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20190495 Ver 1_Cowford_100095_MY1_2022_20230127
ID#* 20190495 Select Reviewer: Ryan Hamilton Initial Review Completed Date 02/01/2023 Mitigation Project Submittal - 1/27/2023 Version* 1 Is this a Prospectus, Technical Proposal or a New Site?* Type of Mitigation Project:* Stream Wetlands Buffer Nutrient Offset (Select all that apply) Project Contact Information Contact Name:* Lindsay Crocker Project Information ID#:* 20190495 Existing ID# Project Type: • DMS Mitigation Bank Project Name: Cowford Mitigation Site County: Onslow Document Information O Yes O No Email Address:* lindsay.crocker@ncdenr.gov Version:* 1 Existing Version Mitigation Document Type:* Mitigation Monitoring Report File Upload: Cowford_100095_MY1_2022.pdf 19.99MB Please upload only one PDF of the complete file that needs to be submitted... Signature Print Name:* Lindsay Crocker Signature: * Year 1Monitoring Report FINAL COWFORDPROJECT NCDMS Project #100095 (Contract #0007746) USACE Action ID: SAW-2019-00487 DWR Project #2019-0495 Onslow County, North Carolina White OakRiver Basin HUC 03030001 Provided by: Resource Environmental Solutions, LLC for Environmental Banc & Exchange, LLC Provided for: NC Department of Environmental Quality Division of Mitigation Services January 2023 3600 Glenwood Avenue, Suite 100 Raleigh, NC 27612 Corporate Headquarters 6575 W Loop S #300 Bellaire, TX 77401 Main: 713.520.5400 January 25, 2023 Lindsay Crocker NC DEQ Division of Mitigation Services 217 West Jones Street Raleigh, NC 27604 RE:Cowford, Project ID #100095, DMS Contract #0007746 Listed below are comments provided by DMS on January, 2023as well as IRT Baseline Review comments regarding the CowfordSite: Year 1Monitoring Report and RES’ responses. Comments: 1. Please include IRT Baseline review comments and provide responses. The IRT Baseline review comments were included (comments 5-9) with responses. 2. Please include IRT correspondence regarding Cowford conservation easement. IRT correspondence is included in Appendix F. 3. Explain how the planted stems increased in many of the species from MY0 to MY1 in the vegetation plots. In Table 9, MY0 total planted stems were not updated to include random vegetation plot stems. This has been updated to the correct number of total planted stems in MY0, which was 259. 4. Include table of performance for headwater portion of stream (KJ1-A, see attached example). A headwater valley performance table has been added to Appendix D. 5.Please QAQC the 2021 references throughout page 6. Done 6.The IRT had initially raised some questions/concerns regarding the single swale proposed from the CE boundary to the stream through the wetland credit area. Looking at the as-built, it appears that six swales were constructed at least partially overlapping the wetland credit area. Were the five additional swales constructed to similar dimensions as the Swale A typical detail/section? If not, please provide more information on the dimensions of the added swales. DWR is concerned with the potential drainage effect of these new swales and may request additional groundwater gauges to demonstrate that wetland credit areas bisected by the swales meet the performance standard. Was the option of diffuse flow through the buffer evaluated as at any of the drain tile outlets, please explain? Also, please confirm that the drain tile outlets and swales will be monitored for stability annually throughout the monitoring period. The design plans submitted with the mitigation plan show proposed Swale A and 3 proposed Drain Tile Outlets (DTO) (See sheets W1 and D3). During construction excavation 3 additional existing drain tiles were found requiring 3 additional DTOs to be installed. These additional res.us exiting drain tiles were not visible in the stream bank and were therefore not observed until construction. All swales associated with DTOs were constructed per the detail on sheet D3: Bottom Width = 4’ / Bank Slopes = 3:1 / Max Channel Slope = 0.3% RES understands the expressed concerns but determined that additional swales were necessary to ensure that the adjacent farming practices could continue unabated. During design, RES determined maintaining the groundwater level below surrounding agricultural fields required drain tile outlets below the existing ground elevation, therefore swales would need to be used to convey this flow to the stream. Because the swales were required diffuse flow could not be achieved, however, the swales were designed to fall within the NCDEQ Treatment Swale requirements, are live staked, and convey groundwater not runoff so they are not anticipated to supply significant nutrient or sediment loading to the system. RES can confirm drain tile outlets and swales will be monitored for stability annually. These swales were designed with low flow velocities, have been matted, seeded, and live staked to help ensure long-term stability. 7. Lastly, in looking at the cross-sections for the headwater valley restoration on KJ1-A, do you anticipate that the pilot channel that was constructed will function more as a single-thread channel rather than a headwater system? RES did not design a low flow (pilot) channel through the HWV reach and expects the reach to develop into a headwater system. 8. Since a foot of inundation (vs. designed 6-inch depressions) can affect tree establishment and growth, DWR requests that a random veg plot capture representative depression(s) within the wetland credit area throughout monitoring. In MY1, random vegetation plot #3 captures a wetland depressional area. RES will continue to monitor vegetation success in wetland depression areas. 9. DWR appreciates the inclusion of the soil and groundwater data. To confirm, GW1 had a zero hydroperiod in 2021 and this wasn't due to a gauge malfunction or relocation? Moving forward in monitoring, it can be helpful to include data on both the consecutive days/% and the cumulative days/% hydroperiod, as well as note the growing season start/end dates and the minimum hydroperiod performance standard value within the wetland hydrology summary table. GW1 had a zero hydroperiod in 2021, this was not due to gauge malfunction or relocation. The wetland hydrology table has been updated to include consecutive days/%, cumulative days/%, growing season start/end dates, and minimum hydroperiod performance values. 2 Table of Contents 1.0 Project Summary ..................................................................................................................................... 