storage of 5 cm. For surface storage of 10 cm the acreage for 5 % or less of the growing season is 56 acres, while 28 acres would be saturated between 5 to 12.5 % of the growing season. The distances from the ditches given in Tables 3 and 4 represent the minimum distance from a ditch of the given depth that saturation for the various durations could be achieved. 20 been increased to 25 cm/hr by the process of plant growth. An impermeable layer was assumed to be present at a depth of 240 cm, since seven to nine feet was the shallowest depth at which clayey sands were encountered. The depth of depressional storage used in the in the initial DRAINMOD simulations was five cm assuming that surface roughing would be used on the site to increase surface storage. Based upon the input data saturation to within 30 cm of the surface for 25% of the growing season (61 consecutive days) could not be achieved with a surface storage of five cm. The simulations were repeated using a surface storage of 10 cm, and saturation for 25 % of the growing season was achieved. The rooting depth function used in the simulation was a constant depth of 45 cm, which is typically used for forested conditions. 4.4 Model Results The DRAINMOD simulations predicted that a very high percentage of the cultivated land would achieve wetland hydrology criteria. The model predicted that at a maximum of 330 feet (100 meters) from the drainage canal, assuming a five ft.0 50 cm) depth to water in the canals, saturation for 12.5% of the growing season could be achieved by filling lateral ditches and assuming surface storage of four inches 0 0 cm). Tables 3 and 4 provide the results of the DRAINMOD modeling study presenting different ditch depths and distances from the perimeter canals that saturation would be present in the top 12 inches (30 cm) for 5%, 12.5%, 20%, and 25% of the growing season. Table 3 summarizes the results for two inches (five cm) of surface storage, and Table 4 summarizes the results for four inches (10 cm) of surface storage. The relative depth of the canals was determined from Figure 12, a conceptualized topography of the site following filling the lateral ditches and central canals. Wetland hydrology was defined as the conditions that resulted in the criteria being met in more than 15 out of 30 years. As was expected, wetland hydrology was more likely to occur in the interior portion of the tract at a distance from the perimeter canals. Based upon the DRAINMOD simulations, between 377 acres and 401 acres of the PC farmlands would meet the criteria of saturation in the top 12 inches (30 cm) for at least 12.5 % of the growing season for surface storages of two and four inches (5 cm and 10 cm) respectively. The wetland hydrology results forecast in Tables 3 and 4 were then used to determine which portions of the tract would not meet wetland criteria, on average, more than half the time. The issue of whether or not a specific portion of the site will have wetland hydrology was determined using the ground elevation at the simulated midpoint relative to the elevation of the water in the nearest perimeter canal. Areas that would not achieve the wetland criteria were mapped on the site according to the ground elevation and the values in Tables 3 and 4. Those areas which would not meet wet land criteria are illustrated in Figures 13 and 14. In general the interior portion of the tract would meet wetland hydrology criteria with the exception of the two small knolls of upland soils, comprising approximately 12 acres, in the southern portion of the site. Based upon the DRAINMOD simulations another 83 acres would meet the criteria 5 % of the time or less and 24 acres would meet the criteria for between 5 to 12.5 % of the time for surface storage of two inches (5 cm). For surface storage of four inches 00 cm) the acreage for 5 % or less of the growing season is 56 acres, while 28 acres would be saturated between 5 to 12.5 % of the growing season. The distances from the ditches given in Tables 3 and 4 represent the minimum distance from a ditch of the given depth that saturation for the various durations could be achieved. 21 TABLE 3 Results of DRAINMOD Simulations for Saturation within 30 cm of surface for Selected Percentages of the Growing Season (Surface Storage = 5 cm) Ditch Dept Percentage of Growing Season Number of Days 30 cm (1 ft) 60 cm (2 f) 90 cm (3 ft) 120 cm (4 ft) 150 cm (5 f) Ditch Spacing (meters) 5 12 25 37.5 50 75 75 12.5 31 50 75 75 100 100 20 49 150 200 300 300 300 25 61 Criteria could not be met with surface storage = 5 cm TABLE 4 Results of DRAINMOD Simulations for Saturation within 30 cm of surface for Selected Percentages of the Growing Season (Surface Storage = 10 cm) Ditch Depth Percentage of Growing Season Number of Days 30 cm (1 ft) 60 cm (2 ft) 90 cm (3 ft) 120 cm 1 (4 ft) 150 cm (5 ft) Ditch Spacing (meters) 5 12 25 37.5 50 50 50 12.5 31 37.5 50 75 75 75 20 49 50 75 75 75 100 25 61 75 75 100 100 150 22 5.0 RECOMMENDED SITE ALTERATIONS TO PROMOTE WETLAND HYDROLOGY The results of the DRAINMOD modeling study indicate that wetland hydrology can be achieved for an area between 377 acres and 401 acres at the study site, if the drainage ditches are effectively removed and the surface depressional storage is made uniformly high across the site. Removal of the drainage ditches can effectively be achieved by filling the lateral feeder ditches and the two drainage canals between the northern and southern tracts of the site. Increasing the depressional storage can be achieved by using both standard forestry practices of rowing and bedding when planting specimens in the formerly cultivated fields and surface roughing. Rows should be established roughly parallel to existing topographic contours with one ft (30 cm) high beds spaced at intervals to allow access by a tractor to periodically mow the area to control the growth of unwanted plant species and scarify the soils between the beds during the first two years of restoration. 5.1 Recommendations For Filling Drainage Ditches Restoring wetland hydrology on the site requires the effective filling the lateral feeder ditches and the canals between the northern and southern portions of the site. The canals should be backfilled in a manner to minimize the former canals serving as pathways of preferential migration for ground water. An example of one means is to backfill in lifts of 30 cm (1 ft) with each lift compacted to at least 90% of the maximum dry density determined by the standard proctor test (ASTM D-698). Failure to minimize preferential migration will allow the former canals to function as french drains and short circuit the groundwater flow at the site and jeopardize the restoration efforts. The feeder ditches may be backfilled in one lift, but a series of one or more clay dikes should be installed across each ditch to minimize preferential migration and excess drainage to the former ditches. The clay dikes should be constructed to extend to 30 cm (1 ft) below the existing bottom of the ditch and upon completion have a hydraulic conductivity of 1 x10'' cm/s (3.6x104 cm/h), or less. Fill material is available on- site from the spoils pile along the western boundary of the site , which currently functions as a berm or dike to prevent overbank flooding. Fill material is also available by removing the road between the two tracts and grading a smooth transition from the north to the south across the former canals and road. Fill material for the ditches and canal should consist of low permeability clays or silty clays, but due to the relative scarcity of clays in the near surface soils, bentonite or montmorillonite clay should be mixed with fill material on site prior to placement and compaction. 5.2 Recommendations for Site Grading Along with backfilling the existing drainage system, portions of the site should be graded to enhance the hydrologic function of the site. The spoils from dredging the canal on the western boundary of the site were piled along the bank running the length of the property, and has acted as a dike to prevent or minimize overbank flooding of the fields by the canal. The spoils should be removed along the entire length of the boundary and used for fill material. The western edge of the northern tract should then be graded down to an elevation of eight feet at the bank of the canal. Following removal of the spoils pile and grading the field down to the bank a berm approximately 1 foot tall should be constructed along the canal bank to reproduce the functions of a natural levee by delaying the recession of flood waters during flooding and extending the period when the western portion of the field is either inundated or saturated. An opening in the levee should be constructed near the north end to facilitate the 23 diversion of flood waters onto the field. Based upon field observations elevations of flood waters in the field are expected to range between 10 and 11 feet above msl. This grading and berm construction would facilitate the restoration of riverine flood plain conditions adjacent to the canal. Estimated acreage of flood plain achieved using 11 feet msl as the maximum elevation is 57, actual acreage of flood plain resulting from grading could be determined in the field during the next growing season. The estimated flood plain area is presented in Figure 15. 24 6.0 REFERENCES CITED Baumer, 0. and J. Rice. 1988. Methods to predict soil input data for DRAINMOD ASAE Paper No. 88-2564. ASAE, St. Joseph, MI 49085. Belcher, H. W. and G. E. Merva, 1987, Results of DRAINMOD verification study for Zeigenfuss, soil and Michigan climate. ASAE Paper No. 87-2554. ASAE, St. Joseph, MI 49085. Brown, Philip M., et al, 1985, Geologic Map of North Carolina, North Carolina Department of Natural Resources and Community Development, 1-.500,000 scale. Cooper, H. H., Jr., J. D. Bredehoft, and I. S. Papadopoulos. 1967. Response of a finite- diameter well to an instantaneous charge of water. Water Resources Research, 3, pp 263-269. Fouss, J. L., R. L. Bengtson and C. E. Carter, 1987, Simulating subsurface drainage in the lower Mississippi Valley with DRAINMOD. Transactions of the ASAE 30 (6)-. 1679 - 1688. Gayle, G., R. W. Skaggs and C. E. Carter, 1985, Evaluation of a water management model for a Louisiana sugar cane field. J. of Am. Soc. of Sugar Cane Technologists, 4: 18 - 28. Hvorslev, M. J. 1951. Time lag and soil permeability in groundwater observations. U.S. Army Corps of Engineers Waterways Experimental Station Bulletin 36, Vicksburg, MS. Rogers, J. S., 1985, Water management model evaluation for shallow sandy soils. Transactions of the ASAE 28 (3): 785-790. Skaggs, R. W., 1980, A water management model for artificially drained soils. Tech. Bull. No. 267, North Carolina Agricultural Research Service, N.C. State University, Raleigh. 54 pp- Skaggs, R. W., 1982, Field evaluation of a water management simulation model. Transactions of the ASAE 25 (3): 666 - 674. Skaggs, R. W., N. R. Fausey and B. H. Nolte, 1981, Water management evaluation for North Central Ohio. Transactions of the ASAE 24 (4): 922 - 928. Skaggs, R. W., J. W. Gilliam and R. 0. Evans, 1991, A computer simulation study of pocosin hydrology. Wetlands (1 1): 399 - 416. Skaggs, R.W., et a[, 1993, Methods for Evaluating Wetland Hydrology. ASAE meeting presentation Paper No. 921590. 21 p. 25 Susanto, R. H., J. Feyen, W. Dierickx and G. Wyseure, 1987, The use of simulation models to evaluate the performance of subsurface drainage systems. Proc. of Third International Drainage Workshop, Ohio State Univ., pp. A67 - A76. USDA-NRCS. 1986. Soil Survey of Chowan and Perquimans Counties, North Carolina. Publication of the National Cooperative Soil Survey. USDA-NRCS. 1994. Soil Survey of Gates Counties, North Carolina. Publication of the National Cooperative Soil Survey. Ward, L. W., Bailey, R. H., Carter, J. G., 1991, "Pliocene and Early Pleistocene Stratigraphy, Depositional History, and Molluscan Paleobiology of the Coastal Plain." in The Geology of the Carolinas, J. Wright Horton, Jr., and Victor A. Zullo, eds. The University of Tennessee Press, Knoxville TN. 26 COORDINATES: LOGGED BY: JLH TOC ELEVATION: DRILLED BY- Geo-Environmental G.S. ELEVATION: DRILL RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-21-94 2" Stickup SAMPLE C. SOIL DESCRIPTION PID WELL DESCRIPTION TYPE REC RESIST U.S. (PPM) Bentonite Seal P 8/24 2: V Sch 40 PVC Riser P 4/24 4 1" Sch 40 ' PVC Screen J . 6 I. . L ... is P 2/241 20-40 Sand Filter Pack • I• P 1 8/24 I -a P 8/24 10 I i Black, organic soil (MUCK) Tan, very fine SAND; trace clay Wet, tan, very fine SAND; trace clay Very wet, tan, very fine SAND; trace As above medium-clayey Very wet, dark gray, medium-clayey SAND Boring terminated at 9 feet 12 I , i I 14 I ! j 16 I 1 18 20- 22- 24- 25-- FILE NAME: ER94018.2-25PZ01 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-1 CHECKED BY. BH COORDINATES: LOGGED BY: JLH TOC ELEVATION: DRILLED BY: Geo-Environmental G.S. ELEVATION: DRILL RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-22-94 2.5" Stickup 10 PID SAMPLE U.S.C. SOIL DESCRIPTION TYPE ! REC RESISTI (PPM) WELL DESCRIPTION Bentonite Seal Black or anic 'I k) P 18/24 " 1 Sch 40 PVC Riser 2 : .. F...... `. P 12/24:i 4 •'rr i 1" Sch 40 I .. PVC Screen P 24/24 20-40 Sand . Filter Pack ... U-- - P 24/24 8- i I g soI (muc 1%0 Fine, brown SAND As above Brown, wet, very fine to fine SAND As above i Wet, brown, very fine, sandy CLAY Wet, blue/green, glauconitic, very fine, sandy i CLAY to clayey, very fine SAND P 9/24 10 As above Boring terminated at 10 feet 12 I 14 16 18- 20- 22- 24- F i 25 FILE NAME: ER94018.2-25PZ02 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-2 CHECKED BY: BH COORDINATES: - TOC ELEVATION: - G.S. ELEVATION: - ELEVATION DATUM: 4.31 " Stickup Bentonite Seal 1 " Sch 40 - PVC Riser 1" Sch 40 - PVC Screen 20-40 Sand Filter Pack 2?. .. . 