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Home My WebLink AboutIn-stream Impoundment Guidance/In-stream Impoundment Guidance Subject: In-stream Impoundment Guidance From: Brian Wrenn <bnan wrenn@ncmail net> Date: Tue, 16 May 2006 17 10 51 -0400 To: David Cox <david cox@ncwildlife org> CC: John Hennessy <John Hennessy@ncmail net>, John Dorney <john dorney@ncmail net>, Cyndi Karoly <Cyndi Karoly@NCMail Net> David, We have reviewed the guidance and have the following comments 1 Over all we agree with the guidance We appreciate your efforts to build consistency among your representatives and to provide a good starting point for anyone considering an impoundment 2 Although it is clear that WRC does not want this to be a regulatory document, DWQ feels that there should be some reference to the 404/401 permitting process in the document The "Remainng Issues Discussion" may be a place to recommend that anyone planning impoundment activates should consult with the Corps, DWQ, and DCM when applicable 3 The next to last bullet on p 13 discusses placing nprap below the high water mark with vegetation aboveon outlet structures For in-stream impoundments is seems that there is the potential for significant hydraulic energy from outlet structures and spillways DWQ would prefer for the energy to be dissipated prior to reaching the stream bed (e g , np rap, stepped spillway, etc ) It is unclear whether vegetation could achieve this kind of energy dissipation In addition, DWQ prefers np rap to be minimized below the high water mark, but understand that it is necessary in many cases to maintain stream stability 4 The first bullet on p 14 is somewhat confusing I understand that you are discussing temperature and DO, but the "Coldwater intake" term makes it difficult to determine whether this is in the pond (standing head pipe type structue) or in the stream (the inlet to the pond) This may need some clarification 5 The fourth bullet on p 14 discusses a sediment management plan What would this consist of? Some further discussion of this bullet may be necessary. Again, thanks for pulling this together Want to do one that discusses dam breaches in depth? Brian Brian L Wrenn Environmental Specialist III 1 of 2 5/18/2006 11 07 AM [Fwd WRC On-Line Pond Literature review and guidance document] Subject: [Fwd WRC On-Line Pond Literature review and guidance document] From: John Dorney <John Domey@ncmatl net> Date: Thu, 04 May 2006 20 57 07 -0400 To: Cyndi Karoly <Cyndi Karoly@NCMail Net>, John Hennessy <John Hennessy@ncmatl net>, Mike Parker <Mike Parker@ncmatl net>, "DENR PROGDEV DWQ" <DENR PROGDEV DWQ@ncmatl net> FYI if you have any comments, please send them to me by May 26 thankx Subject: WRC On-Line Pond Literature review and guidance document From: "Cox, David R " <david cox@ncwtldlife org> Date: Wed, 3 May 2006 14 18 31 -0400 To: " (keith a hams@us army mil)" <keith a hams@us army mil>, Jean B Manuele@us army mil, David M Lekson@us army mil, " (William t walker@usace army mil)" <William t walker@usace army mil>, "Brian Cole (Brian _Cole@fws gov)" <Brian Cole@fws gov>, "Pete Benjamin (Pete _Benjamin@fws gov)" <Pete_Benjamin@fws gov>, " (matt flint@nc usda gov)" <matt flint@nc usda gov>, " (mike hinton@nc usda gov)" <mike hinton@nc usda gov>, Melba McGee@ncmatl net, John Dorney <John Domey@ncmatl net>, John Hennessy <john hennessy@ncmatl net>, Cyndi Karoly <cyndi karoly@ncmail net>, Linda Pearsall <linda pearsall@ncmail net>, " (Gray Hauser@ncmatl net)" <Gray Hauser@ncmatl net>, " (max fowler@ncmatl net)" <max fowler@ncmatl net> Dear State and Federal Agency partners, The NC Wildlife Resources Commission contracted with Danielle Pender to conduct a literature review, regarding the effects of on-line, in-line or in-stream impoundments on aquatic resources and their habitats and write a guidance document detailing those findings The purpose of this document is to give WRC staff information regarding how these impoundments are regulated in other states, provide literature citations describing the effects of these projects on aquatic resources and their habitats and provide a list of recommendations for situations when the construction of these projects is either desired or unavoidable The NCRWC staff would like for your agencies to review this guidance document and suggest edits and ways in which you feel it could be improved upon We will consider any recommendations when preparing a final draft of the document Please circulate the document within your agency or send it to appropriate staff I would like to have any comments back by June 1, 2006 We anticipate having the final guidance prepared by July 1, 2006 Thank you for your consideration of the document We feel that interagency input will