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Home My WebLink AboutCPE Letter to Coats re DMF Comments Brad Rosov Project Manager/Senior Marine Biologist Coastal Protection Engineering of North Carolina, Inc. 4038 Masonboro Loop Road Wilmington, North Carolina Tel: +1 910-399-1905 brosov@coastalprotectioneng.com August 17, 2021 Heather Coats Division of Coastal Management North Carolina Department of Environmental Quality 127 Cardinal Drive Ext. Wilmington, NC 28405-3845 Subject: Dear Ms. Coats, On August 5, 2021, I received your email containing comments from the NC Division of Marine Fisheries (DMF) regarding the Town of Kitty Hawk's CAMA Major Permit application for their proposed beach nourishment project which is planned to go to construction during 2022. The comments were drafted by James Harrison, DMF Fisheries Resource Specialist on July 16, 2021. In your email you stated that the comments not only apply to the Town of Kitty Hawk's application, but also the Towns of Duck and Southern Shores. DMF's comments include a recommendation for the implementation of six monitoring protocols to be used to determine the effects of the proposed dredge and fill beach activity on important nearshore fish and benthic species and habitats. I have formulated responses to this recommendation and have addressed each of the six monitoring protocols individually below. These responses are intended to provide you with some clarifications, additional context, and information. Requested Monitoring Protocol #1: Pre- and post-placement surveys of benthic species (biodiversity and abundance) in order to determine the impact of dredging and placement on benthic species. Over the past several decades, researchers have studied the impacts of beach nourishment projects on benthic communities at dredge sites (aka borrow areas) and at fill placement sites through extensive monitoring efforts. In doing so, these studies, which have taken place throughout the United States including North Carolina, have generated a wealth of monitoring data resulting in a very good understanding of the magnitude of impacts and anticipated recovery rates to benthic invertebrates following beach nourishment events. As such, the applicants feel that additional monitoring efforts are unwarranted. The information presented below is a summary of relevant findings derived from a number of pre- and post-construction benthic monitoring efforts associated with beach nourishment projects from throughout the United States. First, it is widely recognized that dredge and fill operations associated with beach nourishment projects cause the mortality of infaunal organisms found within the wet beach and benthic environments (Saloman, 1974; Oliver et al., 1977; NRC, 1995; USACE, 2001). Dredging activity involves the removal of sediment, including the benthic infauna residing within the substrate. The placement of fill material upon the beach and the intertidal area has the potential to smother and kill the existing infauna community within the swash zone and nearshore benthic habitats. The resultant temporary loss of these lower trophic level organisms has cascading effects on a wide range of species that prey upon them. These include commercially and recreationally important fish as well as threatened and endangered species such as the piping plover and red knot. As such, state and federal regulatory agencies had often required multi-year pre- and post-construction infaunal monitoring program as a condition of a project’s permit in order to document the effect these actions have on these important biological resources. The results of these studies, dating back several decades, suggest a range of recovery rates that are determined largely by the seasonality of construction and the kinds of construction practices used. A recent study by Wooldridge et al. (2016) offered a useful summary of key peer-reviewed literature on the subject. As cited in Wooldridge et al., recovery rates for benthic invertebrates at beach placement sites were documented to be within one year or less for amphipods (Jones et al. 2008; Leewis et al. 2012; Schlacher et al. 2012), mole crabs (Emerita spp.) (Hayden and Dolan 1974; Leewis et al. 2012; Peterson et al. 2014), bean clams (Donax spp.) (Leewis et al. 2012) and polychaetes, most notably the spionid polychaetes Scolelepis squamata (Leewis et al. 2012; Manning et al. 2014). Other studies cited in the Wooldridge paper reported complete recovery within one year for these and other infaunal taxa such as isopods and other bivalves (Burlas et al. 2001; Peterson et al., 2006, Jones et al. 2008; CZR Incorporated and CSE, Inc., 2013; CZR Incorporated and CSE, Inc., 2014). In a robust assessment of past studies within the primary and grey literature, Wilber et al. (2009) reviewed a large body of monitoring studies, also analyzed previously by Peterson and Bishop (2005). In those studies focusing on the intertidal macrofauna at fill sites, the reported macroinvertebrate recovery rates ranged from less than one month (Gorzelany and Nelson 1983), less than one year (Parr et al. 1978; Jutte et al 2002a and b), and to up to 2 years (Rakocinski et al. 1996). Factors contributing to the recovery rates, as cited in these studies, included the seasonality of construction and the similarity of sediments used as fill material to the native beach sediments. Projects incorporating well-matched sediments (with respect to grain size, sorting, carbonate content, and percent fines) and construction periods that avoided the spring recruitment pulse were associated with faster recovery rates. By contrast, springtime construction and a poor sediment match (too coarse, shelly, or fine) led to longer recovery times. Burlas et al. (2001) reached similar conclusions after a comprehensive study of impacts to intertidal and nearshore benthos following a large beach nourishment project in