4.:•:: i. 6 8-1 i i 10 i 12- 14- 16- 18 20 22 24-- 4 - 25 25- LOGGED BY. LOGGED JLH DRILLED BY: Geo-Environmental DRILL RIG: Scorpion Geoprobe DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-22-94 TYPESA EC RESIST! U.S.C. SOIL DESCRIPTION (P? Black, organic (MUCK) and very fine, SAND P 15/24 Rust, very fine SAND As above, becoming moist P 14/24 Moist, brown, very fine SAND :. Rust, then tan, vety fine SAND 4 P 24 /2 Wet, light gray, very fine to fine SAND I P 6/24 Wet, dark gray, very fine to fine SAND P 24/24 I , Wet, dark gray, sandy CLAY to clayey SAND Borina terminated at 10 feet FILE NAME: ER94018.2-25PZ03 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-3 CHECKED BY: BH COORDINATES: TOC ELEVATION: G.S. ELEVATION: ELEVATION DATUM:- 4.20' Stickup Bentonlte Seal 1 " Sch 40 - PVC Riser V soh 40 - PVC Screen 20-40 sand Filter Pack LOGGED BY: Jeri DRILLED BY* Geo-Environmental DRILL RIG: Scorpion Geoprobe DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-23-94 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC 'RESISTi (PPM) ?I 14 Black MUCK) and o i fi , rgan very ne, c d k b SAM 24/24. ar rown Brown, organic MUCK and very fine, dark brown SAND As above P 24/24 Brown, very fine to fine SAND Mottled rust-brown, fine SAND ..:. .. P 24/24 6 'Saturated, flight gray, fine SAND P 13/24 ' Saturated, dark gray, very fine to fine SAND g with clay lens P 0/24 .:.: i Saturated' dark gray, very fine to fine SAND 10 Boring terminated at 10 feet 12 I j I FILE NAME: ER94018.2-25PZ04 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-4 CHECKED BY. BH COORDINATES: LOGGED BY. JLH TOC ELEVATION: DRILLED BY- Geo-Environmental G.S. ELEVATION: DRILL RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-21-94 2.5' Stickup SAMPLE U.S.C. SOIL DESCRIPTION PID WELL DESCRIPTION TYPE ' REC RESISTi (PPM) Bentonite Moist, black, organic soil (MUCK); trace clay " P 18/24 Sch 40 1 PVC Riser 2 h. .. .V l? As above i Wet, dark gray, sandy CLAY P 20/24 " Sch 40 1 PVC Screen 4 :: : ..: . i Wet, dark gray, fine SAND; trace clay . . P 18/24 1 20-40 Sand Filter Pack 6 : l ..... Wet, dark gray, fine SAND : p 1 i 4 6/2 8 Very wet, black, fine SAND I: : 1 l P 22/24 01 ? Moist, light gray, fine SAND Boring terminated at 10 feet 12- 14- j 16 18- 20- 22- ? 24 ' I 25 FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ05 ENVIRONMENTAL Gates and Peiquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-5 CHECKED BY: BH COORDINATES: LOGGED BY: Urn TOC ELEVATION: DRILLED BY- Geo-Environmental G.S. ELEVATION: DRILL, RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-22-94 4.2" Stickup -- TELL DESCRIPTION Bentonlte Seal - 1" Sch 40 PVC Riser 1 " Sch 40 PVC Screen 20-40 Sand Filter Pack SAMPLE TYPE I REC : V P 14/24 . P .21/24; 4 :. .. P 24/241 .. P 1 24/241 8 ? :..:.: P 24/241 10 12 14? RERE T U.S.C. SOIL DESCRIPTION Black, organic soil (MUCK) Becoming moist, brown, very fine SAND Becoming. dark i Wet, light gray, very fine SAND Saturated, light gray, very fine SAND Wet, slightly mottled, dark to light gray, very fine SAND PID (PPM) Saturated, light gray, very fine to fine SAND Boring terminated at 10 feet I 16 1 I 18 1 i 1 1 i 20 22 I 24 25 FILE NAME: ER94018.2-25PZ06 SOUTHEASTERN Dismal Swamp Mitigation Site -.---- ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-6 CHECKED BY: BFi COORDINATES: LOGGED BY: JLH and BLH TOC ELEVATION: DRILLED BY Geo-Environmental G.S. ELEVATION: DRILL RIG:- Scorpion Geoprobe ELEVATION DATUM: DRILLING mETNOD: Hydraulic Hammer DATE DRILLED: 11-23-94 3.09" Stickup SAMPLE SOIL DESCRIPTION PID U S C JELL DESCRIPTION . . . TYPE REC RESISTI (PPM) BentonRe Seal :•. ' Black, organic soil (MUCK) " lh P 24/24 j I S se R Becoming brown fine SAND w i r PVC 2 , ? - Moist, brown, fine SAND; some cla y P j 22/24! V sci, 40 As above PVC Screen 4 20-40 Sand Filter Pack 6 P 8/24 ! I Moist, dark gray, fine SAND; trace clay P ? 8/24 8 j Wet, dark gray, clayey, SAND to sandy CLAY 10 p 12/24Wet, blue-gray, very fine to fine SAND with clay seam Boring terminated at 10 feet 12 14 16 18 20 22 24 25 SOUTHEASTERN ENVIRONMENTAL AUDITS, INC. Dismal Swamp Mitigation Site Gates and Perquimans Counties, NC North Carolina Department of Transportation PZ-7 FILE NAME: ER94018.2-25PZ07 MADE BY: PS CHECKED BY. BH COORDINATES: LOGGED BY: J%Xi TOC ELEVATION: DRILLED BY- Ge0-Environmental O.S. ELEVATION: DRILLRKi: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11"23"94 3.3T Stickup SAMPLE U.S.C. SOIL DESCRIPTION PID WELL DESCRIPTION TYPE REC RESIST', (PPM) Bentonite Seal Dark brown, to black, fine, sandy, organic soil 4/24 t° Sch 40 PVC Riser 2 :. •::? 2 (MUCK) - ; As above 1" Sch 40 4 PVC S ! : : : .: p 18124;. Dark brown, fine, organic, rich SAND creen : : . .. . . • . •?....... Wet, dark brown, fine, organic, rich SAND 20-40 Sand Filter Pack g : P i 12/24 Becoming gray at 5.5 feet 8 i..:...: P 3/24 Saturated, blue-gray, clayey to slightly clayey, fine SAND 10 P 1 I 24/24 Saturated, gray-green, very fine, sandy CLAY Boring terminated at 10 feet 12 - 14 - 161 18 i i 20- 22- 24 25 FILE NAME: ER94018.2-25PZ08 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-8 CHECKED BY: BFi COORDINATES: LOGGED BY: Jun TOC ELEVATION: DRILLED BY• Geo-Environmental G.S. ELEVATION: DRILL RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-22-94 4.25" Stickup SAMPLE WELL DESCRIPTION TYPE REC R Bentonite Seal ti p 18/24 1" Soh 40 PVC Riser 2 P 22/24 I" Sch r een PVC Sc .:::. 24/24 20-40 Sand Filter Pack 6 P 24/24 8 P 6/24 10 - P 12/24 I 12 i P 24/24 I 14 - p j 16/24 1 16 ::.. i p 16/24 18 - P 120/24 20 - 22 I 24 25 U.S.C. SOIL DESCRIPTION IPPIID11 Black, organic, soil (MUCK) Moist, very brown, fine SAND Moist, very brown, fine SAND As above, wet j As above i Wet, very fine to fine SAND As above Wet, light gray, fine SAND As above Light gray, saturated, very fine to fine SAND As above As above, clay seam at 19 feet Boring terminated at 20 feet ! r FILE NAME: ER94018.2-25PZ09 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-9 CHECKED BY. BH COORDINATES: LOGGED BY. JI-H TOC ELEVATION: DRILLED BY Geo-Environmental G.S. ELEVATION: DRILL RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-22-94 2.5' Stickup WELL DESCRIPTION Bentonlte Seal 1" Sch 40 PVC Riser 1 " Sch 40 PVC Screen 20-40 Sand Filter Pack SAMPLE TYPE REC ?. 2 :r.. i P 22/24 ?:...:. , . P 15/24! 1 6 ' : 24/24 - P 124/24 8 P 24/24 10 12- 14 i 16 1 18 j 20 22 24 25 U.S.C. SOIL DESCRIPTION (PPM) RESISTI M M) Black, organic, soil (MUCK) Orange CLAY seam at 1 foot, brown i ve fine SAND i Brown, slightly mottled dark, fine j clayey SAND to sandy CLAY As above ! Becoming wet, blue-green, glauconitic, fine san CLAY Becoming sandier Saturated blue-green, clayey, fine SAND Becoming more clayey Saturated blue-green, fine, sandy CLAY Boring terminated at 10 feet FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ10 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-10 CHECKED BY: BH COORDINATES: LOGGED BY: JLH TOC ELEVATION: DRILLED BY- Goo-Environmental G.S. ELEVATION: DRILL RIG: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-23-94 2.95' Stickup REC RESIST U.S.C. SOIL DESCRIPTION IPA WELL DESCRIPTION SAMPLE Bentonite Seal ? .. • : • a,, P :19/24 W 1 " Sch 40 PVC Riser P 18/24 • 4 . i 11" Sch 40 : .::... PVC Screen :.: {. `. P 24/24 11 20-40 Sand ! Filter Pack 6 .... i , I : I . P 24/24 8 Black, organic MUCK; some clay Wet, dark brown MUCK and fine SAND Wet, brown, fine SAND As above Wet, dark gray, fine SAND Wet, dark gray, very fine SAND with clay Gray-green, fine to very fine SAND with clay Boring terminated at 10 feet P i 24/24 Saturated 10- i 12- it 14- i r 16- L 18 I i 20 22 l 24 25 FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ11 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-11 CHECKED BY: BH COORDINATES: LOGGED BY: JLH TOC ELEVATION: DRILLED BY- Geo-Environmental G.S. ELEVATION: DRILL RIO: Scorpion Geoprobe ELEVATION DATUM: DRILLING METHOD: Hydraulic Hammer DATE DRILLED: 11-23-94 4.18' Stickup SAMPLE SOIL DESCRIPTION PID U S C WELL DESCRIPTION TYPE RFC 'RESIST . . . (PM Bentonite Seal ' Dark brown organic SAND j : 'j ' 24/24 , , . . . p Brown very fine to fine SAND 2 , 1 " Sch 40 PVC Riser P 4/24 1" Sch 40 PVC Screen 4 : j Wet, brown, fine SAND .. a :: I light brown Saturated fine SAND ... p 24/24 j , , 20-40 Sand Filter Pack g : :.. . r .. Becoming gray at 5.5 feet P 24/24 8 r Saturated, gray-green, sandy CLAY to clayey SA - i 1 10 p 4/24 Saturated blue-gray, slightly clayey, fossiliferous fine SAND P 24/24 As above 12 Becoming more clayey i 12/24' 14 P i Becoming less fossiliferous and less clayey 24/24 16 Saturated gray-green, slightly clayey, fine SAND i 22/24 18 p As above , 6/24 i 20 P Saturated, gray, very fine SAND Borina terminated at 20 feet 22- 24- 25- FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ12 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. PZ-12 CHECKED BY: BH COORDINATES: TOC ELEVATION: G.S. ELEVATION: ELEVATION DATUM:- 2.6' Stickup Bentonite Seal j .vans 2 V Sch 40 PVC Riser V Sch 40 PVC Screen 4 20-40 Sand Filter Pack 6 8- 10- 12- 141 16 18 20 22 4 24- 25 25- LOGGED BY: LOGGED JLH DRILLED BY- TJK DRILLRG: TJK DRILLING METHOD: Hand Auger DATE DRILLED: 11-30-94 SAMPLE U.S.C. SOIL DESCRIPTION I PID TYPE REC RESIST! IPPMI i Black, organic, slightly sandy LOAM Becoming brown, organic, slightly clayey SAND, wet at 1.5 feet; As above, saturated Gray-brown, sandy CLAY, saturated Blue-green, clayey SAND, saturated Brown-green, very fine to fine SAND Becoming bluer Boring terminated at 5.5 feet i i i FILE NAME: ER94018.2-25PZ13 ?- SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-13 CHECKED BY: BH COORDINATES: LOGGED BY: TJK TOC ELEVATION: DRILLED BY: JLH G.S. ELEVATION: DRILL RIG: JLH ELEVATION DATUM: DRILLING METHOD: Hand Auger DATE DRILLED: 11-30-94 2.7" Stickup ---?? Bentonite Seal 1 " Sch 40 - PVC Riser 1" Sch 40 - PVC Screen 20.40 Sand Filter Pack SAMPLE ' TYPE REC RESIST U.S.C. SOIL DESCRIPTION ' Black, organic, slightly sandy LOAM 2 ; Black, organic loam to very fine SAND Dark brown, very fine SAND; some clay 4 As above, saturated Brown, very fine SAND, saturated Becoming blue-green, very fine SAND 6 ..:.I very fine SAND; trace clay Blue-gray, 8 As above Boring terminated at 7 feet 10-12 14 16 18 20 22 24 25 I F PID (PPM) FILE NAME: ER94018.2-25PZ14 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-14 CHECKED BY: BH COORDINATES: LOGGED BY- TJK TOC ELEVATION: DRILLED BY- JLH G.S. ELEVATION: DRILL RIG: JLH ELEVATION DATUM: DRILLING METHOD: Hand Aucer DATE DRILLED: 11-29-94 2.48" Stickup TYPE SAMPLE ECRESIST! U.S.C. SOIL DESCRIPTION IPID PPM) WELL DESCRIPTION Bentonite Seal Slightly sandy, black, organic LOAM " ' ' ' ' Sch40 1 PVC Riser 2 ? i • • • • = s Becoming black, organic CLAY " Black, organic, sandy CLAY, wet at 1.5 feet Sch 40 1 PVC Screen 4 .. ,., I Brown, very fine to fine SAND, some clay 20-40 sans Finer Pack 6 Saturated at 3.5 feet, slightly clayey Becoming more sandy j Brown, fine SAND, saturated at 4.5 feet g Blue-gray, sandy CLAY, clayey SAND, saturated at 5.5 feet i Boring terminated at 8.5 feet, no recovery 10 i 12- 14- ? i i 16- I 18 I 20- 22- i 24 25 FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ15 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-15 CHECKED BY: BH COORDINATES: LOGGED BY- JLH TOC ELEVATION: DRILLED BY- TJK G.S. ELEVATION: DRILL RIG: TJK ELEVATION DATUM: DRILLING METHOD: Hand Auger DATE DRILLED: 11-30-94 2.48' Stickup SAMPLE U.S.C. SOIL DESCRIPTION PID wF? rscRlaTleN TYPE •. REC iRESIST (PPM) Bentonite Sea[ ?j\ M " Sch 40 1 ? PVC Riser 2 ; • ., " Sch 40 I 4 PVC Screen 20.40 Sand :.: Filter Pack 6 ; •'.1...... . 8 10 12 Black, organic, slightly sandy loam, becoming clayey Dark brown, o manic, very fine SAND, very moist at 2)I feet Mottled rust, organic, brown, sandy CLAY, wet at 3 feet Becoming sandier, brown, sandy CLAY to gyey SAND, saturated at 3 feet i Becoming blue-gray, sandier Blue-gray, very fine to fine SAND, saturated at 5.5 feet i As above j Boring terminated at 7 feet 14 i 16- 18 j 20- 22- 24- 25- FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ16 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-16 CHECKED BY: BH COORDINATES: LOGGED BY. JLH TOC ELEVATION: DRILLED BY. TJK G.S. ELEVATION: DRILLNG: TJK ELEVATION DATUM: DRILLING METHOD: Hand Auger DATE DRILLED: 11-29-94 2.5' Stickup SAMPLE U.S.C. SOIL DESCRIPTION PID WELL DESCRIPTION TYPE REC RESIST! (PPM) Bentonite Seal Black organic, very fine, sandy LOAM t ° Sch 40 PVC Riser 2 ! Becoming brown very fine SAND at 1.5 feet Very moist tan fine SAND at 2.0 feet Becoming more clayey Becomin less cla a wet at 3.5 feet I„ sch 40 en 4 PVC scre Brown, very fine to fine SAND, saturated at 4 feet As above 20-40 Sand Fitter Pack 6 : . Becoming blue--ggra very fine to fine, slightly ciga a SAN 8 As above 10 I Boring terminated at 9 feet 12 I I 14 I 16 I i 18 20 i - 22 - 24 - 25 ation Site Miti l S i FILE NAME: ER94018.2-25PZ17 SOUTHEASTERN ENVIRONMENTAL wamp sma D g Gates and Perquimans Counties, NC North Carolina Department of Transportation MADE BY: PS AUDITS, INC. PZ-17 CHECKED BY., BH COORDINATES: TOC ELEVATION: G.S. ELEVATION: ELEVATION DATUM:- 3.8' Stickup VELL DESCRIPTION Bentonite Seal 33-8'? 