improve the final product and look forward to receiving your input If you have any questions please feel free to contact me David R Cox Technical Guidance Supervisor Habitat Conservation Program, NCRWC 919 528 9886 WRC On-Line Pond Literature review and guidance document Content-Type: message/rfc822 1 of 2 5/5/2006 10 20 AM [Fwd WRC On-Line Pond Literature review and guidance document] In-stream Impoundments NC DRAFT 3.doc Content-Encoding: 7brt Content-Type: application/msword Content-Encoding: base64 2 of 2 5/5/2006 10 20 AM NORTH CAROLINA WILDLIFE RESOURCES COMMISSION IN-STREAM IMPOUNDMENT GUIDANCE DATE 2006 i '1. t? 1 ?it y ?r . Ilk 1 t 4 ? "` xr s?, mom" Y. ~y rr? i DRAFT NORTH CAROLINA WILDLIFE RESOURCES COMMISSION IN-STREAM IMPOUNDMENT GUIDANCE Prepared by Danielle R. Pender Submitted Date 2006 Table of Contents Preface 1 Introduction 1 Environmental Effects of Impoundments 2 1 Fragmentation and Migration 3 2 Reduced Abundance and Diversity 4 3 Extirpation from Native Range 4 4 Displacement by Exotics 5 Effects of Sto cking 6 Other States 7 A California Department of Fish and Game 7 B Idaho Department of Fish and Game 8 C Kansas Department of Wildlife and Parks 8 D Minnesota Department of Natural Resources 8 E Montana Fish, Wildlife and Parks 9 F New Jersey Division of Fish and Wildlife 10 G New York State Department of Environmental Conservation 10 H Utah Division of Wildlife Resources 10 I Washington Department of Fish and Wildlife 10 J Wisconsin Department of Natural Resources 11 K Wyoming Game and Fish Commission 11 Remaining Issues Discussion 12 Recommendations 12 A Project Design 13 B Project Planning 14 Literature Cited 16 Preface This document is intended to serve as guidance to assist North Carolina Wildlife Resources Commission (NCWRC) personnel with addressing issues related to the effects of in-stream impoundments on perennial stream channels This Guidance includes information, recommendations, and references that will provide meaningful assistance to NCWRC personnel involved in consultation activities where the impoundment of perennial streams is proposed, primarily in the form of small impoundments such as ponds The definition of a pond according to Armantrout (1998) is a "Natural or artificial body of standing water that is typically smaller than a lake [less than 8 ha (20 acre)]" The Guidance supports NCWRC recommendations to locate ponds off-channel and to avoid wetlands and other high quality habitat Refer to the NCWRC Procedures for Reviewing Hydropower Projects Licenses by the Federal Energy Regulatory Commission for information on hydropower projects, to the NCWRC Committee on Nonmdigenous Species Introductions Draft Stocking Policy for detailed stocking recommendations, and to the NCWRC Policies and Guidelines for Conservation of Aquatic and Terrestrial Habitats for general guidance Introduction The NCWRC is charged by statute with management, regulation, protection and conservation of wildlife resources and inland fisheries in North Carolina (G S 113-132) Wildlife resources include all undomesticated avian, terrestrial and freshwater fauna as well as supporting ecosystems (G S 113-129) The NCWRC is dedicated to conserving all natural habitats including wetland, riparian, aquatic, and upland habitat for the benefit of aquatic and terrestrial wildlife and for the enjoyment of North Carolina's citizens North Carolina rivers and streams harbor diverse and unique species, habitats, and ecosystems There are 5,251 dams listed in the North Carolina Division of Land Quality's database, 1,057 of those may be considered relatively small [(< 16 feet high - structural height measured from the lowest downstream elevation to the highest point on the crest of the dam) Dams < 15 feet may not be included in the database unless they meet certain cntena] An in-stream impoundment guidance is necessary because impoundments modify stream flows, affect water quality, and can cause the alteration of the natural diurnal, seasonal, and annual patterns of the upstream and downstream movements of in- stream biota (Yeager 1993) It is the NCWRC policy to advocate avoiding any diminution of the quantity or quality of the natural flow of water Properly designed and managed waterfowl impoundments are acceptable practices within the wildlife management profession Plans for impoundment construction and management should clearly demonstrate public benefits and result in improved habitat for waterfowl without detriment to other aquatic and terrestrial wildlife resources In addition, ponds that are properly managed can provide excellent fishing opportunities to a large number of anglers The NCWRC in cooperation with the North Carolina Cooperative Extension Service published a Pond