New Jersey. Following initial declines in biomass, abundance and taxa richness, the authors reported compete recovery of the intertidal assemblages occurred between 2 to 6.5 months following the placement of beach fill. The authors also concluded recovery was quickest when filling was completed by October, before the seasonal decline of infaunal abundance occurred. When filling continued into the winter when the seasonal decline was underway, the recovery times were longer; the authors postulated that timing of filling prevented recolonization before the seasonal decline. It should also be noted that biological populations are inherently variable and exhibit large natural abundance and diversity fluctuations at a site under same- season comparisons. This natural variability poses a challenge to distinguish between natural and nourishment-induced impacts without a high-frequency and high-density sampling program, which is time consuming and expensive for quantitative analysis (Burlas et al., 2001). The Nags Head beach nourishment project, completed in 2011, included benthic monitoring within the fill placement area as well as the offshore borrow area. Project construction spanned the months of May through October, during the peak period of benthic productivity. The 2013 Year 1 post-construction report concluded that benthic populations in the nourished beach as well as the offshore borrow area were not significantly different from control stations and demonstrated viable populations of organisms as of the one-year sample event (CZR Incorporated and CSE, Inc., 2013). The Year 2 post-construction monitoring report confirmed the results of the Year 1 report (CZR Incorporated and CSE, Inc., 2014). Both reports concluded benthic populations along the beach as well as the offshore borrow area were generally no different from control stations and demonstrated viable populations of organisms during the post-construction sampling events (CZR Incorporated and CSE, Inc., 2014). Further, organisms living in these "high energy" beaches may be better adapted to large-scale changes in the profile associated with storms (e.g., CZR Incorporated and CSE, Inc., 2014). In contrast to the above discussions, a number of recent studies have also reported substantially longer recovery periods, or that no recovery of the infauna was observed through the duration of the monitoring study (Colosio et al. 2007; Manning et al. 2014; Peterson et al. 2014; Wooldridge et al. 2016). However, consideration of the construction practices implemented in the associated beach nourishment projects may help explain the varied results, as well as provide valuable insight for best management practices of beach nourishment projects. In a study conducted in Italy where three beaches were nourished at the same time with varying levels of sediment compatibility, it was observed that the two beaches receiving poorly matching sediments remained nearly free of macrofaunal organisms one year following nourishment. On the beach that received sediment similar to the native beach, the macrofaunal assemblage did not differ significantly from the non-nourished nearby beach following construction (Colosio et. al, 2007). Other studies also demonstrate reduced recovery times that were likely driven by use of unnatural or incompatible sediments for nourishment. A study by Manning et al. (2014) examined physical and biological impacts resulting from two dredge spoil disposal events occurring in consecutive years (1999 and 2000) using sediments obtained from maintenance dredging of a navigation channel. The 1999 disposal event continued from April to June and therefore coincided with the spring recruitment period for macroinvertebrates; by contrast the 2000 disposal event was completed prior to the benthic invertebrate recruitment period. Results demonstrated that sites receiving the disposal material exhibited finer grain size and an increase in sorting as compared to control sites. Invertebrate abundance subsequently remained depressed for all taxa throughout the warm season except the polychaete Scolelepis squamata, which responded positively to the finer sediments. Importantly, the disposal event occurring before the recruitment period of benthos resulted in fewer negative impacts to abundance than the disposal project conducted after the recruitment season. Although recovery occurred within one year after the 1999 disposal event, abundances were again depressed with the implementation of the second disposal event in 2000, highlighting the critical importance of adequate recovery periods incorporated into nourishment cycles, as well as the potential adverse impacts associated with using nourishment material that is finer than the native beach. A study by Peterson et al., 2014 reported multi-year (> 3 years) impacts following two beach nourishment projects that utilized “unnaturally coarse, shelly material”. Use of this material resulted in significant increases in the proportion of gravel to total sediment weight of nourished beaches following nourishment that persisted throughout the study and slowed the convergence of sediment properties between nourished and non-nourished beaches. The percent by weight of gravel did not match sediments at control locations until just over 3.5 years after nourishment occurred. Sampling revealed longer recovery rates for some invertebrate taxa than has been reported for previous studies. Bean clams (Donax spp.) abundances remained depressed by 70 to 90% for three to four warm seasons following nourishment when compared to non-nourished control locations. Likewise, haustoriid amphipods exhibited significantly depressed abundances throughout duration of the study (over 3.5 years) with no indication of trending toward recovery. Mole crabs (E. talpoida) showed small, ephemeral responses to nourishment; abundances were depressed in two years following