1" Sch 40 PVC Rlser 2 1 " Sch 40 4 PVC Screen 20-40 Sand Filter Pack 6 8- 10 12- 14- 16 18 20 22 24 25 FILE NAME: ER94018.2-25PZ18 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-18 CHECKED BY: BH LOGGED BY: 4Lr1 DRILLED BY• TJK DRILL RIG: TJK DRILLING METHOD: Hand Auger DATE DRILLED: 11-30-94 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC RESISTI. (PPM) Black, organic, slightly sandy LOAM Black, organic, clayey SAND, moist at 1 foot Brown, very fine to fine SAND, wet at 3 feet Tan, very fine SAND, saturated at 4 feet Becoming blue-brown, very sandy CLAY to clayey SAND Tan, very fine to fine SAND, saturated at 5 feet Blue-green, slightly sandy CLAY Becoming blue-green, clayey SAND i Boring terminated at 7 feet r I I? ?I 'r COORDINATES: TOC ELEVATION: G.S. ELEVATION: ELEVATION DATUM:- 2.4' Stickup /ELL DESCRIPTION Bentonite Seal V Sch 40 PVC Riser 1" Sch 40 - PVC Screen 20-40 Sand Filter Pack 4 /. 8 10 12 14 16 18 20 22 24 25 LOGGED BY: omen DRILLED BY- JLH DRILL RIG: JLH DRILLING METHOD: Hand Auger DATE DRILLED: 11-29-94 SAMPLE U.S.C. SOIL DESCRIPTION P1D TYPE . REC RESIST (PPM) Black, fine, sandy LOAM Becoming brown and sandy, fine sand at 2 feet Becoming wet, brown, clayey SAND, saturated at 3.8 feet 11 Blue rayy,, clayey, fine SAND to sandy, fine CLA Y, saturated at 6 feet Loose blue-gray, slightly clayey, fine SAND Boring terminated at 6.5 feet FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ19 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. PZ-19 CHECKED BY. BH COORDINATES: LOGGED BY- JLn TOC ELEVATION: DRILLED BY BLH G.S. ELEVATION: DRILL RIG: BLH ELEVATION DATUM: DRILLING METHOD: Hand Auaer n DATE DRILLED: 11-29-94 1.96 Bentonite Seal UJOi 1" Sch 40 W U PVC Riser 2 ^ ..7,77 1 Sch 40 4 PVC Screen ... . 20-40 Sand - -::: Fliter Pack 6 i. 12-1 14 16? 18 20 i 22 24 25 SAMPLE TYPE ; REC RESIST; i U.S.C. SOIL DESCRIPTION Black, organic, sandy LOAM Becoming brown, less organic, very fine SAND Becoming tan Becoming moist, wet at 3.5 feet Dark gray, sandy CLAY to clayey SAND PID (PPM) Blue-gray clay seam at 4.25 feet, j saturated at 5 feet Sand, clay mixture becoming more sandy, blue ra at 5.5 feet i More sandy, blue-gray at 5.5 feet Saturated blue-gray, slightly clayey SAND Boring terminated at 8.5 feet FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-25PZ20 ---- ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS . North Carolina Department of Transportation AUDITS, INC. PZ-20 CHECKED BY: BH 10-? I i COORDINATES: LOGGED BY: BLH TOC ELEVATION: DRILLED BY- BLH G.S. ELEVATION: DRILL RIG: BLH ELEVATION DATUM: DRILLING METHOD: Hand Auger DATE DRILLED: 12-8-94 2.4' Stickup SAMPLE U.S.C. SOIL DESCRIPTION PID WELL DESCRIPTION TYPE REC (RESIST; (PPM) Bentonite Seal Orange, slightly silty, fine to very fine SAND " Sch 40 1 PVC Riser 2 I" Sch 40 PVC Screen 20-40 Sand Filter Pack 4 Boring terminated at 4.62 feet ; 6 i - 8 - 10 - i 12 - i 14 ? I 16 I - 18 i I 20 i - 22 - 24 - 25 - ation Site Miti m l S Di FILE NAME: ER94018.2-25PZ21 SOUTHEASTERN ENVIRONMENTAL g p wa sma Gates and Perquimans Counties, NC North Carolina Department of Transportation MADE BY. PS AUDITS, INC. PZ-21 CHECKED BY. BH COORDINATES: _ TOC ELEVATION:. G.S. ELEVATION:. ELEVATION DATU 1.96 Bentonlte Seal " Sch 40 1 PVC Riser 2 " 1 Sch 40 PVC Screen 20-40 Sand : Fitter Pack 6 ::: •i 8 10 i 12 14 16 18 20 22 24 25 LOGGED BY. JLH DRILLED BY: TJK DRILL RIG: TJK DRILLING METHOD: Hand AWr _ DATE DRILLED: 12-1-94 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC 'RESIST! (PPM) i Black, organic, rich, fine, sandy LOAM Tan, very fine to fine SAND White, well-sorted, very fine SAND Becoming moist and mottled Wet at 4 feet j Becoming slightly clayey to clayey j Slightly mottled orange, dark-gray clayey SAND j to sanCLAY Blue-gray, very fine to fine SAND; trace clay, saturated at 5.5 feet Blue-gray, marine CLAY with sand lenses i Blue-gray, very fine to fine SAND, saturated j Boring terminated at 8 feet FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-WPPZ01 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. WP-1 CHECKED BY: BH COORDINATES:. TOC ELEVATION: G.S. ELEVATION: ELEVATION DATUM:- 2.1' Stickup Bentonite Seal 1 ° Sch 40 - SAMPLE TYPE I REC F LOGGED BY: BLH DRILLED BY BLH DRILL RIG: BLH DRILLING METHOD: Hand AuOer DATE DRILLED: 12-5-94 U.S.C. SOIL DESCRIPTION APP Black, fine, sandy, loamy, organics Dark brown, organic, rich, fine SAND Becoming light brown i Dark brown, fine, sandy, high plastic CLAY Becoming mottled, orange-gray and wet Blue-gray, medium to fine SAND, saturated I' i i i As above terminated at 8 feet I FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-EPPZ03 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. EP-3 CHECKED BY: BH COORDINATES: LOGGED BY: ULM TOC ELEVATION: DRILLED BY. BLH G.S. ELEVATION: DRILL RIG: BLH ELEVATION DATUM: DRILLING METHOD: Hand Auger I-l DATE DRILLED: 12-8-94 2.1 " Stickup SAMPLE U.S.C. SOIL DESCRIPTION PID WELL DESCRIPTION TYPE REC RESISTI (PPM) Bentonite Seal Dark-brown, slightly fine sandy, organics 1 " Sch 40 Ri ser 2 PVC i, Becoming dark-brown, loamy fine SAND 1" Sch 40 Becoming light brown at 3 feet PVC Screen 4 - interbedded, fine SAND and i Clay 20-40 sand -?:::: Filter Pack :.:: j , brown ray, high mastic, CLAY lenses Blue-gray, slightly to clayey, fine SAND, wet Blue-gray, high plastic CLAY Blue-gray. sli htl to cla a fine SAND Saturated ! I Boring terminated at 8 feet 10 ', i I I ? 12 14; 16? 18 j I I 20 i I i 22 I 24- i 25 FILE NAME: ER94018.2-EPPZ02 Site ti Miti SOUTHEASTERN on ga Dismal Swamp Gates and Perquimans Counties, NC MADE BY: PS ENVIRONMENTAL North Carolina Department of Transportation AUDITS, INC. EP-2 CHECKED BY, BH COORDINATES: LOGGED BY: T,1K TOC ELEVATION: DRILLED BY: BLH G.S. ELEVATION: DRILL RIG: BLH ELEVATION DATUM: DRILLING METHOD: Hand AUDer DATE DRILLED: 12-8-84 4.51' Stlcku SAMPLE U SOIL DESCRIPTION PID S C WELL DESCRIPTION . . . TYPE REC RESIST: (PPM) Bentonite Seal .....k Black, fine, sandy LOAM 1° sch 40 PVC Riser 2 Organic Soil Brown, fine, organic, rich SAND V Sch 40 4 Wet at 3.5 feet PVC Screen 20-40 Sand Filter Pack - Boring terminated at 5.5 feet 6 8 10 12 14 16 18 20 22 24 25 FILE NAME: ER94018.2-HPPZ01 SOUTHEASTERN Dismal Swamp Mitigation Site ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY. PS North Carolina Department of Transportation AUDITS, INC. HP-1 CHECKED BY' BH COORDINATES: LOGGED BY: BLH TOC ELEVATION: DRILLED BY: BLH G.S. ELEVATION: DRILL RIG: BLH ELEVATION DATIAI: DRILLING mmoD: Hand Auger DATE DRILLED: 12-8-94 2.1" Stickup PID SAMPLE U.S.C. SOIL DESCRIPTION WELL DESCRIPTION TYPE REC 'RESIST. i (PPAA) Bentonlte Seal Dark-brown, fine sandy, organic LOAM (topsoil) 1 " Sch 40 l? l l PVC Riser 2 White seam at 2 feet lM Becoming light-brown, fine SAND ! I" h PVC screen 4 1 Becoming very light buff at 2.5 feet 20-40 Sand Finer Pack 6 j Becoming light-gray and wet at 5.5 feet I Becoming clayey at 7.5 feet ! Boring terminated at 8 feet 10 12 14 16 18 20 22 24 25 FILE NAME: SOUTHEASTERN Dismal Swamp Mitigation Site ER94018.2-EPPZ01 ENVIRONMENTAL Gates and Perquimans Counties, NC MADE BY: PS North Carolina Department of Transportation AUDITS, INC. EP-1 CHECKED BY: BH 7*S&ME January 31, 1995 Environmental Services, Inc. 1318 Dale Street Suite 220 Raleigh, North Carolina 27605 Attention: Mr. Brian Hayes Reference: Laboratory Test Results of Soil Samples Job Reference ER94-018.2 S&ME Job No. 1053-95-120 Dear Mr. Hayes: At your request, S&ME, Inc. has performed laboratory Grain Size Analysis with Hydrometer on nine (9) soil samples delivered to our office. Plasticity index was determined on three (3) samples as requested. Testing was performed in general accordance with ASTM D-422, "Particle Size Analysis of Soil", and ASTM D-4318, "Standard Test Method for Liquid Limit, Plastic Limit, and Plasticity Index of Soils". Plasticity Index was determined for samples P2-2 (6'-8'), P2-2 (8'-10'), and P2-16. Plasticity Indices are 14, 3, and 19 respectively, as shown in Table I. Attached are Grain Size Distribution Sheets for each sample. S&ME, Inc. appreciates the opportunity to perform laboratory testing for Environmental Services, Inc. If you have any questions or comments concerning these results, please do not hesitate to contact our office. Sincerely, S&ME, Inc. ,?gL C ,k? Brian C. Glidewell, E.I.T. Staff Professional Wes Lowder, P.E. U Construction Services Manager S&ME, Inc. 3100 Spring Forest Rood, Raleigh, North Carolina 27604, (919) 872-2660, Fox (919) 790-9827 Mailing address: P.O. Box 58069, Raleigh, North Carolino 27658-8069 TABLE I ATTERBURG LIMITS 8 S 8° 8 8 g R R°° _ O o ? m 1- S W ?Z y N z N1 U. Z o ? W J O N O W W ? 1Z ? y 3 ca "' 0 8 g 0 0? ? o 0 a s ? W ""O W = W ~ o 4- -1 A 0 S bi 8 8 8 g $ R o o C4 if It 8 $ CO g c4i N O Z r O 1 "' 8 w M W O • Q l z s N W W z ? r ? o w c J N N Z N ? ^ O Z O ? ? N cc UJI LA U v W _ H 3 U u o H c ac c? r = W ? O co ? O ?I p W O H U A W O Z W CIO w a •' Q .- U N N ZZZ N _ _ ., 00 8 I ` C O oa W J Wy? O p Z O 8 8 8 S 8 g 8 R ° ° N z N O N y ? a ?n J W N N W> W M c cr 0 z rA Z O F- m N M& W N Z Z , Q ti m O < U W od W 00 -H v O ? U _ O 3 z tn. a W ? O V4 tn .W u co r4 CQ a J a 0 N ? O W 2 co a N1 O N ..r 1 tP1 e%1 O z N W N N W H O f? D N N g 8 S S S g S $° 8 0 0 0 0 CY N N r. O TTI- -1 11,00 H W 3 2 0 0 . H r Z t0 t O r 0 N r 8 $ S S S S S R o z O P m m U) z c EZ N N z Q cc 0 z' O 1= U LL. U O m vrl v C cc 1) >a U a J a 3 O N N d .? _ co W 0 1 1 ? O 1 ? W .? W 2 Z a Is 0 a ' , ?a 8 8 8 0 8 8 4 8 R 0 0 8 0 0 0 N ok, N r' O N Q ?Z o n 0 0 r r N r N W N H W N c cc O 2 N N m O u= m y W Z 70 2 W &Z N ?zz to W W Z Q Z O U LL U V4 Q O O z a 6 W 0 O f4 W 14 O a J CL J H < 2 S O N H Q I W O ? N Z ? SE I W h w kn O 8$ 2 8 8 g 8 R Z O all S N C113 H g LU i U 0 W W Z W N ?z z V1 U. o ? o R i? W N N J O N N r Z C O y W F ,ui W 00 "4 -0000 z C: LL W v ? O 001- H U ,G - - - - - - - - - - - - - 0 3 F H o b ac cn co WC 0 O ? N r ? t u O ca PO a W O Z ti J w a c7 ? ? O U N eo - - - - - - - - - - - - - - N -4 4- 8 N N 00 a u o O w s w a ?y W N W O O 1 ?O FR 8 $ 8 ° 8 9 S 9 R ° ° Z ay p Z O 1= m N Uzi N W W k Q 11 V H W N co W U! O O 9 N N U a00 U Q t/1 N pZ ?' F ? a ? U U C O ti+ A 1+ A ? rr J ? CL -+ J ? 3 0 N yJ 1 O O1 ? W ..r 0 8 8 8° S 8 S 8 R° Z O M? 8 W W_ S ~ U z V! " Z o o J N y C W W V1 0 8 g ? o v . o O H s m ?a c+. W O LL O r X H` : Z O .r 8 8$° S 8 s 8 R°° 'N N Aw y It It 8 ° g R ° Z O O m N • ? g N Z U ? Q l ? W W ? z Z ?' o o W c N N J _ N O N N y 00 OOF C z O - 000 H W Z U W u W df Z -C -rf i CA v !Ft - - - - - - - - - - - - ? - O O C3 z z p W = C O W r-4 U O a W O *? LL. W CL U N F- 8 u , U O ? C1 W ~ O p O p l oo e0 pp tp o p + p <+! p R O O N Q% z N co C a Q ?s ?M APPENDIX C HYDRAULIC CONDUCTIVITY TEST RESULTS Slug Test PZ -1 1.00 9 8 7 6 5 4 O 0.10 0.00 200.00 400.00 600.00 800.00 1000.00 1200.00 1400.00 1600.00 Time Well Number: PZ' Date: Q2,' j 4 Computed By: Casing diameter d = " 5' -r (cm) Borehole diameter D = S, OR (em) Length of screen L = 2, /, j (cm) Time lag at 0.37 H-/Ho T = 1333- (seconds) k = d2 in r 2mL 1 m= 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. 7 z,?. (z?vl ?? jJ S, v (2z1. 3)?/33S) Note: m = khorizontal Assume kh = kv = 1 /kvertical . /, L Z X/d cam, sP? kh=- DRAWDOWN TEST 'ELL NO. f"- -/ _40P OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER I BOREHOLE DIAMETER .Z SCREEN DEPTH-(,, 0 - ?. L9 c REFERENCE POINT 761 AMOUNT OF WATER REMOVED LOCATION (rY rPf ?o?h T DATE TIME COMPUTED BY ASSISTED BY PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL ?r 4 7 RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho 0 2,yq 2,aj /.C) s 2,55? /, 7 0,77o 1147 Z; dl z. K3 L. 77 3?3r? .2, -70 1,74 K 7 . ° Z, 73 1,72 c?.,Y 47 s. 2.1 5? , Sy 0, 778 l(S° 0,7.E / 7:10 : d? / ?o c1 6°1 ?? 130 0 2- ?v6 (d 3, f ° /f ?S 4 0, ?? s 11 0 , 71, 0, 3 6,5 --?- I 0,?,, D• OS NOTES ! -, -4.,,i I, Ll 4 Slug Test PZ - 2 1.00 -,- 9 - 8 - 7 6 5 4 3 2 O = 0.10 = 8 7 6 5 4 Time Well Number: PZ - a Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: 1a' - ?4 - 9 y Computed By: S" d = z- S 4 (cm) I ., D = S .eR (c m) -Z L = 153. oo (cm) to T (seconds) kh = d2 In -in L 1 8 LT m=1 Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Z (z-) (IX-1 5' 1) ?- K ? CZ.S? ( y -1) ZS.lI - 5 , 0 8 a. O4 d( 9cl - _ a5-40 4U ZS?°`IO C$1? ?s3? C Z wl . Note: m = khorizontal ?kvertical Assume kh = kv =1 kh = 9.9'4- x 1 b _T C?M I Sew DRAWDOWN TEST SELL NO. TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER t , BOREHOLE DIAMETER 2 SCREEN DEPTH 2, 3 S - 'S REFERENCE POINT 7.r/ C AMOUNT OF WATER REMOVED LOCATION -G r 7?,f ('e DATE 30 '41" 94 TIME COMPUTED BY Fj . ?G> ASSISTED BY PERSONS OBSERVING is . /fir o EVACUATION METHOD STATIC WATER LEVEL ?f • q,? SQL - T wL = /4 RECOVERY DATA Sk L lJ vL,T = l 'a ELAPSED TIME GROUNDWATER DEPTH (pw? ) H H/Ho d o 4,?8 7d0 jo 450 0.6 Z,7Y 1. r? z. 7 z, 1 2-y 2" a C , 2, Z, Z q ©. 6"0 2, Z.?d zoo 3.?? 3 7J 0'0 ZS ?, 3, d 3 S v 1, `(? , Z9 7 4 ? f.?6 ?zZ ?,Zys 7 ?.?4 ?,?? o,2v9 g 4,o? 9 / `f. Or? l o-16-3 Id 4?L? U 7 d 4, /5Z r r yr 3d v, < d O, 11 0 ' L 14. ; MOTES sue; c G, < S Slug Test PZ -4 O 1.00 9 8 7 6 5 4 3 2 0.10 0.00 50.00 100.00 150.00 Time I 250.00 200.00 300.00 Well Number: />Z- .?f Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Computed By: Date: 2c57-1--l- 74 d = Z, S? (cm) D = S a'? (c m) L (cm) T = ?y (seconds) k = d2 in r 2mL m = 1 h L D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal /kvertical Assume kh = kv =1 kh = z.29Xlo_y ?I sic DRAWDOWN TEST ? ELL NO. Do:? - ?I OP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER BOREHOLE DIAMETER a', SCREEN DEPTH . (? S - -, . ?, REFERENCE POINT i y C AMOUNT OF WATER REMOVED LOCATION G,-?es C,,. DATE It 30-2-+ TIME 13 4 =rl COMPUTED BY ASSISTED BY -%7 PERSONS OBSERVING_ EVACUATION METHOD STATIC WATER LEVEL q 3 RECOVERY DATA iS 30 bo '? S qo IGS IZ? 14b z Z4 0 ;? 40 ELAPSED TIME GROUNDWATER DEPTH H H/Ho 0 .? I S!, go -- k a,13=1! •?0 ?? 