Management Guide that describes site planning and pond construction, stocking and harvesting, and pond management The Pond Management Guide describes two general types of ponds (1) watershed or embankment ponds, which are formed by constructing a dam to collect stream or surface runoff, and (2) excavated ponds, which are formed by digging down into the water table in an area that is relatively flat More information concerning pond construction and management is found in the "Pond Management Guide" published by the NCWRC and the N C Cooperative Extension Service This guide can be obtained online at www ncwildlife org The objective of the NCWRC In-stream Impoundment Guidance is to assist NCWRC personnel in determining if a proposed pond construction will be conducted in a manner that is consistent with their statutory responsibilities and the need for protecting high quality aquatic and terrestrial wildlife habitat The NCWRC recommends that (1) small impoundments be located off-channel and wetlands and other high quality habitats be avoided and (2) ponds be located on a stream only when all other options have been exhausted The NCWRC strongly recommends against locating ponds in naturally reproducing trout waters, anadromous species waters, and waters that contain state and federally listed species The NCWRC will formulate recommendations to help reduce the adverse effects of impoundments on aquatic and terrestrial resources based on information available to the agency, as appropriate under the circumstances presented Therefore, the language of this Guidance should not be interpreted to establish any binding requirements on NCWRC personnel or regulatory agencies Environmental Effects of Impoundments Running waters are complex physical, chemical, and biological systems that interact and affect downstream elements in many ways Although dams have contributed to national economic development and social welfare, they have had ecological impacts on river and riparian ecosystem structure and function (Blough et al 2004) The negative effects of impoundments are well documented and include blocking migration routes, habitat fragmentation, alteration of natural hydrologic and geomorphic regimes, degradation of water quality, declines in biodiversrty, alteration of natural food webs, and disruption of riparian plant communities (Baxter 1977, Ward and Stanford 1979, and references therein, Tyus 1990, Yeager 1993, Ligon et al 1995, Pringle 1997, Benstead et al 1999, Pringle et al 2000, Blough et al 2004) The cumulative ecological effects of multiple dams are likely to be substantial Depending on outlet depth and design [hypolimnetic (deep), epilimnetic (shallow), multi-level release, or run-of-the-nver], the physical, chemical, and biological attributes of the downstream ecosystem will be affected differently (Yeager 1993, Tyus 1999, Blough et al 2004) In addition to coldwater releases being known to produce several ecological changes, warm surface water releases have coincided with lower densities of cold-water fish species (Lessard and Hayes 2003) Both high and low stream flows influence the survival of aquatic ammals (Schlosser 1991) Water level 2 fluctuations have the potential to adversely affect fish microhabitat (Bain et al 1988) and spawning, seasonal availability of aquatic and floodplain habitat, development of aquatic and terrestrial macrophytes, riparian vegetation growth, and bottom-dwelling organisms (Tyus 1999, Blough et al 2004) As river segments become fragmented due to dam construction, plant and animal movements are interrupted Migration cues may be lost to migratory fish, and resident fish habitat needs for different life history functions, such as spawning, nursery, foraging, and over-wintering areas and seasonal thermal refugia can also be lost (Yeager 1993, Blough et al 2004) The fragmentation of streams can lead to reduced genetic flow and variation to upstream populations, and downstream areas can act as population "sinks" for "source" populations of native species upstream (Pringle 1997) Alternatively, degraded downstream areas can act as "source" populations of exotic species that migrate upstream (Pringle 1997) Nutrient and energy exchange may be prevented from larger downstream systems to upstream areas by stopping or reducing aquatic life passage (Blough et al 2004) Dams trap sediments, nutrients, and large woody debris, prevent their normal processing by rivers, and cut off transport to larger downstream water bodies (Yeager 1993, Tyus 1999, Blough et al 2004) Most published literature contains information about large dams and reservoirs Smaller dams and impoundments influence watersheds and natural resources similarly, but possibly to a lesser degree (Porto et