2 1.1 Project Location and Description .............................................................................................. 2 1.2 Project Goals and Objectives..................................................................................................... 2 1.3 Project Success Criteria ............................................................................................................. 3 Stream Restoration Success Criteria ................................................................................................ 4 Headwater Stream Restoration Success Criteria .............................................................................. 4 Wetland Hydrology Success Criteria ............................................................................................... 4 Vegetation Success Criteria ............................................................................................................. 5 1.4 Project Components .................................................................................................................. 5 1.5 Stream and Wetland Design/Approach ..................................................................................... 5 Streams ............................................................................................................................................. 5 Wetlands .......................................................................................................................................... 6 1.6 Construction and As-Built Conditions ...................................................................................... 7 1.7 Year 1 Monitoring Performance (MY1) .................................................................................... 7 Vegetation ........................................................................................................................................ 7 Stream Geomorphology ................................................................................................................... 7 Stream Hydrology ............................................................................................................................ 8 Wetland Hydrology .......................................................................................................................... 8 Headwater Valley............................................................................................................................. 8 Visual Assessment ........................................................................................................................... 8 2.0 Methods................................................................................................................................................... 8 3.0 References ............................................................................................................................................... 9 Appendix A: Background Tables Table 1. Project Mitigation Components Table 2. Project Activity and Reporting History Table 3. Project Contacts Table Table 4. Project Background Information Table Figure 1. Site Location Map Appendix B: Visual Assessment Data Figure 2. Current Conditions Plan View Table 5. Visual Stream Morphology Stability Assessment Table 6. Vegetation Condition Assessment Vegetation Plot Photos Monitoring Device Photos General Site Photos Appendix C: Vegetation Plot Data Table 7. Planted Species Summary Table 8. Vegetation Plot Mitigation Success Summary Table 9. Stem Count Total and Planted by Plot Species Appendix D: Stream Measurement and Geomorphology Data Table 10. Baseline Stream Data Summary Table 11. Cross Section Morphology Data Table Cross Section Overlay Plots Headwater Valley Performance Table Appendix E: Hydrology Data Table 12. 2022 Rainfall Summary Table 13. Documentation of Geomorphically Significant Flow Events Table 14. 2022 Max Hydroperiod Table 15. Summary of Groundwater Monitoring Results Stream Overbank and Flow Hydrographs Groundwater Hydrographs Appendix F: Conservation Easement Clarification Cowford Site 1 Year 1 Monitoring Report Project #100095 January 2023 1.0 Project Summary 1.1 Project Location and Description The Cowford Project (Project) is located within a rural watershed in Onslow County, North Carolina approximately three and half miles northwest of Richlands, North Carolina. The Project lies within the White Oak River Basin, North Carolina United States Geological Survey (USGS) 8-digit Cataloguing Unit 03030001 and 14-digit hydrologic unit code (HUC) 03030001010010, a Targeted Local Watershed (TLW) and the Division of Water Resources (NCDWR) sub-basin 03-05-02 (Figure 1). The Project provides 3,337 linear feet (LF) of stream as well as re-establish 2.991 acres of wetland that will provide water quality benefit for 238 acres of drainage area. The Project area is comprised of a 17.20-acre easement involving one unnamed tributary within an entrenched channel between agricultural fields, totaling 2,988 existing LF, that drains into Cowford Branch, which eventually drains to the New River. The Project is accessible from U.S. route NC-258. Coordinates for the Project areas are approximately 34.9233, -77.5917, at the crossing in the middle of the project. 1.2 Project Goals and Objectives Through the comprehensive analysis of the Project’s maximum functional uplift using the Stream Functions Pyramid Framework and conclusions based on a Site Hydric Soils Detailed Study, the Project will realize specific, attainable goals and objectives. These goals clearly address the degraded water quality and nutrient input from agricultural practices that were identified as major watershed stressors in the 2010 White Oak RBRP. The Project will address outlined RBRP Goal one and two of the TLW specific goals (listed in Section 2). The Project goals are: • Re-establish hydrology to a historical stream/wetland complex that has been impacted by historic channel realignment, channel entrenchment, field ditching, and field drain tiling; • To transport water in a stable, non-erosive manner and maintain a stable water table in riparian floodplain wetlands that will also contribute to stream baseflow; • Improve flood flow attenuation on site and downstream by allowing for overbank flows and connection to the floodplain; •Create diverse bedforms and stable channels that achieve healthy dynamic equilibrium and provide suitable in-stream habitat for aquatic organisms; • Limit sediment and nutrient inputs into stream