9'. r 1 L1 5 4 i I a a 3 L - 33 v 0 -NOTES Se ?k SecS e to psed Ln,,<2 Slug Test PZ - 5 1.00 - 9 8 7 6 5 4 0 2 2 TIME Well Number: F2 -S Date: Computed By: --SA Casing diameter d = (cm) 1 ` Borehole diameter D = S.oq (cm) Length of screen L = (cm) +o' - 3.Cn = (".09 Time lag at 0.37 H-/Ho T = (seconds) k = d2 In r 2ml, m = 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. --' • \ p ? ??56896 b• 0 000 \1 -• S (o (e Cad C?b?•?1 C(?avl Note: m = khorizontal/kvertical Assume kh =k v =1 kh = 1, x (?"s c,?, l? DRAWDOWN TEST 'ELL NO. 1"22 - 5 TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER BOREHOLE DIAMETER SCREEN DEPTH REFERENCE POINT AMOUNT OF WATER REMOVED +?, LOCATION GG s Co DATE ?l/?/tea v TIME COMPUTED BY ASSISTED BY PERSONS OBSERVING __d /ice, p EVACUATION METHOD STATIC WATER LEVEL 3 RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho a 3. 9J /, o S 3 3 0 1 oc,52-- 3 3<4 0413 2,76 0, 6 / Z/ z,` ? o. 6bS 5: /? i 4 Z z? ?, 6 3 7 5-6 2, 4-f d j. 7d z/ 2-, ?? r?6 L,o D5' 4 21 1,71 0.4 7 ?= 2, i, o, 391 NOTES ??. a - Z - ty Slug Test PZ - 6 1.00 9 8 -- 7 6 5 4 0 3 2 0.10 200.00 0.00 : 0 600.00 1000.00 1400.00 400.00 800.00 1200.00 1600.00 TIME Well Number: RZ- 6 Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: Z.0-12- Computed By: /f 4 f' I d = Z• `< (cm) D = Sad (cm) L = /!1 Z (cm) T = y i (seconds) k = d2 In [ 2mL 1 m = 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. Note: m = khorizontal/kvertical Assume kh = kv =1 k = Z?' S k/? fsP? h DRAWDOWN TEST .YELL NO. / Z- TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER P ' BOREHOLE DIAMETER SCREEN DEPTH 0, 71 - S. T 9 REFERENCE POINT To(' AMOUNT OF WATER REMOVED LOCATION G1 7,,-; re&* r" DATE 3 0 /4-y'/ 9 y TIME COMPUTED BYE,. o ASSISTED BY PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho 0 6"6 e, c l 0 G 3 0.7 7 ,z7 3.y1 0,727 3, 4 o, Z;atl 1,-73 2,7S p.G D z? ; ° /. `%v z 7 585 3 . / s 5-2 7 ?-3j ?. z 3 Z?S S 4.00 Z,37 g p 2 2, OP ?, yv9 8(e Gy0 2- 7 z 9s 73 70 3. `+ 2 7 ©, 27/ o, 2 3J5' / q p 7,P J II 0, 6 3 o, ij5 'OTES i 7 , 4 - 4 zr Slug Test PZ - 8 1.00 -?- 9 8 7 6 5 4 3 2 O = 0.10 = s 7 6 5 4 3 2 0.01 0.00 Well Number: Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: la- ?v - 9 y Computed By: ?3Z K d = a.yi (cm) D = S.oB (c m) ?. L = II h _ t^ (cm) ?o' - h• 3? = 3.?3 T = 3? , S (seconds) k = d2 In r 2mL1 m=1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. ---- ------ - -- - 3'S N 8 O 3 B O K> Note: m = khorizontal Assume kh = kv =1 ?kvertical . kh = 10 ?Te? DRAWDOWN TEST 4 'ELL NO.- OP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER 10 BOREHOLE DIAMETER a" SCREEN DEPTH 1. o -- L. C a REFERENCE POINT AMOUNT OF WATER REMOVED LOCATION C? ?lP S C1 ?, . DATE 11- 3 0 - 9 a TIME COMPUTED BY ASSISTED BY -r r S-tA PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL RECOVERY DATA 1S 3,1 4S 6o 31? 40 I OS 12J I? I? Ibt 16o ;)\o Zoo 300 ELAPSED TIME GROUNDWATER DEPTH H H/Ho U.8S = .30 S °l u S.(,-+ .8 335 .I ? I r ?' 't? eV ci 0,1 5.3o a ?. ?3 1 0. 0 Z 0.1? 0. b-49 57 ?e 1 NOTES ?? ?k ?? Sccs e la psec\ i , e Slug Test PZ - 9 1.00 9 8 7 6 5 4 0 2 3 2 0.10 0.00 20.00 40.00 60.00 80.00 100.00 120.00 140.00 160.00 TIME Well Number: 14?12 -J Computed By: Date: zd' -12 Casing diameter d = (c m) Borehole diameter D = Sa.? (cm) Length of screen L = 135, 4 (cm) Time lag at 0.37 H/Ho T = 32 (seconds) kh = d2 1n ( 2mL 1 m = 1 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. Note: m = khorizontal ?kvertical Assume kh = kv =1 DRAWDOWN TEST /-ELL NO. "Z - D- TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER A BOREHOLE DIAMETER Z " SCREEN DEPTH o 79 - S, 7y REFERENCE POINT 7o r AMOUNT OF WATER REMOVED LOCATION (2 r? DATE 30' .4'a ? `? TIME COMPUTED BY If ASSISTED BY PERSONS OBSERVING fl o EVACUATION METHOD STATIC WATER LEVEL S- 41 - 2-RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho D o S, ?f z (?-3 Zi 9 d Z /. d /- 7 -7 a. z8S ?•3? 2- l%Z z S, 37 d z o al 2., 6,o7 o,l3S NOTES Slug Test of PZ -10 0 1.00 9 8 7 6 5 4 I 0.10 50.00 150.00 250.00 350.00 0.00 100.00 200.00 300.00 TIME 400.00 Well Number: PZyd Casing diameter Borehole diameter Length of screen Time lag at 0.37 Hi/Ho Date: - 12 -4? Computed By: d = 2. S4 (cm) D = 5" 6)21' (cm) L (cm) T = ?S (seconds) k = d2 in r 2mL 1 m= 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal /kvertical Assume kh = kv =1 kh DRAWDOWN TEST /ELL NO.? z - l ?40P OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER /11 BOREHOLE DIAMETER 2- SCREEN DEPTH 2, 4-7 - -7 7 REFERENCE POINT TO " AMOUNT OF WATER REMOVED LOCATION 6-?w >is Cal?g y DATE 3 TIME COMPUTED BY ? /?a ?.r ASSISTED BY PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL s 4 , RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho O?s? 3.jt ?,a6 0, ? (.s 3.S5 6 o,z f? Or 76 . 4 0 2?° ?r.?PZ 0 d,/D 6, 0 S. i? S,d? 0 7 v.o6? 0,057 /, v J (< NOTES S;,T ,,- - 2 Slug Test of PZ -11 O 2 1.00 9 8 7 6 5 4 3 2 0.10 F E L b 0.01 25.00 0.00 50.00 75.00 100.00 12500 150.00 17500 200.00 22500 250.00 Time Well Number: Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: -94 Computed By: SLA d = a.Sy (cm) D = S.u? (cm) z L = ?90.C) (cm) IC - 3.?? = ?.a3 T = 13 -4 - ICT (seconds) k = d21n r 2mL? m=1 h L D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. _ .?- , 33 oao Note: m = khorizontal?kvertical Assume kh =k v =1 kh = `;?. 0 x \ 0-1-i cm1 S,- C, ? DRAWDOWN TEST YELL NO. -rOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER BOREHOLE DIAMETER Z SCREEN DEPTH Z o P 7 c j REFERENCE POINT ! ?- c AMOUNT OF WATER REMOVED LOCATION ?a s Ca DATE 1 ?? - 94 TIME COMPUTED BY ASSISTED BY PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL 3. 7 RECOVERY DATA 30 (?o GU ,7o b? b ?C 3ok 3bt `q osk ELAPSED TIME GROUNDWATER DEPTH H H/Ho c) l Z j v a. S ? .a3 O 9 ?Ss 3 51 ?- ?- - 3 of oa. NOTES Slug Test PZ -13 1.00 9 8 7 6 5 4 3 2 O = 0.10 7 6 4 n a i 0.01 - 50.00 0.00 100.00 i I li j 150.00 200.00 25000 300.00 Time Well Number: P-2 - ?3 Date: Computed By: Casing diameter d = :;k.(cm) Borehole diameter D = io. (cm) Length of screen L = S , (cm) a, - ? C'o _ 4 Time lag at 0.37 H/Ho T = ? y (seconds) k = d21n r 2mL? m=1 h L D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. K" ? C L Io.a - ??- = o.oao4??( - -- - - S 30 . Z S 30(0 4 . Z = 1 Note: m = khorizontal?kvertical Assume kh =k v kh= H,,a xlh?Li cm.i??c DRAWDOWN TEST J 'ELL NO. 'P:?- - 13 OP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER BOREHOLE DIAMETER " SCREEN DEPTH Q. 5-1- 4. S , REFERENCE POINT To C AMOUNT OF WATER REMOVED LOCATION C--,,-? PS C~? . DATE 11- 3a -7y TIME i y?, b COMPUTED BY ASSISTED BY , K PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL 3. - 3? RECOVERY DATA . IS 30 yG (oJ qo 1ef; ?zo ?eS 1R0 Zoo 2H sac 5w ELAPSED TIME GROUNDWATER DEPTH H H/Ho g9 0. o 3 .? 10, 3\FS 3 O . ?l 3 Z .30 .? a 1 t 2. 3. 3 3 t 2.30 I t ?- 0 1 3 3,,44 n. 0190 3 4 3. /A 0, 4,3o - t 56 6-, 5 3 S-? O? 04S NOTES_ Slug Test PZ -14 O 2 5 4 3 2 Time Well Number: Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: Z.P -/z - y "r, Computed By: /jz N d = ?. s4 (cm) D z (cm) L = /6? 6 (cm) T (seconds) k = d21n r 2mL? m=1 h L D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn cat Fang, pp. 29-35. Note: m = khorizontal/kvertical Assume kh =k v =1 k h = //X/a-v ?f . ?.? DRAWDOWN TEST 'ELL NO. TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER 1" BOREHOLE DIAMETER 3 SCREEN DEPTH 2.45 REFERENCE POINT -c)(_- AMOUNT OF WATER REMOVED LOCATION DATE M - 3,0 - gv TIME COMPUTED BY ASSISTED BY M 4 : -T K PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL q. 3 RECOVERY DATA z 3 a S i 4 10 MOTES 0 z? ELAPSED TIME GROUNDWATER DEPTH H H/Ho Q, 6 3c? u 4- 1 I 3.? . I? 3 Q i Q, 45?;L l , 3? 1 & ,4 3, 8 0.8 0 a 3.9 s o z is- y. 30 b a 20 3 ?? t s.h 0.53 .a ? y? as set- ct? IS S,•c. Q?ar b- HE o .:j Slug Test PZ -15 1.00 9 8 7 6 5 4 O 2 Z ` Time Well Number: 'Pa -0S Date: !a - I'S _ q(4 Computed By: a? ?A Casing diameter d (cm) Borehole diameter D (cm) Length of screen L = , q (cm) gyp' - 3. i8 = (". 'S -I Time lag at 0.37 H-/Ho T = q L( O (seconds) k = d2 in r 2mL1 m=1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. (a.5 z Ir Cad<.?? (do?.? >? 1 ?B???O?.y )? q,v01 IS?o3VOa Note: m = khorizontal?k Assume kh = kv = 1 vertical kh = 1.S x 1o-s CO) j?,C-c DRAWDOWN TEST ELL NO. I?z - IS TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER 0 BOREHOLE DIAMETER 3" SCREEN DEPTH 7 . L? 1 REFERENCE POINT ;-p AMOUNT OF WATER REMOVED LOCATION DATE _ 3 0 - 9 y _ TIME 14'Tb COMPUTED BY ASSISTED BY 5H T t?C PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL ? . i R RECOVERY DATA I?, 3o 4rj ba 90 zr 301 4 2.c 45? ?c 900 12« ELAPSED TIME GROUNDWATER DEPTH H H/Ho eel 30 ?- 8 t, L4 Y 9 a 4 -- 3 -t .-4 w 17 D Root "? • S 3 D ? :x . 1519 r) D,?1 to 2. 6-A .S 4? 1S ?, B3 3' o. LI Ib Q- a NOTES ?? S a ?Ci Q?nnS 2A 4',n,,z - O 2 1.00 9 8 7 6 5 4 3 2 0.10 8 7 6 5 4 2 0.01 Slug Test PZ -16 s, 0.00 200.00 400.00 600.00 Time 800.00 1000.00 1200.00 Well Number: PZ- /6 Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Computed By: Date: d =•S? (cm) D = /c.1 (cm) L = /67, (cm) T = 7 4- S (seconds) k = d2 In l L- 1 m= 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal/kvertical Assume kh =k v =1 DRAWDOWN TEST 'ELL NO. P ? - Ih ?OP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER 1 BOREHOLE DIAMETER SCREEN DEPTH X0% a. s a- . 5 3 REFERENCE POINT TO AMOUNT OF WATER REMOVED LOCATION f-z.1 p (? o , DATE ?I - ?n - 9 y TIME COMPUTED BY ASSISTED BY 1-4A t Z PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL y NA RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H I/Ho P' Z ?? o . ?S ?. Ll 14 a off 'A li 1 ?0 9b : O ? ? r)- 49N 2 '' S 0. ?t4 0, Lk 3,T 'F i 73, (o ;L n ?>9 ?.. -5 9 LA ?u 3 b. a a. 314 31 o . ?S NOTES o ' ?t, 48 6 gI o0 c n, 0. ZILZ?x y 0% c). 4o e7 1KS 1 ?nc) 4 IS O 33 n ISa Slug Test PZ -17 O -17 1.00 9 8 7 6 0.10 0.00 20.00 40.00 60.00 i I 100.00 140.00 180.00 80.00 120.00 160.00 200.00 Time Well Number: Date: Computed By: SAN Casing diameter d = a_Sy (cm) Borehole diameter D = (c m) LO Length of screen L = C) (cm) Time lag at 0.37 H-/Ho T = (seconds) --a? k = d2 in r 2mL1 m=1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. ;L99a 13;2990 o, o00?-4q Kr- (z.5?,? CaIC?? Cao?.s? (`.x>(3.8> Z" p, 000 <51 (zo?.S`? (iaa.? Note: m = khorizontal?kvertical Assume kh = kV =1 ?--- -- ki ??+?.= S. a -A ?b 4 m Se,- 6.000 1\ } DRAWDOWN TEST 'ELL NO. f - I-4- "TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER I" BOREHOLE DIAMETER 3!t SCREEN DEPTH Z- S I- 5 1 REFERENCE POINT AMOUNT OF WATER REMOVED LOCATION lTa? es c en . DATE -1 I- 3p-q TIME r5- ; 2, o COMPUTED BY ASSISTED BY 74j PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL 3. -3 RECOVERY DATA 0. 30 4S 7V lob 120 kv ISO ELAPSED TIME GROUNDWATER DEPTH H H/Ho D O 4? a __ -+ IS Y ?/ of O , 9S 0. H (4 'Zlxq ?- 3 as 0. 1 3.1 Z NOTES Se ` ?k i? SPC s e i 4 ' Slug Test PZ -18 1.00 - 9 8 7 6 5 4 0 3 2 0.10 50.00 150.00 250.00 0.00 100.00 200.00 300.00 TIME Well Number: P-a - k$ Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: ta-- is -94 Computed By: SLEA d = a.sti (Cm) I'' D = io, a (cm) 4 L = L4 Q, y (cm) 44 .'7o T = 9 a. (seconds) k = d21n r 2mL1 m=1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. N1 14) Note: m = khorizontal?kvertical Assume kh =k v =1 DRAWDOWN TEST /ELL NO. 1':?z - 1$ ?fOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER BOREHOLE DIAMETER SCREEN DEPTH REFERENCE POINT AMOUNT OF WATER REMOVED RECOVERY DATA LOCATION '.3 DATE t Z - ? q %f TIME III%: COMPUTED BY ASSISTED BY -\ PERSONS OBSERVING_ EVACUATION METHOD STATIC WATER LEVEL. ELAPSED TIME GROUNDWATER DEPTH H H/Ho 1 0 0 34 0 3 3 n. 'a tcl r{ j .Z3 1• 'z'Z n.49 f)- 44 % o, 3 b kx Ilk n. IL. kk 0 •? ?+ 114 NOTES Slug Test PZ -19 O -17 ?- 1. 00 9 8 - 7 6 5 4 3 2 0.10 0.00 0 100.00 200.00 300.00 400.00 500.00 600.00 700.00 800.00 Time Well Number: Date: z,P-1 z -2y Computed By: /f Gib Casing diameter d = Z, S`' (cm) Borehole diameter D = /V. -2 (cm) Length of screen L = / S7, (cm) Time lag at 0.37 H/H0 T = Zoo (seconds) k = d2 in r 2mL 1 m= 1 h D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal/kvertical Assume kh = kv =1 -s kh = P. 7q x"la ,? ?S DRAWDOWN TEST 'ELL NO. ^ t TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER BOREHOLE DIAMETER SCREEN DEPTH t , REFERENCE POINT AMOUNT OF WATER REMOVED LOCATION DATE TIME r 2 COMPUTED BY ASSISTED BY t ti _. T PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL 8 RECOVERY DATA - - n IS 3G ?C? IZO l? ($O ZIU 2140 2-:W 2)G- v ELAPSED TIME GROUNDWATER DEPTH H H/Ho µ 00 1. 3 x ? s 11 '? 0. q '?- S . o -?g o a s 0. o a 37D ro Nr p , 42d t.! 4d° ? ?I.II 3 3 Su u 9 ?f .! 9 D6 ,.? 0 t ?. :-sue COG ?° `I • a1 O, 8fo NOTES J,64a 7 ?? I 44. 3 q 6. ISO X -' !J 4' U - 1 '49 -- 3. 0" = Z, - 1.00 9 8 7 6 5 4 O r Slug Test PZ - 20 Time Well Number: P? - in Date: ?a IiS 1 ev Computed By: :,y Casing diameter d = a.54 (cm) Borehole diameter D = is (cm) 14 Length of screen L = i S y , Z (c m) 11 3'- 4 . CN = 5, a b Time lag at 0.37 H/H0 T = «3. S (seconds) k = d2 In [ 2mL 1 m = 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. IS? x? = L io.D. 60 > 6 - o,6b0139 _S) ISa 3y9, Note: m = khorizontal? Assume kh = kv =1 kvertical kh = I. y x 10-y Can I Se C- DRAWDOWN TEST /ELL NO. 'fq - zib TOP OF CASING ELEVATION' GROUND SURFACE ELEVATION CASING DIAMETER Yl BOREHOLE DIAMETER 3 " SCREEN DEPTH ta- REFERENCE POINT AMOUNT OF WATER REMOVED LOCATION ?SU?Ps ?`o DATE TIME COMPUTED BY ASSISTED BY -Z-?A a, rt - PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL L4, 14 RECOVERY DATA 4S 6c? 90 lob 1Zc, I roy t? 22? ELAPSED TIME GROUNDWATER DEPTH H H/Ho O .30 1 ncn .v5 .? 19 ISLA ?. 1 3 3 a 4 ? . 01 3 11 1 z u G: 3 k a.t z T;)- Z .30 3,q4 2.4 . 8 S 3 q Zti 3. t 5- y e5 _;;toli . 3. 1! y! s3 1 4 U, u ? o . 