al 1999, Beasley and Hightower 2000, Tiemann et al 2004, Santucci et al 2005) In some cases, profound detrimental effects to the biotic integrity of warmwater rivers have been found for low-head dams with relatively small impoundments (Santucci et al 2005) Inflatable dams are often used as seasonal impoundments and the impoundments created are generally of small size However, inflatable dams can cause migration delays (forming a notch in the crest may reduce this effect) (Manning et al 2005) Although several presented studies discuss impacts to smaller systems and impoundments and the impacts caused by ponds may be similar to both large and smaller impoundments, note that the magnitude of pond impacts may occur at a lesser degree Also see the NCWRC Fisheries Management Fact Sheet "Environmental impacts caused by ponds" Common consequences of altered rivers are a decrease in suitable habitats, fewer native flora and fauna, and more non-native plants and animals (Bain et al 1988, Neves and Angermeier 1990, Tyus 1999, Pringle et al 2000, Blough et al 2004) Research on the potential effects of in-stream impoundments on riverme fauna and their habitat are summarized as follows (many of the references below discuss the effects of smaller impoundments) 1 Fragmentation and migration Even during periods of high flow when the Quaker Neck Dam (7 feet high) on the Neuse River, North Carolina, was completely submerged, American shad (Alosa sapidissima) and striped bass (Morone saxatilas) migration was substantially affected (Beasley and Hightower 2000) Low-head barrier dams constructed to control populations of sea lampreys (Petromyzon marinus) were demonstrated to affect movements of some non-target fishes on stream tributaries of the Laurentian Great Lakes (Porto et al 1999) and low-head dams were found to affect the migration of fishes and amphidromous freshwater shrimps in Puerto Rico (Holmquist et al 1998, Benstead et al 1999) Fluvial specialists showed reduced movements among Texas headwater streams upstream of an impoundment (Herbert and Gelwick 2003) An in-stream pond created to reduce nutrient transport was found to slow migration time and increase mortality rate of brown trout (Salmo trutta) smolts in a creek in Sweden (Olsson, et al 2001) Watters (1996) found that small dams restricted mussel fauna to downstream reaches in Midwest river systems and concluded that dams as small as 3 28-feet high were obstacles to the distribution of some fishes, and therefore to the distribution of the mussels 2 Reduced abundance and diversity Aquatic biota diversity and abundance can be reduced due to both impoundments and flow modifications (Erman 1973, Wildhaber et al 2000, Santucci et al 2005) Densities of the federally threatened Neosho madtom (Noturus placzdus) and channel catfish (Ictalurus punctatus) were higher above than downstream of the John Redmund Dam on the Neosho River in Kansas and Oklahoma due to altered physical habitat, hydrology, and water quality (Wildhaber et al 2000) Tiemann et al (2004) found that low head dams on the Neosho River in Kansas were associated with changes in water depth, stream velocity, and substrate compaction and composition which affected macroinvertebrate and fish abundance and evenness In addition to reduced movement effects, Texas headwater streams upstream of an impoundment were also populated by more tolerant macrohabitat-generalist species and showed a reduced abundance of fluvial specialists (Herbert and Gelwick 2003) Although fish passage was found to be feasible for some species at individual low-head dams on the Yellowstone River in Montana, a cumulative fish passage challenge may result in restricted fish distributions and limited abundance due to the six dams in a series (Helfrich et al 1999) Fish assemblage changes were documented in three years of post-impoundment surveys below Beaver Dam on the White River, Arkansas, furthermore, 30 years after impoundment, substantial fish assemblage changes had occurred since the short-term post-impoundment surveys were completed (Quinn and Kwak 2003) Following the Woolen Mills Dam removal on the Milwaukee River, Wisconsin, smallmouth bass (Mzcropterus dolomieu) abundance and biomass increased substantially and they occupied new spawning areas and common carp (Cyprinus carpio) abundance and biomass declined dramatically in the previously impounded reach (Kanehl et al 1997) 3 Extirpation from native range Physical habitat alteration and introduced species are the first and second most frequently cited causal factors of extinction in North American fishes (Miller et al 1989) Isolated upstream populations may become extirpated when reproductive failure or high mortality cannot be compensated by recolomzation