system; • Re-establish wetland; • Restore native wetland and riparian vegetation; • Indirectly support the goals of the 2010 White Oak RBRP to improve water quality and to reduce sediment and nutrient loads; and • To support the life histories of aquatic and riparian plants and animals through stream restoration activities. Functional uplift, benefits, and improvements within the Project area, as based on the Function Based Framework are outlined in the table below. Cowford Site 2 Year 1 Monitoring Report Project #100095 January 2023 Functional Benefits and ImprovementsTable. Level Function GoalObjective Measurement Method Convert the land-use of streams and their Percent Project drainage to transport water from the Hydrology° watersheds from cropland area converted to watershed to the channel in a Transport of water into riparian forest riparian forest (indirect 1 non-erosive manner and from the watershed to measurement) maintain a stable water table in Maintain appropriate the channel the riparian wetland hydroperiod for Muckalee Groundwater wells soil series Improve flood bank Cross sections connectivity by reducing Hydraulic bank height ratios and Stage Recorders Transport of water in increasing entrenchment to transport water in a stable 2 the channel, on the ratios Bank Height Ratio non-erosive manner floodplain, and through the sediments Maintain regular, seasonal Entrenchment Ratio flow in restored, intermittent streams Flow gauge Limit erosion rates and increase channel stability to reference reach As-built stream profile Geomorphology conditions to create a diverse bedform and a Transport of wood and Cross sections stable channel that achieves 3 Improve bedform diversity sediment to create healthy dynamic equilibrium and diverse bedforms and (pool spacing, percent Visual monitoring provides suitable habitat for life dynamic equilibrium riffles, etc.) Vegetation plots Increase buffer width to at least 50 feet Establish native hardwood riparian buffer to provide Indirectly support the goals of canopy shade and absorb the 2010 White Oak RBRP to nutrients achieve appropriate levels for Physicochemical ° water temperature, dissolved Install in-stream structures Temperature and oxygen concentration, and other to created aeration zones 4 oxygen regulation; important nutrients including but processing of organic not limited to Nitrogen and Promote sediment matter and nutrients Phosphorus through filtration, nutrient cycling, buffer/wetland planting and and organic accumulation wetland hydrologic restoration through natural wetland biogeochemical processes Improve aquatic habitat by Biology ° to achieve functionality in levels installing habitat features, Biodiversity and life 1-4 to support the life histories of constructing pools of 5 histories of aquatic life aquatic and riparian plants and varying depths, and histories and riparian animals through instream planting the riparian life buffer and wetlands ° These are benefits that are presumed and will not be measured by the monitoring 1.3 Project Success Criteria The success criteria for the Project will follow the 2016 USACE Wilmington District Stream and Wetland Compensatory Mitigation Update, the Cowford Site Final Mitigation Plan, and subsequent agency guidance. Specific success criteria components are presented below. Cross section and vegetation plot monitoring takes place in Years 0, 1, 2, 3, 5, and 7. Hydrology and visual monitoring takes place annually. Specific success criteria components are presented below. Cowford Site 3 Year 1 Monitoring Report Project #100095 January 2023 Stream Restoration Success Criteria Four bankfull flow events must be documented within the seven-year monitoring period. The bankfull events must occur in separate years. Otherwise, the stream monitoring will continue until four bankfull events have been documented in separate years. There should be minor change in as-built cross sections. If changes do take place, they should be evaluated to determine if they represent a movement toward a less stable condition (for example downcutting or erosion) or are minor changes that represent an increase in stability (for example settling, vegetative changes, deposition along the banks, or decrease in width/depth ratio). Cross sections shall be classified using the Rosgen stream classification method, and all monitored cross sections should fall within the quantitative parameters defined for channels of the design stream type. Bank height ratio shall not exceed 1.2, and the entrenchment ratio shall be above 2.2 within restored riffle cross sections (for C and E streams). Digital images are used to subjectively evaluate channel aggradation or degradation, bank erosion, success of riparian vegetation, and effectiveness of erosion control measures. Longitudinal images should not indicate the absence of developing bars within the channel or an excessive increase in channel depth. Lateral images should not indicate excessive erosion or continuing degradation of the banks over time. A series of images over time should indicate successional maturation of riparian vegetation. Stream restoration reaches will be monitored to document intermittent or seasonal surface flow. This will be accomplished through direct observation and the use of hydraulic pressure transducers with data loggers. Reaches must demonstrate a minimum of 30 consecutive days of flow. One flow gauge was installed on KJ1-A and one stage recorder was installed on KJ1-C. Headwater Stream Restoration Success Criteria Continuous surface water flow must be documented every year for at least 30 days. Channel formation must be documented through consistent indicators. Monitoring years 1-4 require evidence of scour, sediment deposition, sediment sorting, multiple observed flow events, destruction of terrestrial vegetation, presence of litter and debris, wracking, vegetation matted down or bet, and leaf litter disturbed. Monitoring years 5- 7, the headwater valley reach must meet the previous requirements as well as demonstrate bed and banks, natural line impressed on the bank, shelving, water staining, change in plant community and changes in character of soil. Wetland Hydrology Success Criteria The Natural Resources Conservation Service (NRCS) has a current WETs table (1990-2019) for Onslow County upon which to base a normal rainfall amount and average growing season. The closest comparable data station was determined to be the WETS station for New River MCAF, NC. The growing season for Onslow County is 269 days long, extending from March 