14S 'MOTES ? - S ? ? ? 7,0 5? ? ?\? n5 e ? ?; Me Community Restoration Types Nonriverine Swamp Forest - Organic Soil Subtype Nonriverine Swamp Forest - Mineral Soil Subtype Mesk: Lonnleaf Pine-Oak Forest ?: 7z y -?Forns ed red&-- -w 7 Avail- ??- • ylr- %I- A ?- _.,n.?• = ....,,,,.. ter, ?. Also- DRAFT i U .i ;t ;? 11 ? %t I -?? -?- - --°- Ili` 000- r.r.{ +r- .. ter.- .,''1 i From USGS 7.5' Quadrangles: Hobbaville (19M. Sunbury (1881), Chapanoke (109?), LYn(:f9 Canter OW) 1\ Community Piantlrtg Plan Map 7-16": E1194018.2 Ftgu-No.. 3 gym ?%Inr- Proposed Clsmaf Swamp 1318 044 Sant Mitigation Tract Drawn Hr: PS Scale-. 10 = 1000' Suits 220 Gates and Perquimans Counties ---- RnWgk. NC 21605 North Carolina c?pckrd By; JWp 18 Jan 95 _ t-nd 1nt-u 12 011 -131 :QI 1t-:TT NOW Ste.-?T-s3??? d \?+ tir = w• ._ .? - _ .A i » .?. _.? _- .:I-'?.w fir- a •? ? l'w, r' •" t7 - ?, ? _`?, .,?,? •?` r./'!' .._? ICI .t. .?• w• '? - ?'- f -'+ ^i...? •r. f rtr _ -W - i -o. 17 _ •_ !i -?+ rte?' I .?__-.1} _r?s ? ?-? _ -_ - ?-?•?! _ _ -?_-- ^? .,. . A. M Y .J 71 ------------ ? •w ?.t Grave f w :r r? \ 1T 77, ?J Y \ i • I J v \ ?I c nd ?nrrt It+ I YO fw 4 H 74 k ?rp M ' CU f . Y f ?r CAT )R 1 L 11 s w}+ Aft :n`--I :7i Tr:TT rlrna s6.-2T-.q 31 Soil Typ s &P- Arapahoe Typic H maqquepts) BE Solhaven/ (ferric ©disaprinta) Echaw EntlC aa lohgumod.4) Icarla IC Umbraquuks) ?l Leon ( eric Haplaquode) .. t.?... _ IC 5.04. LE A*. -• .? ~ ICI 5 BE/SG - ' -•? ''? BE/SC LE t IC ,- „?, - -11,27- ? „?. • ?-/.-- BE/SC- Ho EC USC -?.. -- ~\ f .5 ..br- -46 % -?? ?es.-des h From USGS 7.5' Quadrangles: IioCbsviile (19921t. Sunbury Chapanoke (1982). LyncKs Comer 099 NRCS Soil Survey Map P"j"" ER94018.2 Mir-No.. 7 Proposed Dismal Swamp iai` g n stc Mitigation Tract nrnW„ BY: PS s?s?: 1000' I sutce 21_0 Gates and Perquiman ; Counties x.Jafgk 14C 27609 North Carolina Checfmd nr• JWO Dare: 18 Jan 95 4 1 :111 c-r : i i Pinta rcld Env" : nr? ?3 ROADSIDE DITCH IMPACT STUDY US 17 WIDENING HERTFORD TO EDENTON CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA ESI Job No.: ER94-018.2 (R-2208A) Prepared for, N.C. Department of Transportation 1 South Wilmington St. Raleigh, NC 27601 Prepared by: ENVIRONMENTAL SERVICES, INC. 1318 Dale St., Suite 220 Raleigh, NC 27605 TEL (919) 833-0034 FAX (919) 833-0078 • April, 1995 ?° .w-ten M ?o- STATE OF NORTH CAROLINA DEPARTMENT OF TP ANSPORTATION JAMES B. HUNT, JR. DIVISION OF HIGHWAYS GOVERNOR P.O. BOX 25201. RALEIGH. N.C. 27611-5201 May 15, 1995 Dr. G. Wayne Wright Chief, Regulatory Branch Department of the Army Wilmington District, Corps of Engineers Post Office Box 1890 Wilmington, North Carolina 28402-1890 Dear Dr. Wright: R. SAMUEL HUNT III SECRETARY SUBJECT: Roadside Ditch Impact Study, Supplemental Report to Dismal Swamp Mitigation Site Report; TIP No. R-2208A, State Project No. 6.03900T, Widening of US 17 from Hertford to Edenton, Perquimans and Chowan Counties Please find enclosed three copies of the Roadside Ditch Impact Study for TIP Project R-2208A. This study, issued as a supplement to the Dismal Swamp Mitigation Plan, was identified in my letter to you dated April 24, 1995. The study was conducted by our consultant, Environmental Services, Inc. (ESI). It quantifies the additional impacts to wetlands caused by the excavation of ditches parallel to sections of the proposed widening of US 17. We propose that the additional 10. 11 acres of wetland impacts identified in this study be added to those already set forth in the Dismal Swamp Mitigation Plan. We propose that all impacts from TIP Project No. R-2208A be debited from the Dismal Swamp Mitigation Site. Please note that the 10.11 acres of ditch impacts do not affect riverine wetlands (page 10 of ESI's Roadside Ditch Impact Study). If you should need additional information, please feel free to contact me or Dr. David Robinson at (919) 733-3141. Thank you for your cooperation in reviewing this document. HFV/dhs Enclosures (3) cc: (with one copy of enclosure) Mr. Mike Bell, COE Mr. Lee Pelej, USEPA Mr. David Cox, NCWRC Mr. David Dell, USFWS L,-Mr. Ron Ferrell, NCDEHNR Sincere Franklin Vick, P. E., Manager Planning and Environmental Branch Mr. Eric Galamb, NCDEHNR Mr. Ron Sechler, NMFS Mr. N. L. Graf, P.E., FHWA; Attn: Roy Shelton Mr. D. R. Morton., P.E., State Highway Engineer-Design Mr. W. D. Johnson, P.E., State Roadside Environmental Eng. Mr. A. L. Hankins, P.E., State Hydraulics Engineer ROADSIDE DITCH IMPACT STUDY US 17 WIDENING HERTFORD TO EDENTON CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA ESI Job No.: ER94-018.2 (R-2208A) Prepared for: N.C. Department of Transportation 1 South Wilmington St. Raleigh, NC 27601 Prepared by: ENVIRONMENTAL SERVICES, INC. 1318 Dale St., Suite 220 Raleigh, NC 27605 TEL (919) 833-0034 FAX (919) 833-0078 April, 1995 ROADSIDE DITCH IMPACT STUDY US 17 WIDENING HERTFORD TO EDENTON CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA ESI Job No.: ER94-018.2 Prepared for: North Carolina Department of Transportation 1 South Wilmington St. Raleigh, North Carolina 27601 Issue Date: 26 April 1995 Gerald R. McCrain, Ph.D., CEP Vice President Signature Brian L. Hayes, P.G. Senior Hydrogeologist Signature ENVIRONMENTAL SERVICES, INC. 13 18 Dale St., Suite 220 Raleigh, North Carolina 27605 TEL (919) 833-0034 FAX (919) 833-0078 D:\W PTEXT94\ESI\PROJECT\ER94-018.2\DTCHMPT.RPT .r C R, (., ee ? 8 SE At _ 1018 , Seal TABLE OF CONTENTS LIST OF FIGURES ................................................... i LIST OF TABLES ...................................................ii INTRODUCTION ....................................................1 SITE DESCRIPTION .................................................1 SOIL BORINGS AND SITE HYDROLOGY ................................... 1 ASSESSMENT METHODOLOGIES ....................................... 4 GROUNDWATER MODEL .............................................4 MODEL DESCRIPTION ...............................................5 WATER BALANCE ..................................................5 MODEL CALIBRATION ............................................... 6 MODEL RESULTS ...................................................9 ADDITIONAL RESEARCH .............................................9 CONCLUSIONS ...................................................11 REFERENCES CITED ................................................13 APPENDICES Appendix A - Boring Logs Appendix B - Slug Test Data LIST OF FIGURES Figure 1 - Site Location ............................................... 2 Figure 2 - Location Map Showing Sites of Wetlands and/or Surface Waters of the United States .................................... 3 LIST OF TABLES Table 1 - Soil Input Parameters for Roanoke Soil ............................. 7 Table 2 - Soil Input Parameters for Portsmouth Soil ........................... 8 Table 3 - Projected Additional Wetland Impacts from R-2208A .................. 10 ROADSIDE DITCH IMPACT STUDY US 17 WIDENING HERTFORD TO EDENTON CHOWAN AND PERQUIMANS COUNTIES, NORTH CAROLINA INTRODUCTION North Carolina Department of Transportation (NCDOT) retained Environmental Services Inc. (ESI) to prepare a Compensatory Mitigation Plan for the widening of US 17 from Hertford to Edenton, TIP No. R-2208A. ESI was commissioned, as part of this plan, to conduct a study to assess the additional impact of the proposed roadside ditches on adjacent wetlands along the alignment. The scope of the study involved analyzing the effect of excavated ditches along approximately 6000 linear ft 0 829 m) of the proposed alignment. The proposed roadside improvements are expected to directly impact approximately 5.7 acres (2.3 ha) of wetlands as described in NCDOT's permit application dated February 7, 1994. ESI was requested to determine the probable additional acreage affected by the ditches and provide supporting data for this determination. SITE DESCRIPTION The site of interest for this investigation consists of the proposed right of way alignment for widening of US 17 between Edenton and Hertford, North Carolina (Figure 1). The existing highway consists of a two-lane roadway, primarily paved with an asphaltic concrete surface. The proposed widening would convert this section of US 17 to a four-lane divided highway. The proposed widening would include excavation and fill of wetlands along the highway. The wetland boundaries were mapped by NCDOT personnel. The approximate locations of the four sites accounting for the majority of the 6000 linear ft (1829 m) of ditching are shown in Figure 2. The majority of the land along the proposed alignment is forested with some cleared land for agriculture and residential property. All wetland sites impacted by ditching are typed as nonriverine/interstream forest habitats. SOIL BORINGS AND SITE HYDROLOGY ESI personnel visited the site on 5-6 April 1995 to evaluate three proposed wetland crossings for R-2208A for hydrologic characteristics. A review of soil survey maps for the area (NRCS, 1986) indicated the presence of two hydric soils, Portsmouth sandy loam (thermic Typic Umbraquu/ts) and Roanoke clayey loam (thermic Typic Ochraquu/ts). The sites were chosen to provide representative data for each soil type. Nine hand auger borings (three per site) were advanced to determine the current depth to groundwater at various locations. The borings were advanced to a maximum depth of 9 ft (2.7 m) below land surface and logged to record changes with depth. The boring logs are attached as Appendix A to this report. After 1 • ' lave 1 ?• ??-_ ? 4?nr - _r-.-- • I I I ? / ` 4•(_?,, .? raw - ?? -T - ? I I ? I ? R•? r _/' '0?6 -._.Ij I 1 .(i -'OJT ' J111I1 ..\`\ lwojO d7 ara...•. rj • .. f., , r r r - .L ` • i r .. 00 • ? J 11s '?` i, I ?? ?yJ_ 1 war, A % `•?? I 9 ? ?`'?i• ? :.:. US 17 Edenton to Hertford Fr. R-2208A I /4 T ® De(.ortn .i li ?1'i _ -__- °`'?a, ... ?, ..va .a - ' ?• a "w".. _ "?'..° .'I. ?,? ? I I ?• ? O 1 Z J MM1ES 'r ?'-fd •1 e'ase' ' .I•" 1 ""'° w + Source: DeLovne Mapping, 1993 1 rrtav..mna '•. r^ ? i ? ? • ? arr ? ,»+ ?a'...rr k ?i . Figure: 1 ` Environmental Site Location h ` y3( k Services, Inc. US 17 Edenton to Hertford, 1318 Dale Street (R-2208A) Project: ER94018.2 Suite 220 Perquimans, and Raleigh, NC 27605 Chowan Counties, NC Date: 5 April 1995 •'??'? 2 Legend 4 Location of primary wetland crossings NCDOT Project R-2208A Map Source: Project Location Map NCDOT Permit Application, Feb. 7, 1994 Environmental Location Map Showing Services, Inc. Sites of Wetlands 1318 Dale Street US 17 Edenton to Hertford, Suite 220 (R-2208A) Raleigh, NC 27605 Perquimans, and Chowan Counties, NC 3 Project No.: ER94018.2 I Figure: 2 Drawn By: PS Scale: NTS Checked By: BH I Dam: April 1995 a boring was completed, a 5 ft (1.5 m) section of PVC screen and a 5 ft 0.5 m) section of PVC riser was installed in the boring to prevent caving while slug tests were conducted to determine hydraulic conductivity of the soils. The results of the hydraulic conductivity tests are also attached to this report as Appendix B. The depths to groundwater varied from 0.19 ft (5.8 cm) below-land-surface(bis.) to 5.48 ft (167 cm) bls. The measured hydraulic conductivities ranged from 5.3 x 10r3 ft/hr 0.6 x10C3m/hr)to 6.4 x 10-2 ft/hr (2.0 x10"2m/hr) in the Portsmouth soil, and from 2.3 x 10"3 ft/hr (7.0 x 10"4m/hr) to 9.5 x 10"2 ft/hr (2.9 x 10r 2m/hr in the Roanoke soil. The data collected was used to facilitate the assessment of the impact of the proposed ditching on the soils. ASSESSMENT METHODOLOGIES Assessing the probable impacts of the proposed ditches on adjacent wetlands can be conducted by at least three methods: Empirical observation, mathematical calculations, and analytical modeling. The first method (empirical observation) requires identifying one or more sites with analogous conditions to the areas to be impacted and collecting data on the behavior of groundwater at the site over a period of time. The duration of the observation must be sufficiently long to accommodate annual fluctuations in weather (rainfall and temperature). The requirements of this study preclude a long term study of impacts at analogous sites. The second method (mathematical calculations) are based upon the assumption that the water table follows an elliptical curve from the level in the ditch to a point where the influence of the ditch is non-existent, or balanced by another ditch some distance away. Mathematical calculations, such as those outlined in "Agricultural Water Table Management 'A Guide For Eastern North Carolina"' (USDA-NRCS, 1986b) are static representations of a dynamic system, requiring new calculations for each change of conditions. This method is also intensively time consuming if every possible variable is accounted for in the calculations. Repeated iterations of the calculations using all possible variables in essence comprises the beginning of analytical modeling of the site as a dynamic, system. The third method (analytical modeling) allows the evaluation of the system rapidly and with the capability to assess the sensitivity of the system to variability of soil properties used to create the simulation. DRAINMOD is one such model with a history of wide spread application to the effects of drainage structures on soils with a shallow water table. The wide spread use of DRAINMOD and the relative simplicity of the model were factors considered in selecting this model for the study. GROUNDWATER MODEL The groundwater modeling software selected as most appropriate for simulating shallow subsurface conditions and groundwater behavior at the site was DRAINMOD. This model was developed by Dr. R.W. Skaggs of North Carolina State University (NCSU) to simulate the performance of water table management