nourishment, but not always statistically significant. Polychaetes abundances were variable, and no indication of an effect of nourishment on abundances. Total biomass of all macroinvertebrate taxa was depressed, but not significantly so, and recovered in one to two years. This study also looked at indirect impacts to the predators of invertebrates, namely ghost crabs and foraging shorebirds. The authors reported the effect on ghost crabs determined via burrow density counts, was initially negative and most pronounced on the beach flat where sand was placed. However, considerable recovery occurred by the following warm season, and the effect was no longer evident within two warm seasons. The number of foraging shorebirds was substantially reduced, but recovered two to three years after nourishment. The negative impacts on benthic infauna recovery associated with using unnaturally course sediments for nourishment has also been suggested in other studies (Peterson et al. 2006; Manning et al. 2013) Wooldridge et al.'s 2016 study reported that some infaunal taxa did not recover at the end of the 15-month monitoring period despite using sediment that was deemed compatible with the native beach. The study involved comprehensive sampling of invertebrates on eight beaches along the southern California coast. Contrary to other studies, Emerita sp. and Donax sp. recovered within 1 year, while other invertebrate taxa studied (amphipods and polychaetes) remained reduced in terms of density and abundance after 15 months of monitoring. Nourishment occurred in the fall; therefore it is possible that placement of fill material depressed the population too late in the season and did not allow for recolonization prior to the seasonal population decline, as has been suggested in other studies (Burlas et al. 2001). As presented above, a wealth of data that has been generated over recent decades resulting in a comprehensive understanding of the impacts to benthic resources in response to beach nourishment projects. Some of the information presented above even includes the results from a recent benthic monitoring study from a similar project (use of beach compatible sand with placement during the summer months) from a nearby location (Nags Head). As such, the applicants feel that additional monitoring efforts as requested by DMF are not necessary as the effects of the proposed activity is widely known. Furthermore, Burlas et al. (2001) concluded that the natural variability of the benthic community poses a challenge to distinguish between natural and nourishment-induced impacts without a high-frequency and high-density sampling program, which is time consuming and expensive for quantitative analysis. In conclusion, DMF's request for a single pre-construction monitoring event paired with two post- construction monitoring events would most likely result in statistically insignificant results. Requested Monitoring Protocol #2: Turbidity plume monitoring, to ensure increases in turbidity are not causing significant impacts on the surrounding environment. Ideally, this would include monitoring to observe how widespread the turbidity plume occurs during dredging and placement operations. This should also involve taking water quality samples before, during, and after dredging and disposal operations. At a minimum, this should be completed once per day, taking measurements before dredging and placement at the dredging location and disposal site, and at least once during dredging and once during placement. Specific parameters should include (at a minimum) turbidity (i.e. secchi depth) and surface and bottom measurements of dissolved oxygen, temperature, and salinity. Permits issued for the construction of the 2017 nourishment event within the Town's of Duck, Southern Shores, Kitty Hawk, and Duck oceanfront shoreline did not include conditions requiring water quality monitoring. Due the constant mixing of water driven by currents, tides, waves, and wind, water temperature and dissolved oxygen levels in the nearshore environment of the Atlantic Ocean are typically not impacted by the placement of beach fill material along the beach. As such, the applicant asserts that daily water quality monitoring efforts for these parameters should not be required. However, it is common practice during beach nourishment projects for the contractor to maintain sand dykes on the beach in proximity to the outfall pipe as a means to control the turbidity levels within the nearshore environment. This practice was successfully employed during the 2017 nourishment project and the proposed project will include the same mitigation measure. If DMF or DCM raises concerns regarding turbidity levels during the construction of the proposed project, a turbidity monitoring regime could be implemented at that time. Requested Monitoring Protocol #3: Habitat surveys at the disposal locations to ensure the projects are not causing significant alterations in habitat type (i.e. SAV, wetlands, intertidal). In cases such as the intertidal area, this would be to show that the placement of material isn't causing a significant shift in habitat types that are based on water depths (removal of shallow habitat and/or conversion of shallow habitat to deeper habitat, conversion of intertidal to subtidal, etc.). As indicated in the applicant's Major CAMA permit application, no SAV or wetlands occur within the project area and therefore no project-related impacts to those resources will be incurred as a result of the proposed activity. The characteristics of the borrow material utilized during a beach nourishment project helps to determine the slope of the beach berm and the nearshore seafloor. Because the borrow area (Borrow Area A) used for the 2017 nourishment event will be the same sand source for the proposed beach nourishment project, the sediment characteristics (sediment grain size, % silt, sorting, etc.) will