10 to December 4, and is based on a daily minimum temperature greater than 28 degrees Fahrenheit occurring in five of ten years. Based upon field observation across the site the NRCS mapping units show a good correlation to actual site conditions in areas of the site. Mitigation guidance for soils in the Coastal Plain suggests a hydroperiod for the Muckalee soil of 12-16 percent of the growing season. The hydrology success criterion for the Site is to restore the water table so that it will remain continuously within 12 inches of the soil surface for 12-16 percent of the growing season (approximately 33 days) at each groundwater gauge location. Due to the extensive drainage efforts, it may take at least a year for the site to become completely saturated and reach the target hydroperiods. Cowford Site 4 Year 1 Monitoring Report Project #100095 January 2023 Vegetation Success Criteria Specific and measurable success criteria for plant density within the riparian buffers on the Project will follow IRT Guidance. The interim measures of vegetative success for the Project will be the survival of at least 320 planted three-year old trees per acre at the end of Year 3, 260 five-year old trees at seven feet in height at the end of Year 5, and the final vegetative success criteria will be 210 trees per acre with an average height of ten feet at the end of Year 7. Volunteer trees that are listed on the approved planting list will be counted, identified to species, and included in the yearly monitoring reports, and if established for two or more years, may be counted towards the success criteria of total planted stems. Moreover, any single species can only account for up to 50 percent of the required number of stems within any vegetation plot. Any stems more than 50 percent will be shown in the monitoring table but will not be used to demonstrate success. 1.4 Project Components The streams and wetlands provided for restoration have been significantly impacted by ditching, drain tiling, and other agricultural practices for over 50 years. Provided improvements to the Project will help address impacts specifically discussed as priorities in in the 2010 White Oak River Basin Restoration Priorities (RBRP). Through stream restoration, headwater valley (HWV) restoration, and wetland restoration, the Project presents 3,347 LF of provided stream, generating 3,538.67 Warm Stream Mitigation Units (SMU) and 2.991 acres of provided wetland, generating 2.991 Wetland Mitigation Units (WMU). Cowford Project Components Summary (Mitigation Plan) Stream Mitigation Mitigation Approach Linear Feet Ratio Warm SMU 913.000* Restoration (HWV) 923 1:1 2,424.000 Restoration 2,424 1:1 Total 3,347 3,337 Non-standard Buffer Width Adjustment201.670 Total Adjusted SMU’s 3,538.67 Wetland Mitigation Mitigation ApproachArea (acres)RatioWMU Re-establishment 2.991 1:1 2.991 Total 2.991 2.991 *Headwater valley credits are calculated from valley length, not included in NSBW calculations. ** Credit adjustment for Non-standard Buffer Width calculation using the Wilmington District Stream Buffer Credit Calculator issued by the USACE in January 2021. See Section 6.6 for further information 1.5 Stream and Wetland Design/Approach Streams The Project includes stream and headwater valley restoration. Stream restoration will incorporate the design of a single-thread, meandering channel, with parameters based on data taken from reference site, published empirical relationships, regional curves developed from existing project streams, and NC Regional Curves. Analytical design techniques will also be a crucial element of the project and will be used to determine the design discharge and to verify the design. Based on soil type, valley slope, and drainage area headwater Cowford Site 5 Year 1 Monitoring Report Project #100095 January 2023 valley restoration was incorporated in the design. Headwater valley restoration includes the design of a vegetated diffuse flow system that will allow for the passive development of a headwater stream. The Project has been broken into the following design reaches: Reach KJ1-A (HWV) A headwater valley restoration approach is provided for this reach to address historic ditching and buffer impacts. Restoration activities includes: Grading a headwater valley, Installing wood structures to provide grade control and habitat, Installing live stakes to stabilize the bed and banks, Riparian planting. Reach KJ1-B An offline restoration approach is provided for this reach to address historic ditching and buffer impacts. Restoration activities includes: Grading a new, single-thread channel in the existing floodplain (Priority I Restoration), Installing log structures to provide grade control and habitat, Establishing a riffle-pool sequence throughout the new channel, Installing toe protection on meander bends, Installing live stakes to stabilize the banks and provide channel shading, Filling and grading the existing channel to create wetland habitat, Riparian planting. Reach KJ1-C An inline, P2 restoration approach is provided for this reach to address historic ditching, channelization, and buffer impacts. Restoration activities includes: Grading a new, single-thread channel in an excavated floodplain, Installing rock and log structures to provide grade control and habitat, Establishing a riffle-pool sequence throughout the new channel, Installing toe protection on meander bends, Installing live stakes to stabilize the banks and provide channel shading, Filling the existing channel, Riparian planting, and Invasive vegetation treatment. Wetlands The Cowford Project offers a total ecosystem restoration opportunity. As such, the wetland restoration is closely tied to the stream restoration and drain tile interruption. The Project provides 2.991 WMUs through wetland re-establishment. Wetland re-establishment is only provided in areas that have been determined appropriate for wetland restoration by a licensed soil scientist due to the presence of hydric soils and potential hydrology. Re-establishment activities includes a successful restoration that raises the local groundwater elevation, allows frequent flooding, the plugging of ditches, removing all drain tiles within the easement, and creating shallow depression features in the wetland. A 2D model of the provided stream restoration was run in HEC-RAS to evaluate the effectiveness of the design at increasing wetland flooding. Inundation maps from this model of the 1- and 10-year design storms demonstrate that the provided design will function in this capacity. These activities help to raise the local Cowford Site 6 Year 1 Monitoring Report Project #100095 January 2023 groundwater and have a more natural hydrologic cycle in the riparian zone. Surface roughening through shallow soil ripping improves infiltration and slow runoff through the floodplain. Surface roughening also create microtopography and shallow depressional areas, re-establishing more natural conditions and establishing habitat diversity. Historic land-use impacts will be addressed through the planting of a native hardwood wetland community. 