systems. The model was originally developed to simulate the performance of agricultural drainage and water table control systems on sites 4 with shallow water table conditions. DRAINMOD was subsequently modified for application to wetland studies by adding a counter that accumulated the number of times that the water table rose above a specified depth and remained there for a given duration during the growing season. The model results can then be analyzed to determine if wetland criteria are satisfied during the growing season, on average, more than half of the years modeled. Required model inputs include the threshold water table depth, required duration of high water tables, and beginning and ending dates of the growing season. Dr. George Chescheir of NCSU also participated in the current study by reviewing the site characterization data and setting up the DRAINMOD model for the study area. Dr. Chescheir provided input parameters required by DRAINMOD and supplied model results for the study area. Output from the DRAINMOD model was applied to the study area to determine the probable distance from the centerline of the ditch achieving wetland hydrology criteria. Wetland hydrology criteria were defined in the model as having groundwater within 12 in (30 cm) of the surface for 12 consecutive days (5% of the growing season). For the purposes of this study the growing season was defined as the period between 21 March and 19 November( USDA-NRCS, 1986). MODEL DESCRIPTION DRAINMOD performs water balances in the soil-water regime at the midpoint between two drains of equal elevation. The model is capable of calculating hourly values for water table depth, surface runoff, subsurface drainage, infiltration, and actual evapotranspiration over long periods of climatological data. The reliability of DRAINMOD has been tested for a wide range of soil, crop, and climatological conditions. Results of tests in North Carolina (Skaggs, 1982), Ohio (Skaggs et a/., 1981), Louisiana (Gayle et aL, 1985; Fouss eta/., 1987), Florida (Rogers, 1985), Michigan (Belcher and Merva, 1987), and Belgium (Susanto et aL, 1987) indicate that the model can be used to reliably predict water table elevations and drain flow rates. DRAINMOD has been used to evaluate wetland hydrology (Skaggs et a/., 1993). The model has also been used to evaluate wetland hydrology criteria and threshold drain spacing for various soils and criteria (Skaggs et a/., 1994) WATER BALANCE The water balances in DRAINMOD involve two basic equations. The first equation is a water balance in the soil profile: AV.=D+ET+DS-F (1) Where: AV. = change in air volume D = drainage from the profile 5 ET = actual evapotranspiration from the profile DS = deep seepage from the profile F = infiltration into the profile The second equation is a water balance at the soil surface: AS = P - F - RO Where: AS = change in volume of water stored at the soil surface P = precipitation F = infiltration volume RO = surface runoff Methods for evaluating equation variables are discussed in detail in Skaggs (1980). (2) The hydrology of various soil water conditions applicable to the study area was simulated using DRAINMOD. The simulations were conducted from 1951 to 1990 using climatological data from Plymouth, North Carolina. Tables 1 and 2 summarize the soil parameters used in the DRAINMOD simulations. Appendix B contains the results of the slug testing conducted on soils at the site. MODEL CALIBRATION The hydrology of various soil water conditions applicable to the study site was simulated using DRAINMOD. The simulation used the soil water characteristics of the Portsmouth and Roanoke soils. Soil input parameters for DRAINMOD were calculated by the NRCS model, DMSOIL (Baumer and Rice, 1988) using soil texture data from soil samples collected on site, and existing data from prior research. Soil hydraulic conductivity values used in DRAINMOD simulations were determined from the on-site slug test data. The simulations were conducted for the years from 1951 to 1990 using climatological record from Plymouth, North Carolina. The model simulates the fluctuations in the water table depth at the mid point between ditches spaced a given distance apart. DRAINMOD simulations were conducted for a ditch depth of 2 ft (60 cm) (the maximum ditching depth shown on plan drawings) and various distances. An impermeable layer was assumed to be present at a depth of 9.8 ft(300 cm) based upon data collected from the soil borings. For this study the simulations modeled the effects of a two-ditch system with spacing at distances ranging from 50 ft (15 m) to 197 ft (60 m). The ditch spacings are approximately twice the distances that a single ditch is expected to influence. 6 Table 1 Soil Input Parameters for Roanoke Soil Volume rained, pf ux, Green-Ampt Parameters, and Hydraulic Conductivity for Roanoke Soil Water Table Depth (cm) Volume Drained (cm) Upflux (cm/hr) 0.0 0.00 0.1000 10.0 0.25 0.0800 20.0 0.40 0.0600 30.0 0.65 0.0500 40.0 0.92 0.0400 50.0 1.35 0.0200 60.0 1.85 0.0063 70.0 2.53 0.0025 80.0 3.40 0.0016 90.0 4.45 0.0014 100.0 5.50 0.0011 120.0 7.50 0.0005 140.0 10.45 0.0003 160.0 13.40 0.0000. 200.0 19.30 0.0000 240.0 25.60 0.0000 280.0 32.10 0.0000 320.0 38.70 0.0000 1000.0 100.00 0.0000 Green-Ampt Parameters Water Table Depth (cm) A B 0.0 0.0 0.00 60.0 4.0 0.25 120.0 12.0 1.00 500.0 12.0 1.00 Saturated Hydraulic Conductivity Depth to Bottom of Layer K (cm/hr) 45 3.0 90 0.60 135 0.30 170 1.50 300.0 0.16 Table 2 Soil Input Parameters for Portsmouth Soil Volume drained, pf ux, Green-Ampt Parameters, and Hydraulic Conductivity for Portsmouth Soil Water Table Depth (cm) Volume Drained (cm) Upflux (cm/hr) 0.0 0.00 0.1000 10.0 0.1858 0.5000 20.0 0.488 0.2000 30.0 0.8328 0.0625 40.0 1.23 0.0306 50.0 1.6895 0.0142 60.0 2.20 0.0112 80.0 3.6244 0.0035 100.0 5.3624 0.0012 120.0 7.2505 0.0001 140.0 9.234 0.0000 160.0 11.3131 0.0000 180.0 13.5069 0.0000 200.0 15.82 0.0000 220.0 18.15 0.0000 240.0 20.49 0.0000 250.0 21.65 0.0000 1000.0 100.00 0.0000 Green-Ampt Parameters Water Table Depth (cm) A B 0.0 0.0 0.00 50.0 1.2 0.75 100.0 6.5 1.2 150.0 10.0 1.5 200.0 12.0 1.5 500.0 15.0 1.5 Saturated Hydraulic Conductivity Depth to Bottom of Layer . K (cm/hr) 60 2.00 300.0 0.375 The depth of depressional storage, used in the initial DRAINMOD simulations, was 1.6 in (4 cm) assuming that surface roughness would increase due to biological processes as vegetation recovers following construction. The simulations were repeated using a surface storage of 0.8 in (2 cm) to simulate a site that was graded and maintained by human intervention. ESI expects that the actual surface storage will vary between these values dependent on factors such as distance from the ditch, vegetation types, and other influences. The rooting depth function used in the simulation was a constant depth of 12 in (30 cm), which is an average value used for mixed forest and grass covered lands. MODEL RESULTS The DRAINMOD simulations predicted wetland hydrology criteria would be met at a distance from the ditch of 50 ft (15 m) in the Portsmouth soil and 57 ft (17.5 m) in the Roanoke soil for a surface storage of 1.6 in (4 cm). Modeling a surface storage of 0.8 (2 cm) in resulted in distances from the mid point of the ditch of 74 ft (22.5 m) and 98 ft (30 m) for the Portsmouth and Roanoke soils respectively. The average zone of influence for the respective soils is 62.5 ft (19.1 m) for the Portsmouth and 77.5 ft (23.6 m)for the Roanoke. Using these averages approximately 10 acres (4.1 ha) of additional impacts. will occur (calculated impacts range from 7.6 acres (3.1 ha) to 12.6 acres (5.1)). Based upon the data in NCDOT's permit application to the U.S. Army Corps of Engineers (COE) dated 7 February 1994 the proposed ditches would increase the impacted wetlands as presented in Table 3. ADDITIONAL RESEARCH Published literature regarding ditch impacts in situations similar to those of this study has been found to be rare and somewhat inconsistent. Several studies have been based on observations without empirical data. For example, Sharitz and Gibbons (1982) found that ditch impacts on adjacent plant communities are generally localized and limited in extent. However the authors provided no data in their report supporting their claims. Site specific studies were performed by Skaggs et al (1994) in New Hanover County, North Carolina using DRAINMOD to predict ditch impacts on wetlands. This study forecast a zone of influence of 107 ft (32.5 m) to 157 ft (48 m) in Portsmouth soils with 1-2 in (2.5 -5 cm) of surface storage. However the Skaggs study involved ditch depths of 4 ft (1.2 m) - approximately twice the depth of the US 17 study, and hydraulic conductivities substantially greater than those measured at the US 17 sites. Both of these factors greatly affect the zone of influence extending out from the ditches. When the Skaggs data was re-analyzed for 2-ft (60 cm) ditches, the zone of influence was reduced to a range of 82 ft (25 m) to 131 ft (40 m). It is reasonable to assume that if the soil hydraulic conductivities in the Skaggs study had been lower, the forecasted zone of influence would have been smaller and closer to the forecasted distances found in the US 17 study. 9 Table 3 Projected Additional Wetland Impacts From R-2208A Site Project Station Soil Type Length of Average Distance Additional * Ditching (ft/m) of Influence Area (ft/m) Impacted by Ditching (Acres/ha) 4 52 + 60 to 69+15 Portsmouth 1655/504.4 62.5 / 19 2.4/.9 9 213+95 to 225 + 00 Roanoke 1105/336.8 77.5/23. 6 2.0/.8 10 247 + 20 to 259 + 80 Roanoke 1260/384 77.5/23.6 2.2/.9 13 270+40 to 284+15 Roanoke 1375/419.1 77.5/23.6 2.5/1.0 Misc. 14 minor wetland Roanoke 605/184.4 77.5/23.6 1.1 /.4 excavation sites Totals 10.11 /4.1 *See Figure 2 for locations of sites 4, 9, 10, and 13. All sites consist of r1onriverine/interstream forest. 10 The Agricultural Water Table Management guidelines (NRCS 1986b) have often been employed as standard protocol for designing drainage systems in eastern North Carolina by farmers and agricultural engineers. These guidelines contain sets of standard equations which utilize certain parameters measured in the field which allow the user to predict spacing and depth of ditches (or drains) in an effort to maximize crop yields. However, it is important to note that values for zones of influence vary greatly depending on baseline information used in calculations. For example, zones of influence were found to vary from 18 ft ( 5.5 m) to 117 ft (35.7 m) in Portsmouth soils assuming a 2-ft (60 cm) ditch depth and targeted water table depths ranging between 0 to 12 in (0 -30 cm) below the surface. The widely variable range demonstrates the importance and need for site specific information, such as in situ hydraulic conductivities, on calculating the zone of influence in varying soil types under certain, well defined conditions. Based upon available information, the work performed on the US 17 project is a demonstrable, marked improvement over existing, subjective assessments of zonal ditch influence. Site specific data using tested analytical models afford a more realistic picture of probable ditch impacts, as compared to the sole use of empirical observation, or NRCS guidelines where site specific data is not utilized. Therefore, the average zone of influence of 62 ft (19 m) to 77 ft (23.6 m) for ditching in Portsmouth and Roanoke soils assuming a ditch depth of 2 ft (.6 m) as in this project, is believed to constitute a reasonable representation of average field conditions in the project area. Due to the variability of site specific parameters such as hydraulic conductivity, infiltration capacity, or surface storage from site to site, it is very important to collect and interpret in situ field data on a case by case basis for future studies. CONCLUSIONS Based upon field observations, and available data, ESI has developed the following conclusions for this site: • The soils encountered on site and hydrological conditions observed, are consistent with the mapping performed by the NRCS. • DRAINMOD simulations indicate that the zone of influence of ditching varies from a minimum of 50 ft (15 m) to a maximum of 98 ft (30 m)based on varied surface storage characteristics. The average zones of influence are 62 ft (19 m), for the Portsmouth soil and 77 ft (23.6 m)for the Roanoke soil. • A review of existing literature indicates that observed impacts from road side ditching are inferred to be localized to the immediate area of the ditches. Previous studies using DRAINMOD infer that the US 17 findings are within reasonable expectations given existing field characteristics and in situ soil properties. Other methodologies, such as NRCS guidelines provide widely variable results and were discounted for use in 11 evaluating ditch impacts associated with this project. Based on model results, the proposed ditches along the alignment would increase the impacted amount of wetland by an average of 10 acres (4 ha) (ranging from 7.6 acres (3.1 ha) to 12.6 acres (5.1 ha)). 12 REFERENCES CITED Baumer, 0. and J. Rice, 1988. Methods to predict soil input data for DRAINMOD ASAE Paper No. 88-2564. ASAE, St. Joseph, MI 49085. Belcher, H.W. and G.E. Merva, 1987. Results of DRAINMOD verification study for Zeigenfuss, soil and Michigan climate. ASAE Paper No. 87-2554. ASAE, St. Joseph, MI 49085. Bower H. and R.C. Rice, 1976. A slug test for determining conductivity of unconfined aquifers with completely or partially penetrating wells. Water Resources Research. 12: 423-428. Bouwer, H., 1989. The Bouwer and Rice slug test -- an update. Ground Water. 