be very similar. Therefore, it is expected that the beach will respond in a similar manner resulting in similar slopes along the beach, intertidal areas, and nearshore subtidal areas. Accordingly, no discernable shifts in habitat types are anticipated from this project. Requested Monitoring Protocol #4: Monitoring for dead fish and crabs along placement - any deceased fish/crabs observed in disposal areas (those in which the cause of death isn't obviously related to recreational fishing) should be recorded and reported. This should also include monitoring, recording, and reporting any fish/crabs that are caught and/or killed by dredging equipment. Recordings should include, at a minimum, date/time/location observed, species, and length (tail length - measured in centimeters from tip of the mouth to the tail fork; for crabs, measurement should be the width of the carapace). Pictures are also helpful with this to ensure correct identification and for verification that mortality is related to dredging. The applicants will agree to making note of any dead fish or crabs observed by the construction observer who will be on site at the beach fill location on a daily basis throughout the duration of the project. The observer will record the date/time/location of each dead fish or crab and make note of the species, if possible, along with length (tail length or carapace width). The protected species observer (PSO) aboard the hopper dredge will make note of any dead fish or crab along with other fauna during dredging, however due to physical constraints it may not be feasible to obtain individual specimens to take measurements. It is unlikely that crabs or fish entrained by the dredge will be identifiable and therefore the applicants do not feel it is practical to require monitoring for dead fish and crabs aboard the dredge. Requested Monitoring Protocol #5: If possible, noise monitoring should be included. Ideally, this would occur at varying distances from the dredge and disposal locations. Monitoring should include recording noise levels before or after operations (to provide a baseline) and during the dredging and disposal (to observe the increases that result from the dredging and disposal). Ambient sound levels within coastal waters can vary seasonally and temporally, and are associated with shipping and industrial sounds, wind-and-wave induced sound, and biologically produced sound (Richardson et al. 1995). Reine et al. (2014) characterized ambient sound levels at an offshore borrow area to be quite high; sound pressure levels (SPLs) averaged 117 dB re 1μPa at the upper listening depths (3-m water depth) and 114.9 dB re 1μPa at the lower listening depth (9-m water depth). Overall average ambient SPL at the offshore borrow area was 116.1 re 1μPa. During dredging activities, noise levels will increase above the ambient levels at the borrow areas and beach site due to the presence of construction equipment and personnel. Previous studies have already revealed the typical noise levels that may be incurred during dredge and fill activities similar to what is being proposed. Marine dredging produces broadband, continuous, low frequency sound that can be detected over considerable distances and may trigger avoidance reactions in marine mammals (Thomsen et al., 2009) and other organisms. The sound produced is dependent on many factors including, but not limited to, substrate type, sediment type being dredged, type of equipment used and skill of the dredge operator. The variation in noise emitted by equipment type is related to how the machinery makes contact and extracts material from the sea floor. Clarke et al. (2002) performed a study of underwater noise produced by various types of dredging equipment, including a hydraulic cutter suction dredge and a trailing suction hopper dredge. Recordings of a hydraulic cutter performing maintenance dredging in Mississippi Sound, Mississippi emitted noise as the cutterhead was turned at 1 – 10 rpm within the substrate. Sounds were continuous and fell within the 70 to 1,000 Hz range while sound pressure levels peaked between 100 to 110 dB re 1μPa rms. In the case of a hopper dredge, much of the sounds emitted during the active dredging process are produced by propeller and engine noise, pumps and generators. Similar to a cutter suction dredge, most of the sound energy produced fell within the 70 to 1,000 Hz range and was continuous in nature. However, Clarke et al. (2002) reported peak pressure levels recorded by a listening platform ranged from 120 to 140 dB re 1μPa rms for hopper dredges, which is comparatively much higher than a cutter suction dredge. A more recent study evaluated sound levels produced by hopper dredges operating in an offshore environment during sediment excavation, transport of material, and pump-out of material (Reine et al., 2014). When averaged across all dredging activities, SPLs averaged 142.31 dB at a distance of 50 meters, and grew progressively less to 120.1 dB at 1.95 km. At all distances from dredging activity, sound levels were highest during sediment removal activities and transition from transit to pump-out, and were quietest during flushing of pipes at pump-out (132.45 dB). At a distance of 2.5 km, sounds attenuated to ambient levels. Because the noise generated by beach nourishment projects such as what is being proposed for the four beach towns in Dare County are already well understood, the applicants assert that noise monitoring is not warranted. Thank you for considering these responses to DMF's request to include monitoring activities as a condition to the towns of Southern Shores, Kitty Hawk, and Kill Devil Hill's anticipated Major CAMA permits. Please contact me anytime should you have any questions or need anything in addition. Sincerely, COASTAL PROTECTION ENGINEERING OF NORTH CAROLINA, INC. Brad Rosov Project Manager/Senior Marine Biologist