1.6 Construction and As-Built Conditions Site construction was completed on July 30th, 2021, and planting was completed on March 8th, 2022. The Cowford Site was overall built to design plans and guidelines, as-built stream and wetland areas were only slightly different than proposed. Wetland Depressions were designed to be 0.3-0.5 feet deep but As-Built Wetland Depressions were found to be slightly deeper than proposed ranging from 0.5-1.0 feet deep. During construction additional drain tiles were found, which were then interrupted at the easement boundary. Additionally, extra t-posts were installed around the boundary of the easement in 100-foot intervals to reduce concerns of encroachment by farming practices. Minor monitoring device location changes were made during as-built installation, however, the quantities remained as proposed in the Mitigation Plan. 1.7 Year 1 Monitoring Performance (MY1) The Cowford Year 1 monitoring activities were performed in November 2022. All Year 1 Monitoring data is present below and in the appendices. The Site is on track to meeting vegetation, wetland, and stream interim success criteria. Vegetation Monitoring of the nine permanent vegetation plots and five random vegetation plots were completed on rd November 3, 2022. Vegetation data are in Appendix C, associated photos are in Appendix B, and plot locations are in Appendix B. MY1 monitoring data indicates that all plots are exceeding the interim success criteria of 320 planted stems per acre. Planted stem densities ranged from 324 to 931 planted stems per acre with a mean of 659 planted stems per acre across all plots. A total of 10 species were documented within the plots. Volunteer species were noted in one out of nine plots during Year 1 monitoring and are expected to increase in upcoming years. The average stem height in the vegetation plots was 2.0 feet. In April 2022, an additional 45 three-gallon trees (Tag alder, Tulip poplar, Sycamore, and Elm) were planted along the northern easement edge above KJ1-C. Visual assessment of vegetation outside of the monitoring plots indicates that the herbaceous vegetation is becoming well established throughout the project. Chinese privet was treated in an area near VP 9 before As-built in November, 2021. No additional invasives were present during MY1 site visits. Stream Geomorphology st Cross section geomorphology data collection for MY1 was collected on November 1, 2022. Summary tables and cross section plots are in Appendix D. Overall the baseline cross sections and profile relatively match the proposed design. The MY1 conditions show that shear stress and velocities have been reduced for all restoration/enhancement reaches. Visual assessment of the stream channel was performed to document signs of instability, such as eroding banks, structural instability, or excessive sedimentation. The channel is transporting sediment as designed and will continue to be monitored for aggradation and degradation. Cowford Site 7 Year 1 Monitoring Report Project #100095 January 2023 Stream Hydrology th One stage recorder on KJ1-C, was installed on January 19, 2022. One flow gauge, on KJ1-A, was installed th on January 19 , 2022. The stage recorder is in place to document bankfull events, while the flow gauge is in place to track frequency and duration of stream flow events. The stage recorder on KJ1-C measured two bankfull events with the highest being 0.38 feet above the top of bank. The flow gauge on KJ1-A measured 11 flow events with the longest flow event lasting 55 days. Gauge locations can be found on Figure 2 and photos are in Appendix B. Wetland Hydrology A total of five groundwater wells with automatic recording pressure transducers were installed throughout ndth the wetland areas on November 2 , 2021, and April 28, 2022. All five groundwater wells failed to meet success of 12-16 percent of the growing season (GW1 0%, GW2 1%, GW3 7%, GW4 4%, and GW5 5%) Appendix E. It is important to note that GW5 is located outside of the wetland crediting area. Although all five groundwater wells did not meet success, it was noted that due to extensive draining efforts that it may take at least a year for the site to become completely saturated and reach the target hydroperiods. Onslow county has experienced drought conditions for more than 70% of 2022 and rainfall amounts in February and June were below normal limits which could have attributed to lower hydroperiods. Therefore, RES expects the hydroperiods to increase in subsequent years as the wetlands continue to establish. Headwater Valley th Setup of cross sections 1, 2, and 3 in the headwater valley took place on January 19, 2022. Overall, the baseline cross sections and profile relatively match the proposed design. The flow gauge located in the headwater valley measured 55 consecutive flow days. The livestakes are becoming established within the channel and will provide opportunities for flow paths to develop in subsequent years. Additional headwater valley channel performance criteria are listed in Appendix D. Digital images can be found in Appendix B. Visual assessments and updated images will be documented in years to follow as indicators are established. Visual Assessment Digital images will be used to subjectively evaluate channel aggradation or degradation, bank erosion, success of riparian vegetation, and effectiveness of erosion control measures. Digital images will also capture the headwater valley, boundaries, and culverts of the site, located in Appendix B. 2.0 Methods Stream monitoring was conducted using a Topcon GTS-312 Total Station. Three-dimensional coordinates associated with cross-section data were collected in the field (NAD83 State Plane feet FIPS 3200). Morphological data were collected at 15 cross-sections. Survey data were imported into CAD, ArcGIS®, and Microsoft Excel® for data processing and analysis. The stage recorders include an automatic pressure transducer placed in PVC casing in a pool. The elevation of