27 (3): 304-309. Fouss, J. L., R. L. Bengtson and C.E. Carter, 1987. Simulating subsurface drainage in the lower Mississippi Valley with DRAINMOD. Transactions of the ASAE 30 (6): 1679 - 1688. Gayle, G., R.W. Skaggs and C.E. Carter, 1985. Evaluation of a water management model for a Louisiana sugar cane field. J. of Am. Soc. of Sugar Cane Technologists, 4: 18 - 28. Hvorslev, M.J. 1951. Time lag and soil permeability in groundwater observations. U.S. Army Corps of Engineers Waterways Experimental Station Bulletin 36, Vicksburg, MS. Rogers, J.S., 1985. Water management model evaluation for shallow sandy soils. . Transactions of the ASAE 28 (3): 785-790. Sharitz, R.R. and J.W. Gibbons, 1982. The ecology of southeastern shrub bogs (pocosins) and Carolina bays: a community profile. U.S. Fish and Wildlife Service, Div. of Ecological Services, Washington DC. FWS/OBS-82/04. Skaggs, R.W., 1980. A water management model for artificially drained soils. Tech. Bull. No. 267, North Carolina Agricultural Research Service, N.C. State University, Raleigh. 54 pp- Skaggs, R.W., 1982. Field evaluation of a water management simulation model. Transactions of the ASAE 25 (3): 666 - 674. Skaggs, R.W., D. Amataya, R.O. Evans, and J.E. Parsons, 1994. Characterization and evaluation of proposed hydrologic, criteria for wetlands. Journal of Soil and Water Conservation 49 (5): 501-510. 13 Skaggs, R.W., N.R. Fausey and B.H. Nolte, 1981. Water management evaluation for North Central Ohio. Transactions of the ASAE 24 (4): 922 - 928. Skaggs, R.W., J.W. Gilliam and R.O. Evans, 1991. A computer simulation study of pocosin hydrology. Wetlands (1 1): 399 416. Skaggs, R.W., et a[, 1993. Methods for Evaluating Wetland Hydrology. ASAE meeting presentation Paper No. 921590. 21 p. Susanto, R.H., J. Feyen, W. Dierickx and G. Wyseure, 1987. The use of simulation models to evaluate the performance of subsurface drainage systems. Proc. of Third International Drainage Workshop, Ohio State Univ., pp. A67 - A76. USDA-NRCS. 1986. Soil Survey of Chowan and Perquimans Counties, North Carolina. Publication of the National Cooperative Soil Survey. USDA-NRCS. 1986. Agricultural Water Table Management "A guide for eastern North Carolina." 14 N y a? rn M H- O N cc m F- ? m N co E M b b b b b b b b b x x x x X X ?- ` M r- O e- M M X X X 't ac L N M M m d ao to co m m y r to co N d' M N N N b b N b b b b b b L x _ _ _ It x x M X M CO m E co am M to d- rn rn ?- hC U cM d P? N P? n b b b b b b b b b V- r- T- r- T T- r- X X * rn 0 O (o CD 1f cX C D tO M n N O tG O Lo ]G CO N N d M N N M b b b b b L u x * x w m x co O * E O N co 't O M = hL U N n r-? CC a0 M N * J CD (D ' 04 0) ?, t0 N to ? CO to I? ui m N O 4 ui vi > L L o 0 E .c co a0 I? N M CL E N it O d U) U) N N r- 0) T . H a r co P4 r4 ao ao c6 c; L N }' Uc co O to O O O O to o {- 0 cv w w 0 1? ao of m of d L ? + + 4 O > > O O O cn cn ca C C C C C C L ? ` w co co co o c m y, I a a / a oC ?.. I.I o c It ? / li cc rn 6 ' ? N M ? to CO 1? 00 ? o Z m a a a a a d. a a a 0 10 10 10 0 0 0 O a> U _m N -o c 7 O L O NO L CL a) (D CD J L V a) to O M N CD m ? L N 0 J = L vn a rn CD M n rn m U_ co 7 O m CD a * r JOB: ER94018.2 LOGGED By._B.L. Hayes DRILLED By. B.L. Hayes DRILL RIG: DRILLING METHOD: Hand Auger DATE DRILLED. 4 April 1995 SAMPLE PID U.S.C. SOIL DESCRIPTION TYPE REC RESIST (PPM) Black, organic, rich, sandy LOAM; abundant roots A A A A A 1.0'- Gray, very fine SAND; trace clay and sift 1 ?1.5'- Becoming orange, mottled, clayey, fine SAND 2 3 3.0'- Becoming sandier, moist 3.5- Becoming gray, very fine SAND; wet 41? 4.0'- Becoming slightly clayey, mottled orange 5-r///? 5.0' -Becoming sandier, saturated H W 5.5' - Becoming slightly clayey; saturated LL = 6 F- W As above O 7 V11Z 8 8.5'- Termination of drilling - no recovery; saturated 9 10 11 12 SOUTHEASTERN DP-1 Dit h I d S FILE NAME: DP01 DSML ENVIRONMENTAL c mpact tu y US-17 Widening MADE BY: PS AUDITS INC R-2208A . CHECKE NCDOT D BY: BH A-1 JOB: ER94018.2 LOGGED BY: J.L. Hardy DRILLED BY• B.L. Hayes DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED.. 4 April 1995 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC RESIST (PPM) Gray, slightly, clayey, fine SAND Becoming clayey at 8.0 1 Gray, mottled orange, clayey, very fine SAND 2 -? 3 Gray, mottled, orange, clayey, very fine SAND Becoming sandier q 4.0'- Gray, slightly mottled, orange, fine SAND; wet Becoming wetter 5 Gray, mottled, orange, fine SAND; saturated W LL = 6 •' Blue-gray, fine SAND; saturated H W 7 As above 8 As above 8.6 - Termination of drilling 9 10 11 12 SOUTHEASTERN DP-2 d S FILE NAME: DP02DSML ENVIRONMENTAL y Ditch Impact tu US-17 widening MADE BY. PS AUDITS INC R-2208A , . E NCDOT CH CKED BY: BH A-2 JOB: ER94018.2 LOGGED BY: J.L. Hardy DRILLED BY- B•L HayeS 1 2 3 4 5 1- W W U. = 6 f- a W D 7 DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED. 4 April 1995 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC RESIST (PPM) 0.5'- Black, organic, muck; wet 1.0'- Gray, very clayey, very fine SAND; with roots, saturated 1.5'- Gray, silty CLAY, trace sand 8- 9- 10- 11 12 2.5'- Becoming sandier 3.0'- Gray, slightly mottled, orange, clayey SAND As above 5.0'- Termination of drilling As above SOUTHEASTERN DP-3 h I d Di t St FILE NAME: DP03DSML ENVIRONMENTAL mpac y tc u US-17 Widening MADE BY: PS AUDITS INC R-2208A . CHECK NCDOT ED BY: BH A-.3 JOB: ER94018.2 LOGGED BY: J.L. Hardy DRILLED By.. B.L. Hayes DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED. 5 April 1995 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC RESIST (PPM) Dark brown, slightly mottled, silty CLAY 1 1.0'- Becoming gray, slightly mottled orange 2 1 1 1 As above 3 As above 3.5- Becoming sandy, moist 4 Gray, clayey, fine SAND; moist 4.5' - Brown-gray, slightly silty, fine SAND; wet 5 5.0'- Brown-gray, mottled, slightly clayey, fine SAND; wet W W U. = 6 6.0'- Gray, slightly clayey, fine SAND; saturated a W 7 7 0' - Becoming mottled orange; more clayey - Termination of drilling r75 8- 9- 10- 12 SOUTHEASTERN DP-4 FILE NAME: DP04DSML ENVIRONMENTAL Ditch Impact Study US-17 widening R-2208A MADE BY: PS AUDITS INC. NCDOT CHECKED BY: BH A-4 JOB: ER94018.2 LOGGED BY: J.L. Hardy DRILLED By. B.L. Hayes DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED- 5 April 1995 SAMPLE U.S.C. SOIL DESCRIPTION PID TYPE REC RESIST (PPM) 0 - 6.0" - Dark brown, organic, rich LOAM j Mottled gray-orange, slightly sandy CLAY 1 1.5" - Mottled gray-orange, silty CLAY; very stiff 2 / 2.0'- Slightly mottled gray, highly plastic CLAY 2.5- Soft, gray CLAY; moist 3 3.0'- Becoming sandy 3.5- Gray, very silty, fine SAND 4 4.0'- Gray, slightly silty, fine SAND; wet 4.5- As above; saturated 5 As above W W 5.5- mottled orange; saturated U. 3 6 60 - Becoming slightly clayey; saturated 1- a W 0 7 As above 8 8.0' -Termination of drilling 9 10 11 12 SOUTHEASTERN DP-5 FILE NAME: DP05DSML ENVIRONMENTAL Ditch Impact Study US-17 Widening MADE BY: PS R-2208A AUDITS, INC. CHECKED BY NCDOT . BH A-5 JOB: ER94018.2 LOGGED BY: J.L. Hardy DRILLED By. B.L. Hayes DRILL RIG: B.L. Hayes DRIWNGMETHOO: Hand Auger DATE DRILLED. 5 April 1995 SAMPLE U.S.C. SOIL DESCRIPTION PiD TYPE REC RESIST (PPNQ 0- 3" - Dark brown omar ,/ 6" - Dark gray, mottled or 1 1.0" - As above 1.5" - Becoming very stiff 2 As above 3 i% 3.0'- Becoming sandy 3.5'- Gray, slightly mottled orange, sandy CLAY 4 4.0'- As above 4.5'- Light gray, fine SAND; wet 5 As above; saturated W Becoming clayey, blue-gray LL 3 6 Blue-gray, clayey, fine SAND; saturated a W D Blue-gray, very clayey, SAND $ Becoming greenish-blue 9.0'- Greenish-blue, sandy CLAY 9 9.0'- Termination of drilling 10 11 12 SOUTHEASTERN DP-6 FILE NAME: DP06DSML 1 D ENVIRONMENTAL US 7 Widening MADE BY. PS AUDITS INC R-2208A , . CHECKED NCDOT BY: BH A-6 1 2 3 4 5 1- W W LL = 6 1 a 0 D 7 8 9 10 11 12 JOB: ER94018.2 LOGGED BY: J. L- Hardy DRILLED By. B.L. Hayes DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED: 4 April 1995 SAMPLE U.S.C. SOIL DESCRIPTION PiD TYPE REC RESIST (PPM) Black, organic, rich, sandy, clayey LOAM Becoming sandier; gray 1.5' - Very moist, gray, sandy CLAY Firm, gray, slightly mottled orange, silty CLAY 2.5'- Becoming sandier Soft, gray, slightly mottled orange, sandy CLAY 3.5'- As above; very moist Gray, slightly mottled, slightly clayey, fine SAND; very moist 4.5' - As above As above; wet 5.5'- Tan, mottled orange, slightly clayey, fine SAND; wet Becoming mottled with gray 6.5'- Blue-green, slightly clayey, fine SAND As above; saturated As above As above As above 9.0' - Termination of drilling - no recovery SOUTHEASTERN DP-7 FILE NAME: DP07DSML ENVIRONMENTAL Ditch Impact Study US-17 Widening MADE BY. PS AUDITS INC R-2208A . CHECKE NCDOT D BY: BH A-7 JOB: ER94018.2 LOGGED BY: J. L. Hardy DRILLED BY• B.L. Hayes DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED. 4 April 1995 S AMPLE P(D U.S.C. SOIL DESCRIPTION TYPE REC RESIST (PPM 0-6" - Black, organic, rich, silty, clayey LOAM Firm gray, slightly mottled orange CLAY 1 As above 2 As above; trace fine sand 2.5'- Very moist, light gray, slightly clayey, fine SAND 3 Light gray, slightly silty, fine SAND; wet 3.5' - Gray, mottled orange, sandy CLAY; saturated 4 As above 4.5' - Gray, mottled, orange, slightly clayey, fine SAND; wet 5 As above; saturated F- LU As above UJI No recovery = 6 a W 7 Becoming browner; more clayey As above 8 As above As above 9 90-Termination of drilling 10 11 12 SOUTHEASTERN DP-8 FILE NAME: DP08DSML ENVIRONMENTAL Ditch Impact Study US-17 Widening MADE BY: PS R-2208A AUDITS INC. CHECKED BY NCDOT : BH A-8 SAMPLE TYPE REC I 1 2 3 4 ?i W W LL = 6 rr- a W D 7 8- 9- 10- 11 12 SOUTHEASTERN ENVIRONMENTAL AUDITS, INC. JOB: ER94018.2 LOGGED BY: J. L. Hardy DRILLED BY- B.L. Hayes DRILL RIG: B.L. Hayes DRILLING METHOD: Hand Auger DATE DRILLED- 4 April 1995 U.S.C. SOIL DESCRIPTION P)D (PPM) 0-6" - Dark gray, silty CLAY; saturated at 2" Gray, slightly mottled orange, silty CLAY; saturated As above 2.5' - Becoming sandy Gray, mottled orange, clayey, fine SAND 3.5'- As above Orange, mottled gray, clayey, fine SAND 4.5' - Becoming grayer 4.5' - Termination of drilling DP-9 Ditch Impact Study US-17 Widening R-2208A NCDOT FILE NAME: DP09DSML MADE BY: PS CHECKED BY. BH A-9 H a?+ d1 H 7 0 .N co m ? ? H H ? t m N W CE G 7 N N m N N m /7 O O O O O O m ? N x x x x x X w m r N M Ch Cfl d' OR Ln CO C9 Y . Lo CO N tt m N N O O N O N O O O O O m E of ? N CO IRt rn x CA X CO m -t x CD M CD co Y V M ?t 1? N n n Pf O N O N O ' N O tq O N O ? N O N O N O r r t ! r ! r r !" # r M Oo CO CD LO C9 CO d' .- x + to co N O co O LO Y CO N N et Lt) N N O O O O O O O * t LO x CD O 0 x co O * E O N Lo qt co - O x Y V N P? r-: CO OO C? N # J co CC) co q f- La N LO CO Lo r LL M N O LO M .- O w O O E CL E d Lo CO n N M T O It lO LO N N O F- a N w et r, N t? tp co th L 4r - I- H O Lo Lo O LO O O O O LO U OO Oo Lp 1-? OO to 6 6 4 L L L CD CL 7 O 7 O 7 O C? d to C9 W N ~ Y Y Y Y Y Y Y N M C C C C C C - ?. ? Lv m w cc m m O O O O O O O O O O cn a O_ a cc cr cc cr fr m rn o o Z N co 'Rt LO co N O0 O c CL CL CL CL d- d- d- OL CL 0 0 C IO 0 0 0 0 0 Ca U c6 7 fl7 C O 3 O (U .L7 O. ? o ? J '- O U C c0 _ CC > N N V1 N > O 7: C13 v~- N Q Q # DRAWDOWN TEST LL NO. Q / ` OP OF CASING ELEVATION =ROUND SURFACE ELEVATION CASING DIAMETER 2 BOREHOLE DIAMETER Z, 7 SCREEN DEPTH REFERENCE POINT T 0 r. AMOUNT OF WATER REMOVED LOCATION S -17 ..,? , DATE_ L f -V-`7 5 TIME?[ COMPUT D BY y u-?? ASSISTED BY PERSONS OBSERVING ff 4r ?J d lea/f r EVACUATION METHOD_ 3, , j e. STATIC WATER LEVEL _ 6. i L S-r('c.e 7.1! RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho a o q 3? ?,a6 d ?o ?v z S? ?Y4- 3 o, zz 3G 10 Z 12d .d 1.?9 ?.sgz '?.? ?? 15-0 7; Z 1. Sv 0.490 . Lr d -33a -? 1?i7 o3?z L4U 7, 3 !,(1 z a, 333 300 7 U . 2 d. 2? 6'ld 310 7.02 O. 7o z2? C, ?Lf 0, 6,7- 0, 26 kid (. 6 0. s y o. 179- go, 6d 77 0. ? 0,/4,7 fZ.S 7 SO so G • 2 / 3o NOTES B-1 DP-1 time dtw H WHO 0 9.38 3.06 1 30 8.90 2.58 0.843137 60 8.53 2.21 0.722222 90 8.25 1.93 0.630719 120 8.01 1.69 0.552288 150 7.82 1.50 0.490196 180 7.64 1.32 0.431373 210 7.49 1.17 0.382353 240 7.34 1.02 0.333333 300 7.14 0.82 0.267974 370 7.02 0.70 0.228758 420 6.94 0.62 0.202614 480 6.86 0.54 0.176471 600 6.77 0.45 0.147059 750 6.69 0.37 0.120915 B-2 DP-1 recovery vs. time - - - best fit U 1.00- 9 8 7 6 5 4 0.10 i ? 1 ? i i ? 0.00 200.00 400.00 TIME (sec) 600.00 800.00 B-3 Well Number: n P-t Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: Computed By: 9,1-, d = .S (cm) D = (cm) L = /32 (cm) T = 2g- d (seconds) k d2 in r 2mL 1 m= 1 h D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal/kvertical Assume kh = kv = 1 2, U 11X(v 13?? ,, z B-4 DRAWDOWN TEST fA LL NO. Q ? - Z- P OF CASING ELEVATION OUND SURFACE ELEVATION SING DIAMETER Z BOREHOLE DIAMETER s, 7 SCREEN DEPTH REFERENCE POINT % 0 L AMOUNT OF WATER REMOVED LOCATION DATE 4 - 5 TIME COMPUTED BY // 4 ,., , / .- ASSISTED BY PERSONS OBSERVING EVACUATION METHOD STATIC WATER LEVEL RECOVERY DATA ELAPSED TIME GROUNDWATER DEPTH H H/Ho 0 . a o ?.S 1 o t.-3 ° b. 3 s s s 6 S, a to ' a iz s S, oS l ? rya 1-1 NOTES d•s1 3$ .r t °I B-5 DP-2 time dtw H WHO 0 8.20 3.69 1 30 7.58 3.07 0.831978 60 7.04 2.53 0.685637 90 6.80 2.29 0.620596 120 6.65 2.14 0.579946 150 6.49 1.98 0.536585 180 6.33 1.82 0.493225 240 6.07 1.56 0.422764 300 5.88 1.37 0.371274 360 5.71 1.20 0.325203 420 5.55 1.04 0.281843 480 , 5.42 0.91 0.246612 600 5.23 0.72 0.195122 750 5.05 0.54 0.146341 900 4.93 0.42 0.113821 B-6 DP-2 recovery vs. time 1.00 - 9 8 7 6 5 4 = 3 2 0.10 - - - best fit I ? I ? I I 170 0.00 200.00 400.00 600.00 TIME (sec) 800.00 1000.00 B-7 Well Number: D?, 2 Date: Computed By: yla 1'1S Casing diameter d = 5 (cm) Borehole diameter D = 7 (cm) Length of screen L = 187 (cm) Time lag at 0.37 H-/Ho T = 330 (seconds) k= d2 in r 2mL 1 m= 1 h L D J 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal ?kvertical Assume kh = kv =1 B-8 DRAWDOWN TEST WELL NO.