from downstream sources (Pringle et al 2000) Due to impounding and poor water quality on the Tennessee River system, extirpation of species and changes in species composition of fishes, mussels, and other 4 faunal groups have been observed (Neves and Angermeier 1990) Extensive changes in fish community structure occurred after the construction of the Altus Dam on the North Fork of the Red River, Oklahoma, including the extirpation of two minnow species and the drastic decline and possible extirpation of two other minnow species (Winston et al 1991) A mussel spatial extinction gradient was observed downstream of impoundments on the Little River in Oklahoma, where mussel species richness and abundance increased gradually with increasing distance from the reservoir and only sites furthest from the impoundment contained relatively rare species (Vaughn and Taylor 1999) In the Little River study, some mussel species did not begin to recover until 12 miles downstream of the impoundment and did not peak until 44 miles, which led researchers to suggest that considerable stream lengths are necessary to overcome the effects of impoundment on mussel populations 4 Displacement by exotics Dams can be a factor in allowing or preventing non-native species to become established in new systems (Blough et al 2004), and non-native species may be favored by altered flow regimes (Tyus 1999) After the formation of Grayrocks Reservoir on the Laramie River, Wyoming, significantly fewer native and more exotic species were collected from both upstream and downstream reaches (Quist et al 2005) The impoundment of Kinkaid Creek in Illinois resulted in the extirpation of six native species and a change in fish community structure that showed a potentially deceptive increase in species richness (Taylor et al 2001) An observed increase in species richness can also be due to an invasion of native species that does not normally occupy the area (Scott and Helfinan 2001) Habitat alteration, which may make a stream region unsuitable to an endemic specialist, may also increase the suitability for generalist species (Scott and Helfinan 2001) Dam removal as an option to support watershed restoration is an increasing trend in the United States, at least 123 dams have been removed since 1970 (Blough et al 2004) with the majority being less than 16 feet in height (Poff and Hart 2002) Dam removal that has occurred in North Carolina includes the Quaker Neck Dam in 1997-1998 (Meuse River), Cherry Hospital Dam in 1998 (Little River, a tributary to the Neuse River), Rains Mill Dam in 1999 (Little River), Lowell Mill Dam in December 2005 (Little River), and Carbonton Dam on the Deep River in January 2006 Dillsboro Dam on the Tuckasegee River, Steeles Mill Dam on Hitchcock Creek (a tributary of the Pee Dee River), and Pleasant Green Road Dam on the Eno River are in the process of being removed Dam removal offers long term benefits such as lotic habitat restoration and aquatic life passage, however, some short-term negative ecological effects may occur such as the release of sediments (Stanley et al 2002) and the burial of sedentary species such as mussels could occur following removal (Sethi et al 2004) Because dam removal, or even a partial breach, to restore native habitats and species assemblages could cause social, economic, and ecological disruptions (such as allowing the spread of invasive species to upstream locations) that greatly complicate decisions, the American Fisheries Society recommends that decisions about dam removal involve all vested interests based on a wide array of issues (Blough et al 2004) 5 Effects of stocking There are many reasons aquatic biota are introduced into alien freshwater environments Commonly accepted management strategies for realizing the full potential of altered aquatic habitats produced by impoundments are planned introductions (Blough et al 2004) Fish stocking in North Carolina is recognized as an important and appropriate fisheries management tool In recognition that thoughtful consideration should be given when making decisions regarding fish introductions, the NCWRC Committee on Nonmdigenous Species Introductions developed a stocking policy statement, a four-step stocking evaluation protocol, and a decision flow chart to evaluate stocking proposals Also refer to the NCWRC Fisheries Research Fact Sheet (16), "Dangers of fish introductions to our State's waters" Introductions of non-native fishes have resulted in a loss of biological diversity and have played a large part in the homogenization of fish faunas (Rahel 2000) Exotics may affect native species through predation, habitat use alterations, hybridization, and introductions of diseases or parasites (Allan and Flecker 