the bed and top of bank at each stage recorder are used to detect bankfull events. Vegetation success is being monitored at nine permanent vegetation plots and five random vegetation plots. Vegetation plot monitoring follows the CVS-EEP Level 2 Protocol for Recording Vegetation, version 4.2 (Lee et al. 2008) and includes analysis of species composition and density of planted species. Data are processed using the CVS data entry tool. In the field, the four corners of each plot were permanently marked with PVC at the origin and metal conduit at the other corners. Photos of each plot are to be taken from the Cowford Site 8 Year 1 Monitoring Report Project #100095 January 2023 origin each monitoring year. The random plots are to be collected in locations where there are no permanent vegetation plots. Random plots are collected in the form of 100 square meter belt transects with variable dimensions. Tree species and height will be recorded for each planted stem and the transects will be mapped and new locations will be monitored in subsequent years. Wetland hydrology is monitored to document success in wetland restoration areas where hydrology was affected. This is accomplished with three automatic pressure transducer gauges (located in groundwater wells) that record daily groundwater levels. Three have been installed within the wetland restoration crediting area and one within the adjacent upland area to document the wetland boundary. One automatic pressure transducer is installed above ground for use as a barometric reference. Gauges are downloaded quarterly and wetland hydroperiods are calculated during the growing season. Gauge installation followed current regulatory guidance. Visual observations of primary and secondary wetland hydrology indicators are also recorded during quarterly site visits. 3.0 References Griffith, G.E., J.M.Omernik, J.A. Comstock, M.P. Schafale, W.H.McNab, D.R.Lenat, T.F.MacPherson, J.B. Glover, and V.B. Shelburne. (2002). Ecoregions of North Carolina and South Carolina, (color Poster with map, descriptive text, summary tables, and photographs): Reston, Virginia, U.S. Geological Survey (map scale 1:1,500,000). Lee Michael T., Peet Robert K., Roberts Steven D., and Wentworth Thomas R., 2008. CVS-EEP Protocol for Recording Vegetation Level. Version 4.2 Peet, R.K., Wentworth, T.S., and White, P.S. (1998), A flexible, multipurpose method for recording vegetation composition and structure. Castanea 63:262-274 Resource Environmental Solutions (2021). Cowford Site Final Mitigation Plan. Schafale, M.P. 2012. Classification of the Natural Communities of North Carolina, Third Approximation. North Carolina Natural Heritage Program, Division of Parks, and Recreation, NCDENR, Raleigh, NC. USACE. (2016). Wilmington District Stream and Wetland Compensatory Mitigation Update. NC: Interagency Review Team (IRT). Cowford Site 9 Year 1 Monitoring Report Project #100095 January 2023 Table 2. Project Activity and Reporting History Cowford Mitigation Site Elapsed Time Since grading complete:16 months Elapsed Time Since planting complete:8 months 1 Number of reporting Years: 1 Data Collection Completion or Activity or DeliverableCompleteDelivery Restoration PlanNA26-Mar-21 Final Design – Construction PlansNA03-May-21 Stream ConstructionNA30-Jul-21 Site PlantingNA08-Mar-22 Invasive TreatmentNA21-Nov-22 As-built (Year 0 Monitoring – baseline)Jan/March 2022Apr-22 Supplemental Planting NAApr-22 Year 1 MonitoringNov-22Dec-22 Year 2 Monitoring Year 3 Monitoring Year 4 Monitoring Year 5 Monitoring Year 6 Monitoring Year 7 Monitoring 1 = The number of reports or data points produced excluding the baseline Table 3. Project Contacts Table Cowford Mitigation Site RES / 3600 Glenwood Ave., Suite 100, Raleigh, NC 27612 Designer Primary project design POCBenton Carroll, PE RES / 3600 Glenwood Ave., Suite 100, Raleigh, NC 27612 Construction Contractor Construction POCAndrew Dimmette RES / 3600 Glenwood Ave., Suite 100, Raleigh, NC 27612 Survey Contractor Survey POCBrian Hockett Shenandoah Habitats Planting Contractor Planting contractor POCDavid Coleman RES / 3600 Glenwood Ave, Suite 100, Raleigh, NC 27612 Monitoring Performers Monitoring POCHannah Gadai Table 4. Project Background Information Project NameCowford Project CountyOnslow Project Area (acres) 17.20 Project Coordinates (latitude and longitude)34.92293, -77.5917 Planted Acreage (Acres of Woody Stems Planted)16.35 Project Watershed Summary Information Level IV Ecoregion63h - Carolina Flatwoods River Basin White Oak USGS Hydrologic Unit 14-digit 30203020102 USGS Hydrologic Unit 8-digit3020302 DWR Sub-basin03-05-02 Project Drainage Area (Acres and Square Miles)238 ac (.37 sqmi) Project Drainage Area Percentage of Impervious Area <1% Reach Summary Information Reach KJ1-AReach KJ1-B Parameters Reach KJ1-C Length of reach (linear feet) 935852 1574 Moderately Valley confinement (Confined, moderately confined, unconfined) UnconfinedUnconfined confined Drainage area (Acres and Square Miles) 115181 238 Perennial, Intermittent, Ephemeral IntermittentIntermittent Intermittent NCDWR Water Quality Classification NoneNone None Stream Classification (existing) G5G5 G5 to E5 Stream Classification (proposed) N/AE5 / C5 E4 / C4 Evolutionary trend (Simon) IIIIII III-IV Zone X (Minimal Zone X FEMA classificationZone X (Minimal Risk) Risk) (Minimal Risk) Wetland Summary Information Parameters WA Size of Wetland (acres) 2.969 Wetland Type RR Mapped Soil Series Muckalee loam Drainage Class Poorly Soil Hydric Status Yes (LESS) Source of Hydrology GW, OL, SF Restoration or enhancement method H, V Cowford Legend Easement TLW - 03030001010010 White Oak River Basin - 03030001 Date: 2/17/2022 Figure 1 - Site Location Map Drawn by: HRG © Cowford Mitigation Site Checked by: JRM 05001,000 Onslow County, North Carolina 1 inch = 1,000 feet Feet seicepS evisavnI dxm.drofwoC - 2202 1YM VPCC - 2 erugiF\\2202 1YM\\gnirotinoM_6\\DXM\\drofwoC_009001\\stcejorP\\sigtne\\sigseR\\:R :htaP tnemucoD 100%100%100%100%100%100% Intended % Stable, Performing as 0000 Footage Unstable Amount of 83 in As-built Total Number 83 Stable, Number Intended Performing as not Totals include undercuts that are modest, appear sustainable and are 9251850providing habitat. Metric Bank lacking vegetative cover resulting simply from poor growth and/or surface scour Bank toe eroding to the extent that bank failure appears likely. Does NOTFluvial and geotechnical - rotational, slumping, calving, or collapseGrade control structures exhibiting maintenance of grade across the sill. Bank