--UP 3 OP OF CASING- AS G ELEVATION ROUND SURFACE ELEVATION 4ASING DIAMETER V BOREHOLE DIAMETER_ 2, 7 SCREEN DEPTH REFERENCE POINT To AMOUNT OF WATER REMOVED LOCATION DATE_ u - Lk- 9<?- TIME COMPUTED BY -St-t ASSISTED BY PERSONS OBSERVING EVACUATION METHOD_ STATIC WATER LEVEL _ _ a \ RECOVERY DATA y ELAPSED TIME GROUNDWATER DEPTH H H/Hq 0 V-zc 14. -4 Li ` G y 3 g /L U 4 3-ao 150 3.51 3-3n??6 3. A t L(0 S 270 6 . 330 ?. ?9d g 4S? A. STo }a t 7za ?•. t3 I 20 311. NOTES B-9 DP-3 time dtw H WHO 0 5.08 4.27 1 30 4.74 3.93 0.920375 60 4.41 3.60 0.843091 90 3.86 3.05 0.714286 120 3.64 2.83 0.662763 150 3.51 2.70 0.632319 180 3.42 2.61 0.611241 210 3.32 2.51 0.587822 270 3.02 2.21 0.517564 330 2.76 1.95 0.456674 390 2.50 1.69 0.395785 450 2.22 1.41 0.330211 570 1.72 0.91 0.213115 B-10 DP-3 recovery vs. time best fit 2 1.00 0.10 i i J i 0.00 200.00 400.00 600.00 Time (sec) B-1 1 Well Number: DP- 3 Casing diameter Borehole diameter Length of screen Time lag at 0.37 HJH0 Date: Computed By: /3.4 AoyP1 -- I d = S (cm) D 7 (cm) L = Y4t41 (cm) T = 3SIL (seconds) k d2 In r 2mL m = 1 h L D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. Note: m = khorizontal/kvertieal Assume kh = kv = 1 kh = 2. 0 ? WO If c?/s / A1ti1 B-12 DRAWDOWN TEST WELLNO. ()P- U SOP OF CASING ELEVATION ROUND SURFACE ELEVATION --CASING DIAMETER 2 `' BOREHOLE DIAMETER 2 , 75 SCREEN DEPTH REFERENCE POINT To AMOUNT OF WATER REMOVED LOCATION ?,- 7, / j DATE a ,¢nn - / 'i S TIME (? d COMPUTED BY /4 „ /ASSISTED BY PERSONS OBSERVING EVACUATION METHOD ?/3 , •%, STATIC WATER LEVEL ?.Z`1 s9ory RECOVERY DATA t. ELAPSED TIME GROUNDWATER DEPTH H H/Ho Q 9.2-4 1,01 3 ?. ?? s .a . TO 2 ? SS 3 (? ?2 ° 0, /1 L Y o zc• 4 off t,ocy 0.36 4 a. a 7 .5 ( d (G .Ks 1 ?• 3 S 4.33 ?U 30 14u NOTES Z 3 X (? ' CL 20 T= e - l 1 B-13 DP-4 time dtw H WHO 0 9.87 2.87 1 30 9.48 2.48 0.864111 60 9.12 2.12 0.738676 90 8.90 1.90 0.662021 120 8.58 1.58 0.550523 150 8.38 1.38 0.480836 180 8.20 1.20 0.418118 210 8.04 1.04 0.362369 240 7.92 0.92 0.320557 300 7.75 0.75 0.261324 360 7.65 0.65 0.226481 420 7.58 0.58 0.202091 480 7.54 0.54 0.188153 600 7.45 0.45 0.156794 750 7.38 0.38 0.132404 900 7.33 0.33 0.114983 B-14 DP-4 recovery vs. time - - - best fit z 1.00 E L 2 0.10 \ I I \ \ I I I \ \ \ I \ I I \ Zyo 0.00 200.00 400.00 600.00 Time (sec) 800.00 1000.00 B-15 Well Number: 0,P- y Casing diameter Borehole diameter Length of screen 71me lag at 0.37 H-/Ho Date: Computed By: 13. /{?yPr d = '9 S (cm) D = 7 (cm) L (cm) T = 2 it d (seconds) kh = d2 In C 2mL 1 m = 1 D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal/kvertical kh= ?.US l ?6 Assume kh =k v =1 B-16 DRAWDOWN TEST WELL NO. D F- -S TOP OF CASING ELEVATION GROUND SURFACE ELEVATION CASING DIAMETER 'a BOREHOLE DIAMETER a,-45 SCREEN DEPTH REFERENCE POINT -TO r: AMOUNT OF WATER REMOVED LOCATION- ,?; Ae DATE y-? _q ?- TIME COMPUTED BY: t-1 ASSISTED BY r-3LK PERSONS OBSERVING EVACUATION METHOD , ; 1 e. a STATIC WATER LEVEL '4, q g tu,73 x.98 RECOVERY DATA -Z 5 ELAPSED TIME GROUNDWATER DEPTH H WHO O I 3 Zr 3S ?. o O 30 ? zS Z 3 10 4 1 . F S 1 6 off 1 oA .9 15 z (5d' leo i-I -2 (1 1., Ta 15•5\ v. 53 0, 23 XTi -Tn z? B-1/ DP-5 time dtw H WHO 0 10.33 2.35 1 60 10.25 2.27 0.965957 90 10.18 2.20 0.93617 120 10.18 2.20 0.93617 180 10.14 2.16 0.919149 240 10.10 2.12 0.902128 300 10.06 2.08 0.885106 360 10.04 2.06 0.876596 420 10.02 2.04 0.868085 600 9.91 1.93 0.821277 900 9.76 1.78 0.757447 1500 9.51 1.53 0.651064 2100 9.16 1.18 0.502128 3780 8.50 0.52 0.221277 B-18 DP -5 recovery vs. time 1.00 9 8 7 6 5 4 3 I 0.10 - - - best fit i i I 0.00 1000.00 2000.00 Time (sec) 3000.00 4000.00 B-19 Well Number: OP-5 Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/H0 Date: Computed By: 13. L. / P-r d = S (cm) D = 7 (cm) L = $/ (cm) T = Z6?_3 (seconds) kh = d2 In 12 m L 1 8 LT m=1 Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. Note: m = khorizontal /kvertical Assu me kh = kv = 1 kh = ?. S 2 X (o K(°- ) /n4 B-20 DRAWDOWN TEST WELL NO. 9p-S. P OF CASING ELEVATION ROUND SURFACE ELEVATION -ASING DIAMETER Z BOREHOLE DIAMETER_ 2 .?S SCREEN DEPTH REFERENCE POINT -m c AMOUNT OF WATER REMOVED LOCATION DATE_ ti _ _ q•s TIME COMPUTED BY t1 ASSISTED BY g k PERSONS OBSERVING EVACUATION METHOD_ k,, A STATIC WATER LEVEL _ S. 3 3 RECOVERY DATA `d . 3 j S ?3 3 5 5 . ?, ELAPSED TIME GROUNDWATER DEPTH H H/Ho U 83 5. ?0 da :3a $ 3B 1 a 1'•'i I ?- ?(9 ?' 30 3 '? . 4 4 b she Io. ? (.Y j b. ?f J a if7 ID a Iz. s IS s a /0 c 1-4• 7Z 5.x+3 "I NOTES B-21 DP-6 time dtw H WHO 0 8.83 3.50 1.000 30 8.38 3.05 0.871 60 8.22 2.89 0.826 90 7.99 2.66 0.760 120 7.83 2.50 0.714 150 7.66 2.33 0.666 180 7.44 2.11 0.603 210 7.31 1.98 0.566 240 7.18 1.85 0.529 300 6.97 1.64 0.469 360 6.76 1.43 0.409 420 6.59 1.26 0.360 480 6.50 1.17 0.334 600 6.22 0.89 0.254 750 6.00 0.67 0.191 900 5.82 0.49 0.140 1069 5.68 0.35 0.100 B-22 DP-6 recovery vs. time 1.00 - 9 8 7 6 5 4 A r 3 2 0.10 - - - best fit - i I i ? I i i i I b f i b 0.00 400.00 800.00 1200.00 Time (sec) B-23 Well Number: (),P- L Casing diameter Borehole diameter Length of screen Time lag at 0.37 H-/Ho Date: Computed By: 13 , Gt '/4,, rf d = 5 (cm) D = 7 (cm) L = g L' (cm) T = 436 (seconds) k d2 In r -2m--L 1 m= 1 h D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal/k vertical Assume kh = kv = 1 kh = /. 7 2ly - y c'./S. B-24 DRAWDOWN TEST LL NO. IJP- --:? P OF CASING ELEVATION OUND SURFACE ELEVATION SING DIAMETER a BOREHOLE DIAMETER a . ? SCREEN DEPTH REFERENCE POINT TOL " AMOUNT OF WATER REMOVP LOCATION DATE 4 - C - 9 TIME COMPUTED BY _ ASSISTED BY t3-K PERSONS OBSERVING EVACUATION METHOD 6, kc d STATIC WATER LEVEL 3. z 3 ':?,'3'z ZS 3• q3 `' ? RECOVERY DATA --4-,-601 3 ELAPSED TRAE GROUNDWATER DEPTH H H/H, o . 3a L d . d d . o b . S(o Z? S 9 75 S. S 3' 3o S • a 4 zti? 4 9 (? 7 s o Y S ??o y. s ?, 31 3 Z 3.94 & 3.-4 6.St? IZ.S IS Zo 3a ,z 1 G ?. B-25 DP-7 time dtw H WHO 0 7.32 4.09 1.000 36 6.56 3.33 0.814 60 6.17 2.94 0.719 90 6.18 2.95 0.721 120 6.27 3.04 0.743 150 5.95 2.72 0.665 180 5.58 2.35 0.575 210 5.23 2.00 0.489 240 4.98 1.75 0.428 300 4.54 1.31 0.320 360 4.20 0.97 0.237 420 3.97 0.74 0.181 480 3.79 0.56 0.137 536 3.64 0.41 0.100 B-26 DP-7 recovery vs. time - - - best fit -6 2 1.00 0.10 i i I , s? 0.00 200.00 400.00 600.00 Time (sec) B-27 Well Number: np-7 Casing diameter Borehole diameter Length of screen Time lag at 0.37 HIH0 Date: Computed By: d = S (cm) D = 7 (cm) L = 2L,C (cm) T = 2- 5", (seconds) kh = d2 In C 2 m L 1 m= 1 D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn be Fang, pp. 29-35. Note: m = khorizontal/kvertical Assume kh = kv = 1 kh = Z ZS k(a-y eAZ? 8, l Y/0- 3 log B-28 DRAWDOWN TEST X LL NO. DP- 8 P OF CASING ELEVATION _OUND SURFACE ELEVATION CASING DIAMETER a BOREHOLE DIAMETER a , a< SCREEN DEPTH REFERENCE POINT -rvc- AMOUNT OF WATER REMOVED LOCATION S;Aa 9 DATE - 5 - q S TIME COMPUTED BY -<" ASSISTED BY '8+k PERSONS OBSERVING EVACUATION METHOD tea: \ c? rN STATIC WATER LEVEL 'C , 0 0 RECOVERY DATA yy 3 ELAPSED TIME GROUNDWATER DEPTH H H/Ho + L'•1V B .8S 3 $. 4 4 .s Lft0 6a" ?o . 0, A iz.5 S S 30 (1 9 NOT9S B-29 DP-8 time dtw H WHO 0 9.57 4.57 1 30 9.42 4.42 0.967177 60 9.22 4.22 0.923414 90 8.66 3.66 0.800875 130 8.85 3.85 0.842451 150 8.66 3.66 0.800875 180 8.44 3.44 0.752735 210 8.22 3.22 0.704595 240 8.04 3.04 0.665208 300 7.87 2.87 0.628009 360 7.54 2.54 0.555799 420 7.19 2.19 0.479212 480 6.88 1.88 0.411379 600 6.65 1.65 0.36105 750 6.59 1.59 0.347921 900 6.55 1.55 0.339168 1200 6.41 1.41 0.308534 1800 5.85 0.85 0.185996 2880 5.12 0.12 0.026258 B-30 DP-8 recovery vs. time 1.00 = 0.10 2 s E 2 0.01 - - - best fit G r ` i I I \ \ I \ I i i f i Bon 0.00 1000.00 2000.00 . Time (sec0 3000.00 B-31 PP, ? 14 12 A AND C 10 e E 1 (i 4M Le= w H - XrK,3 6, 3 r z.7f -rd c - (I h e 3 2 O I 5 t0 5o 100 500 1000 5000 Le It Fig. 2. Dimensionless parameters A, B, and C as a function of I Jr... fnr r,4 I., 10 11 1 B-47 .IMPERMEABLE .,FIGURE 1 Well Number: nP4 Casing diameter Borehole diameter Length of screen Time lag at 0.37 H,/Ho Date: Computed By: 13. L., d = S (cm) D = 7 (cm) L = I7Z (cm) T = 8o() (seconds) kh = d2 In C 2mL 1 m= 1 D 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = khorizontal? kvertical kh C A? Assume kh = kv = 1 B-32 14 12 A AND C 10 e E SS 31 H ' (Ih) to = ?D, z3 4rk/ 1 C = 2, 8 3 Z O I 5 t0 50 100 500 1000 5000 Lc /r Fig. 2. Dimensionless parameters A, B, and C as a function of I - /r... fnr „f I., ID 1. 1 B-43 IMPERMEABLE .-F?GuRE ? c DRAWDOWN TEST ==WELL NO. DP- g SOP OF CASING ELEVATION ,ROUND SURFACE ELEVATION CASING DIAMETER ( 5 BOREHOLE DIAME PER. SCREEN DEPTH REFERENCE POINT -Mc AMOUNT OF WATER REMOVED ELAPSED TIME GROUNDWATER DEPTH H H/Ho O Z. ZZ ?. O z.14 30 1.9z 1. -tZ 0, Ite x:30 1. 0•3y ?3S ( 3?lo a • 4 . 4? 3 43 Mk 1. '31 14 S4 1 . is 1 S 1 ?a LOCATION q DATE V-5-9r TIME COMPUTED BY ASSISTED BY gN PERSONS OBSERVING EVACUATION METHOD b?; IQ a STATIC WATER LEVEL 2.2z ?•2b \,Z(o "N RECOVERY DATA k 0 ,. d1 7 a 1( B-33 L, 3-1 r 11. DP-9 time dtw H WHO 0 2.22 0.96 1.000 15 2.14 0.88 0.917 30 1.92 0.66 0.688 45 60 1.80 1.72 0.54 0.46 0.563 0.479 90 1.60 0.34 0.354 120 1.53 0.27 0.281 150 1.47 0.21 O.2 180 1.43 0.17 210 240 294 1 .42 1.39 136 0.16 0.13 0.10 A B-34 DP-9 recovery vs. time best fit A 2 2 1.00 2 0.10 .d s 0.00 100.00 200.00 300.00 Time (sec) B-35 Well Number: /gyp-5 Casing diameter Borehole diameter Length of screen 71me lag at 0.37 H/H 0 Date: Computed By: lj L, d = S (cm) D = 7 (cm) L = /3/s (cm) T = - ios (seconds) k = d2 In r 2mL 1 h D J m=1 8 LT Note: This equation is valid only for a typical monitoring well situation. If the situation differs significantly consult Foundation Engineering Handbook, Winterkorn & Fang, pp. 29-35. Note: m = J-k--- horizontal/kvertical Assume kh = kv = 1 kh = ?lU X?? - k/:?c B-36 ? ?S4 Environmental Services, Inc. JOB NO. ER SHEET NO. DATE JOB NAME Z2,'4- A, a/ S.'? 4 .., e 1-2,, Tj 4 5 COMPUTED BY 13' SUBJECT - _r g /r ii/ f T r -r o jz' /r '4 y ?v,.ryr? d- JQ t Mrfb? CHECKED BY '!?<re /f pP k= (? ?Zx (,?Cy 2-5 4r C #1 2-V; e Y Z, ?1 , - c17 96<h, 2.s4er k- -r _ Yya sPc J1 4(, 11 y? r?= 2. Sy L /4 v . S c.4- 610sec y r31?o6 Y6 16'. "t ? K= 4(2,6 1) 7. q " ?, 21 o4xio "`?c"?f?L / XIliB to•ir Z?3 Z C?6s CZ?/qo_S) ?zC) 3 _ B-37 c:\coreldrw\pam\network\ jrid1-i . cdr DP-1 drawdown vs. time 10.00 s s 7 6 5 4 3 2 C 1.00 U 9 cu 8 Q. N 7 6 6 5 4 3 2 0.10 0.00 400.00 800.00 1200.00 Time (sec) B-38 DP-2 drawdown vs.time 10.00 s 8 7 6 5 4 3 2 1.00 co s a 8 U) 7 6 5 4 3 2 0.10 0.00 400.00 800.00 1200.00 Time (sec) B-39 DP-3 drawdown vs. time 10.00 s E 1.00 cc N \ O 0.10 0.00 400.00 800.00 1200.00 1600.00 B-40 pP,?/' r r e= 4,;f (raj 4 14 12 A ANO C to A- z. ?s i a o, Z( 1 = ZI4J 8 4 B E 3 s Z O i to -- too --- 1000 5000 Le /r. Fig. 2. Dimensionless parameters A, B, and C as a function ! f I /r f-, .._t .mot I_ rrn r. % B-41 'IMPERMEABLE F-I6 UR E 1 2 OP r 14 12 A AND C 10 l; E _ 6 s. 0 4 q7, 3 w v v.s 4 H 3 2 O 1 5 10 50 100 500 1000 5000 Le /r Fig. 2. Dimensionless parameters A, B, and C as a function B-42 IMPERMEABLE .:F?GuRE ! c ? "I ? U !0 • Z NO. Environmental Services, Inc. JOB SHEET NO. ER NO. 3 DATE -/ TAO/ 9f JOB NAME 20 '.CA c? Ski C i Li COMPUTED BY SUBJECT t o i ?v?vvn? d IQ 'c + Mr>1ft CHECKED BY 137-111 of- 7 30, zC/Cs.2J 3co 2.fy IGS. Z -? - 360 y? = 137, 1,4 yam' 3v_4? 2- el&) PC pp-? L. skit r? 2-SY l1 SO Y4- 2-W7- 2 L Z66 Y z Y = 3, 0 N,V cM F. B-44 cAcore1drw\pam\network\arid1-1.cdr 14 12 A AND C 10 e E e l LIP H - \Ih q 7, 3 `w 13 u??g 1 C- z . 7s B 3 2 O I 5 10 50 100 500 1000 5000 Le /r Fig. 2. Dimensionless parameters A, B, and C as a function B-45 .IMPERMEABLE F-IGURF ! c,- 14 12 A AND C 10 s 6 4 C S `?L (i?,j L e= ty -: L, 7. 3 " W C 13 8 3 2 10 5 10 50 100 500 1000 5000 Ce /r Fig. 2. Dimensionless parameters A, B, and C as a function t, , . . . . B-46 IMPERMEABLE Fa6U.RE 1 C / i / DP-7 drawdown vs. time 10.00 s 8 7 s 5 4 3 2 1.00 ? s CO) a. 8 7 s 5 \ 4 \ 3 \ 2 \ 0.10 0.00 200.00 400.00 600.00 800.00 Time (ft) B-48 DP-8 drawdown vs. time 10.00 8 7 6 5 4 3 2 1.00 U 9 t? 8 Q CO) 7 5 6 5 4 3 2 0.10 0.00 1000.00 2000.00 3000.00 Time (sec) 6-49 DP-9 drawdown vs. time E N U cu 0- ca 0 1.00 0.10 9 8 7 6. 5 4 3 2 0.00 100.00 200.00 300.00 400.00 Time (sec) B-50 O P- q IY 12 A ANO c 10 8 6 4 2 C 77 6 11 7 'O 3. G (in j L e= Lw= h - (1 h) C 31, ?w A 2.sd L _ Z d t B 3 2 O 1 5 10 50 100 500 1000 5000 Lc /r Fig. 2. Dimensionless parameters A, B, and C as a function B-55 .IMPERMEABLE c / Environmental Services, Inc. JOB NO. ? SHEET NO. DATE JOB NAME i f /? c? SiL/ w+ f Tj ?I S 7-/?. COMPUTED BY SUBJECT _+?r ?./, 7.'.h t o 7C j, CHECKED BY SrP ?3 o? y 6 ?z, stiff (/l 1 ?2 ? _ /, s \ - Z (ire, 2S? Z C = ZZ Ss Pc yo = a 7 9?. 'y' 3 0. 4 aq f. o l xr -S?l?yse? 2C-- S -C Al t`, i Su u `1 1 Sd 2 L ?? q SD ? 3d .4? y 7 /. 9 ? yo Z . I?a<? C'OK LZ.sg)Z? Yv y? 3G. 4? B-51 C*\cnraltirw\nnm\natwnrk\nrirH _1 -4, DP-4 drawdown vs. time 10.00 a) 1.00 a U _N Q N 0.10 0.00 400.00 800.00 1200.00 s-52 Time (sec) DP-5 drawdown vs. time 1? N U _cu Q. N_ 0 10.00 1.00 E 4 2 2 0.10 3 3 0.00 2000.00 4000.00 6000.00 Time (sec) B-53 DP-6 drawdown vs. time 10.00 E 1.00 U _co Q. N 0.10 0.00 400.00 800.00 1200.00 1600.00 Time (sec) B-54 I 12 A AND C 10 e 6 4 2 C 32,04 L e= 2-K7 Lw= 2.67 (;.,) f-i = 23, ? 2. z? = v. 3 3 (t h? e 3 J2 0 5 to 50 100 500 1000 5000 Lt /r Fig. 2. Dimensionless parameters A, B, and C as a function B-56 IMPERMEABLE ..FIGURE 1 C 14 12 A AND C 10 8 l e= -? L (r n j rw ?? 3 da U • 4S? 13 C Z, 7S t 6 B 3 a 2 O I 5 10 SO IDO 500 1000 5000 ? 0 LC /r Fig. 2. Dimensionless Parameters A, B, and C as a function *-If I - /r, fnc 1_I,+;_ - -f I- I r:) /. I B-57 IMPERMEABLE I FJGURF / f C??