1993) Introduced species may also colonize waters beyond the point of release (McMahon and Bennett 1996) Introductions can be planned or unintended, such as by the release of bait fish Some exotics are popular sport fish and support important recreational fisheries Salmomds form the basis of important fisheries in the North Carolina mountains Although trout species other than native brook trout (Salvelinus fontinahs) are also valuable to the fishery and to North Carolina citizens, non-native trout species have been known to negatively affect brook trout Therefore, careful consideration should be given to the placement of trout species in North Carolina waters The American Fisheries Society's Southern Division Trout Committee developed a position statement to advocate management approaches suitable for conserving native southern Appalachian brook trout (Habera and Moore 2005), which includes emphasizing conservation and prescribes fishery managers to restrict the use of hatchery-produced (non-native) brook trout to areas where southern Appalachian brook trout genetic integrity cannot be compromised through interbreeding or altered selective pressures related to ecological interactions Some of the effects reported in the literature of non-native trout introductions on native brook trout are summarized below • Over a 15-year period, a population of 100% brook trout was replaced by a dominant brown trout (Salmo trutta) population with some brook trout and rainbow trout (Oncorhyncus mykas) also being present in Valley Creek, Minnesota, likely due to habitat perturbations and the variable behavior of the trout species (Waters 1983) • Microhabrtat location and vertical distribution of brook trout shifted and brook trout lost weight and contracted fungus in the presence of brown trout in a laboratory stream (DeWald and Wilzbach 1992) 6 Water temperature and elevation generally limit wild trout habitat in the southern Appalachian region, which includes waters in Georgia, North Carolina, South Carolina, Tennessee, and Virginia (Habera and Strange 1993) Brook trout, originally the only salmomd present, now represent only about 25% of the southern Appalachian salmomd population in terms of inhabited stream length, and northern strains of brook trout that were part of past stockings or hybrids between northern and southern strains may now occupy much of the region (Habera and Strange 1993) Flebbe (1994) found brook trout to be located at higher densities in allopatry than in sympatry with brown and rainbow trout in southern Appalachian streams in North Carolina and Virginia, and rainbow and brown trout were most abundant in North Carolina lower elevation streams However, Strange and Habera (1998) did not find a change in allopatric brook trout range with rainbow trout in Tennessee Introductions of other non-resident species can affect resident fauna as well Stocking catchable-size hatchery rainbow trout in Montana streams coincided with a reduction in numbers and biomass of self-sustaining wild brown and rainbow trout (Vincent 1987) Where green sunfish (Lepomzs cyanellus) were introduced in North Carolina Piedmont headwater streams, their abundance and biomass exceeded that of any other coexisting species, and when they were removed, the biomass and numbers of most native species increased (Lemly 1985) Other States Thirty-eight state fish and wildlife resource agencies have pond information readily available on their websrtes, mostly in the form of a pond management guide For many states, the pond management guide only discusses upland ponds with some also discouraging stream impoundments, however, it is unclear from most of the guides whether in-stream ponds are disallowed or discouraged Some states also have special pond regulations, and information from those states is summarized below This list is not necessarily exhaustive A California Department of Fish and Game (http //www dfg ca gov/) • California law requires any person, state or local governmental agency, or public utility to notify the Department of Fish and Game (CDFG) before beginning an activity that will substantially modify a river, stream, or lake If the CDFG determines that the activity could substantially adversely affect an existing fish and wildlife resource, a Lake or Streambed Alteration Agreement is required Applicants are required to complete a notification package and submit a fee • Fish and Game Code section 1602 requires any person, state or local governmental agency, or public utility to notify the CDFG before beginning any activity that will do one or more of the following (1) substantially obstruct or divert the natural flow of a river, stream, or lake, (2) substantially change or use 7 any material from the