erosion within the structures extent of influence does exceed 15%. (See guidance for this table in DMS monitoring guidance document) JK1-A Surface Scour/Bare BankToe ErosionBank FailureGrade ControlBank Protection Major Channel Category Visual Stream Stability Assessment Assessed Bank Length ReachAssessed Stream Length Bank Structure 100%100%100%100%100%100% Intended % Stable, Performing as 0000 Footage Unstable Amount of 7 16 in As-built Total Number 7 16 Stable, Number Intended Performing as not Totals include undercuts that are modest, appear sustainable and are 8501700providing habitat. Metric Bank lacking vegetative cover resulting simply from poor growth and/or surface scour Bank toe eroding to the extent that bank failure appears likely. Does NOTFluvial and geotechnical - rotational, slumping, calving, or collapseGrade control structures exhibiting maintenance of grade across the sill. Bank erosion within the structures extent of influence does exceed 15%. (See guidance for this table in DMS monitoring guidance document) JK1-B Surface Scour/Bare BankToe ErosionBank FailureGrade ControlBank Protection Major Channel Category Visual Stream Stability Assessment Assessed Bank Length ReachAssessed Stream Length Bank Structure 100%100%100%100%100%100% Intended % Stable, Performing as 0000 Footage Unstable Amount of 1728 in As-built Total Number 1728 Stable, Number Intended Performing as not Totals include undercuts that are modest, appear sustainable and are 15723144providing habitat. Metric Bank lacking vegetative cover resulting simply from poor growth and/or surface scour Bank toe eroding to the extent that bank failure appears likely. Does NOTFluvial and geotechnical - rotational, slumping, calving, or collapseGrade control structures exhibiting maintenance of grade across the sill. Bank erosion within the structures extent of influence does exceed 15%. (See guidance for this table in DMS monitoring guidance document) JK1-C Surface Scour/Bare BankToe ErosionBank FailureGrade ControlBank Protection Major Channel Category Visual Stream Stability Assessment Assessed Bank Length ReachAssessed Stream Length Bank Structure )) /2022/2022 33 // 1111 ( 6 ( Vegetation Plot Vegetation Plot 8 )) /2022/2022 33 / / 1111 5 ( Vegetation Plot Vegetation Plot 7 ( ) /2022 3 / 11 9 ( Vegetation Plot ) ) /2022/2022 33 // 11 11 2 (4 ( Vegetation Plot Vegetation Plot Random Random )) /2022/2022 33 // 11 11 ( 3 ( Vegetation Plot 1Vegetation Plot Random Random MY0 Random Vegetation Monitoring Plot Photo Cowford ) /2022 3 / 11 ( 5 Vegetation Plot Random ) /2022 /2022) 3 / 3 / 11 ( 11 A - Wetland Gauge 2 ( Flow Gauge KJ1 ) ) 2022 /2022 1 3 / /2022 3 11/ ( MY 11 s C - KJ1 Photo Wetland Gauge 1 ( Stage Recorder Monitoring Device Cowford ) /2022 3 / 11 Wetland Gauge 4 ( )) /2022/2022 33 / / 1111 ( Wetland Gauge 3 (Wetland Gauge 5 ) ) /2022 /2022 3 3 / / 11 11 ( ( C - of KJ1 top Kinston Highway Culvert at the Culvert at Photo Point 2: Photo Point 4: ) ) /2022 3 /2022 / 3 / 11 ( 11 ( B - Wetland of KJ1 2022 1 bottom at edge of MY tment pool Culvert at the Trea General Site Photos Photo Point 1: Photo Point 3: Cowford ) 3/16/2022 /2022) ( 3 / B - 11 ( Easement marker Haybale brush toe in BJ1 ) /2022 3 / /2022) 3 / 11 11 Headwater Valley ( ESP & Treatment Pool ( Appendix C. Vegetation Plot Data Table 7. Planted Species Summary Bare Root Planting Tree Species Common NameScientific NameMit Plan %As-Built %Total Stems Planted River Birch Betula nigra 15152,000 Buttonbush Cephalanthus occidentalis 15152,000 Bald Cypress Taxodium distichum 10101,300 Water Oak Quercus nigra 10101,300 Willow Oak Quercus phellos 10101,300 Overcup Oak Quercus lyrata 10101,300 Swamp Tupelo Nyssa biflora 10101,300 American sycamore Platanus occidentalis 10101,300 Southern red oak Quercus falcata 55700 Green ash Fraxinus pennsylvanica 55700 Total 13,200 Planted Area 16.35 807 As-built Planted Stems/Acre Table 8. Vegetation Plot Mitigation Success Summary Average Success Planted Volunteer Total Planted Plot #Criteria Stems/AcreStems/AcreStems/AcreStem Met? Height (ft) 1 9310931Yes2.6 2 9310931Yes2.2 3 6880688Yes2.4 4 5670567Yes2.2 5 8500850Yes1.3 6 6470647Yes1.7 7 5260526Yes1.7 8 8090809Yes1.7 9 60740647Yes2.3 R1 72800Yes2.3 R2 68800Yes2 R3 48600Yes2.2 R4 44500Yes2 R5 32400Yes2.3 Project Avg6594662Yes 2.0 Headwater Valley Performance Table KJ1-A Channel EvidenceYear 1Year 2Year 3Year 4Year 5 Year 6Year 7 Max consecutive days of channel flow55 Presence of litter and debris (wracking)No Leaf litter disturbed or washed awayNo Matted, bent, or absence of vegetation (herbaceous or otherwise)No Sediment depostion and/or scour indicating sediment transportNo Water staining due to continual presence of water*No Formation of channel bed and banks*No Sediment sorting within the primary path of flowNo Sediment shelving or a natural line impressed on the banks*No Change in plant community (absence or destruction of terrestrial vegetation and/or transition to species adapted for flow or inundation for a long duration, including hydrophytes)*No Development of channel pattern (meander bends and/or channel braiding) at natural topographic breaks, woody debris piles, or plant root systems*No Exposure of woody plant roots within the primary path of flow*No Other:NA *represents indicators that are required in monitoring years 5-7 Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Elevation (ft) Table 12. Rainfall Summary MY1 2022 Normal Limits MonthAverageRichland Station Precipitation* 30 Percent70 Percent January3.702.784.574.55 February3.502.324.200.93 March3.762.684.432.85 April3.001.693.774.91 May 4.112.514.853.70 June5.313.516.383.50 July 6.054.407.464.75 August7.233.668.954.40 September7.023.918.395.02 October4.112.244.974.27 November3.681.964.41- December3.662.634.27- Total Annual**34.2966.6538.88 Above Normal Below Normal LimitsLimits *Rainfall data was acquired from Richland Station which is approximately 4 miles from the Site. **Normal Limits were determined from WETS Station New River MCAF, NC. Approximately 20 miles from the Site Table 13. Documentation of Geomorphically Significant Flow Events Number of Bankfull Height Above YearDate of Maximum Bankfull Event EventsBankfull (ft) Stage Recorder KJ1-C MY120.384/5/2022 Maximum Consecutive Maximum Cummlative Maximum Consecutive Date YearNumber of Flow Events Flow DaysFlow DaysRange Flow Gauge KJ1-A MY111551603/9/2022-5/3/2022 Table 14. 