bed, channel, or bank of a river, stream, or lake, or (3) deposit or dispose of debris, waste, or other material containing crumbled, flaked, or ground pavement where it can pass into a river, stream, or lake Fish and Game Code section 1602 applies to all perennial, intermittent, and ephemeral rivers, streams, and lakes in the state If an Agreement is required, the CDGF will conduct an onsite inspection, if necessary, and submit a draft agreement to the applicant The draft agreement will include measures to protect fish and wildlife resources while conducting the project The applicant may also be required to obtain a permit, agreement, or other authorization from one or more governmental agencies B Idaho Department of Fish and Game (http //fishandgame Idaho gov/) • A pond is defined as private only if it is entirely surrounded by private land and is not located on a natural stream channel Stocking or maintaining fish in such a pond requires a Private Pond Permit Any lake, pond, or reservoir with legal access to the public is considered a public water body The Idaho Department of Fish and Game (IDFG) manage the fisheries on public waters • Private Fish Pond Permits are free and must be renewed every five years The permits allow IDFG to monitor and prevent introductions of fish that could harm wild populations • Before a permit can be issued, landowners must screen the outlet of their pond to insure that fish cannot escape into public waters from the pond The inlet may also require screening to keep wild fish from entering the pond • Since even the best screens may fail, IDFG only allows stocking of desirable species that are currently found in adjacent waters To prevent the introduction and spread of disease, only fish from an approved, disease-free hatchery may be stocked C Kansas Department of Wildlife and Parks (http //www kdwp state ks us/) • A permit is required to construct a pond or otherwise modify habitat occupied by threatened or endangered fish and wildlife species Permits are obtained from the Kansas Department of Wildlife and Parks D Minnesota Department of Natural Resources (http //www dnr state mn us/index html) • A permit is necessary for transferring live game fish into and within the State of Minnesota This permit is available free of charge The information needed to complete the permit includes the source of fish, the legal description (Township, Range, Section) of the destination of the fish, the species, number and size of the fish to be stocked, the date of stocking and the size, license number, and route of the truck to be used for hauling the fish 8 E Montana Fish, Wildlife and Parks (http //fwp mt gov/default html) • Based on state law first passed in 1945, Montana Fish, Wildlife & Parks (MFWP) administers private fish pond licensing Regulations are intended to allow the stocking of private fish ponds while ensuring that public resources are not adversely affected by unwanted fish or fish diseases, that nuisance aquatic species are not planted into ponds where they can escape or be introduced into state waters, and habitat of wild fish is not harmed • Pond builders should be aware of and be sensitive to the fact that water withdrawals for new fish ponds may negatively impact downstream public resources including wild fish All private fish ponds consume some water Every effort should be made to eliminate or minimize the use of stream surface water or alluvial groundwater for ponds • A private fish pond permit applicant must have a water right appropriate for the size and location of the pond MFWP cannot issue fish stocking permits until it is certain that legal water rights exist (if needed) for the pond or reservoir MFWP may file an objection to a requested water right if it is determined that the withdrawal will pose an unacceptable risk to fish in adjacent public/state waters • Pond owners will not be permitted to stock fish if the pond is likely to flood or if it poses an unacceptable risk to game fish or species of special concern • In-stream ponds will not be permitted unless it can be demonstrated that there is no threat to game fish or species of special concern in adjacent waters The applicant must provide documentation verifying that game fish or species of special concern do not occur in the tributary, spring or stream for the proposed in- stream pond, and that the pond does not pose an unacceptable risk to game fish or species of special concern in adjacent waters Verification must be in the form of a formal report from an MFWP-approved professional fisheries consultant, or other reliable data and documentation (MFWP survey/inventory data, university studies, scientific journal articles) • The MFWP is required by law to prepare an environmental