2022 Max Hydroperiod 2022 Max Hydroperiod (Growing Season 10-Mar through 2-Dec, 267 days) ConsecutiveCumulative Well IDOccurrences DaysHydroperiod (%)DaysHydroperiod (%) GW1 102.014 GW2 21624 GW3 19734.51310 GW4 1242396 GW5 13520.584 <5%5-12%>12% Table 15. Summary of Groundwater Monitoring Results Summary of Groundwater Monitoring Results Cowford Hydroperiod (%) Wetland Well ID Pre Con Pre Con Year 1 Year 2 Year 3 Year 4 Year 5 Year 6 Year 7 ID (2020)(2021)(2022)(2023) (2024)(2025)(2026)(2027)(2028) GW1WA1.00.0 0.0 GW2WA 1.0 GW3WA 7.0 GW4WA 4.0 GW5WA 5.0 Rainfall (in) Stage (ft) Rainfall (in) Water Depth (in) Precipitation (inches) Groundwater Elevation (inches) Precipitation (inches) Groundwater Elevation (inches) Precipitation (inches) Groundwater Elevation (inches) Precipitation (inches) Groundwater Elevation (inches) Precipitation (inches) Groundwater Elevation (inches) From:Isenhour, Kimberly T CIV USARMY CESAW (USA) To:Allen, Melonie Cc:erin.davis@ncdenr.gov; travis.wilson@ncwildlife.org; Tugwell, Todd J CIV USARMY CESAW (USA); bowers.todd@epa.gov; Merritt, Katie Subject:RE: Clarification request on IRT protection mechanism clarification vs. amendment Date:Thursday, June 23, 2022 3:42:56 PM Melonie Erin and I discussed these projects yesterday. The CE protection mechanism is one of the most critical elements of a mitigation project, and any modifications to the easement should be proposed to the Corps for IRT review. Below are comments on the two projects. If you would prefer to decouple this from the As-built review and address these changes separately, that's fine too. Cowford: We both had concerns about existing ditches and buffers around the wetlands due to the adjacent landowner's need to decrease hydrology in his fields. For this specific project, we are ok with the CCPV callout as long as the narrative discussion provides context/clarity. I agree that this can be treated as an easement clarification that you can handle with a Transfer Illustration and CCPV note; however, situations like this should be discussed during the post- contract stage moving forward. We agree that there is a big difference between leaving a ditch open as part of project construction and allowing landowner ditch maintenance within an easement. I don't recall that this was a discussion topic during the post- contract visit or the draft mitigation plan review. If the existing ditch is centerlined in the CE and labeled "to remain open," we would assume that the ditch has potential future maintenance; however, if the ditch is located fully in the CE, we would assume there would be no maintenance by the landowner. CE signage will be important in this area. Additionally, DWR requests that "no mow" signs be added to clearly indicate the extent of the allowable ditch maintenance area. For future reference, if a new ditch is proposed outside of the CE and during construction ends up partially within the CE and is expected to be maintained, then this should be a formal IRT discussion before DMS/SPO action is taken. Similarly, if an existing road/path to be maintained is located within the CE but was not identified in the mit plan, or a new road/path is constructed partially within the CE contrary to the approved mit plan, I would not assume IRT concurrence with a CE clarification and would recommend formal IRT discussion before DMS/SPO action is taken. UT to Rush Fork: Any new or shifted structures or roads installed within the easement, particularly if they require future maintenance, should be identified for IRT review prior to actions taken by DMS/SPO. In this case, I would suggest that DMS submit the proposal to modify the easement (or remove the structures from the easement) prior to making any changes. Paul can submit this request with the As-Built review request so that the review timeline is only 30-days, and not 15-days for the As-Built plus an additional 30-days for the easement mod. I've copied Katie Merritt because I believe Cowford is one of her projects, and other IRT members for their awareness during the As-Built reviews. Please let me know if you still have questions. Thanks Kim Kim (Browning) Isenhour Mitigation Project Manager, Regulatory Division I U.S. Army Corps of Engineers l 919.946.5107 From: Allen, Melonie Sent: Friday, June 17, 2022 10:49 AM To: Kim Browning <Kimberly.D.Browning@usace.army.mil>; Haywood, Casey M CIV USARMY CESAW (USA) <Casey.M.Haywood@usace.army.mil>; Davis, Erin B <erin.davis@ncdenr.gov>; Wilson, Travis W. <travis.wilson@ncwildlife.org>; Tugwell, Todd J CIV USARMY CESAW (US) <Todd.J.Tugwell@usace.army.mil> Subject: Clarification request on IRT protection mechanism clarification vs. amendment IRT, Yesterday I responded to two very different easement scenarios that I'd like to get clarification on if possible. I. Cowford Project: 100095 Onslow County White Oak MY1 i. The recorded plat indicated the existing ditch located partially or fully in the easement on the far east side of the CE (see screen shot below with ditch annotation in red box). It was the intention to leave the ditch and enable the landowner(s) to maintain the ditch when the easement was acquired. Filling the ditch was never proposed in the RFP technical proposal or Mitigation Plan. Ideally when the easement was acquired a line following the 'centerline of ditch' should have been added to indicate; ditch to remain and may be maintained. It is the property boundary. * I interpret this as an easement clarification: I propose that DMS be able to handle interpretations such as this with a Transfer illustration and note it in the CCPV. The transfer illustration would protect the landowner from SP interpretation of violation upon maintenance. The call out in the CCPV would alert the IRT that the ditch is to remain. II. Ut to Rush Fork: 100068 Haywood Co. French Broad, MY0 review i. The recorded plat indicates a road upstream of UT 4 and the installed crossing culvert and headwall extend the easement. There is also an installed BMP that extends beyond the easement. These are clearly mistakes and I interpret this to require moving the infrastructure or amending the easement to ensure the infrastructure is excluded and BMP is included (much more likely scenario). In this case, I propose that DMS notify the IRT of intent to modify easement and get concurrence prior to making any changes. Let me know if you need any additional information or have any questions, Thanks, Melonie Melonie Allen Closeout & Credit Release Division of Mitigation Services N.C. Department of Environmental Quality 919-707-8540 office 919-368-9352 cell > Melonie.Allen@ncdenr.gov <mailto:Melonie.Allen@ncdenr.gov 217 West Jones St. Raleigh, NC 27603