assessment (EA) of any proposal to introduce fish into a pond and must provide a minimum 14-day public comment period on potentially controversial proposals or proposals that may have impacts that require mitigation At least one site visit is necessary as part of the EA process • The MFWP regional office will contact the applicant to conduct a pond inspection as part of the EA process and to ensure that the pond is properly screened to prevent fish from entering or escaping the pond • The Regional MFWP office issues private fish pond permits Permits are issued for a duration of 10 years Only fish species approved and obtained from a lawful source may be stocked Normally, fish approved for stocking will be limited to those species presently occurring in the drainage • Because the MFWP is funded by general license dollars, department biologists cannot provide technical assistance to private pond owners unless free public access is provided • The applicant may also be required to obtain a permit, agreement, or other authorization from one or more governmental agencies 9 F New Jersey Division of Fish and Wildlife (http //www state nj us/dep/fgw/) • The New Jersey Fish and Game Code requires that a stocking permit from the Division of Fish and Wildlife be obtained for stocking any fish or fish eggs in all waters of the State, both public and private, which are contiguous with the ocean G New York State Department of Environmental Conservation (http //www dec state ny us/website/dfwmr/) • Prior to stocking fish in a pond, a Farm Fish Pond License must be obtained from the New York State Department of Environmental Conservation (NYSDEC) The license allows the licensee, his immediate family, and his employees to take fish at any time, in any size, in any number, and in any manner as stipulated in his license The farm fishpond license also serves as a stocking permit, eliminating the need to obtain a separate NYSDEC fish stocking permit, which is required to stock fish into any waters of the state • A Permit to Stock Triploid Grass Carp must be obtained if the applicant chooses to use grass carp to control aquatic plants A current New York State fishing license is required to catch fish from the pond • A Stream Protection Permit is required for the disturbance of a protected stream A Freshwater Wetland Permit is required for excavating or filling an area within 100 feet of a NYSDEC regulated freshwater wetland H Utah Division of Wildlife Resources (http //wildlife utah gov/index php) • All ponds must be inspected by Utah Division of Wildlife Resources (UDWR) personnel before a Certificate of Registration is issued to confirm that adequate screening is installed and that the pond is not on a natural stream No private pond can be constructed on a natural flowing stream (Utah Code 23-15-10) Inflows (except springs) and outflows of ponds are required to be screened to prevent migration of fish in and out of the pond • A Certificate of Registration is required to produce, propagate, rear, or possess any aquatic wildlife or aquaculture product in a private fish pond for private, noncommercial purposes A separate certificate of registration is required for each private fish pond • A private fish pond owner or operator may not sell, donate, or transfer live fish or live fish eggs, except approved species may be transferred to the private fish pond from an approved source • Private stocking is limited only to those species approved on the certificate of registration I Washington Department of Fish and Wildlife (http //wdfw wa gov/) • A Fish Stocking Permit from The Washington State Department of Fish and Wildlife (WDFW) is required to plant fish into ponds or lakes on private land in 10 Washington State The main concern with most fish stocked into private ponds is to prevent any escapement into nearby waters of the state The WDFW is trying to protect native and important non-native fish species The spread of stocked fish species can have a detrimental impact through predation or competition Additionally, stocked fish species coming from commercial or wild sources may carry disease agents to waters that currently do not have them By requiring a Fish Stocking Permit, WDFW biologists are able to examine these possibilities and make determinations on the risk to fish in the waters intended for stocking and any nearby state waters The required fish stocking permit and biological evaluation covers two aspects concerning approval The first relates to the pond site parameters, while the second deals with approval of the source of fish Pond site parameters reviewed by WDFW biologist include water quality and quantity, inlet and outlet structures, connections to nearby state waters, and flooding potential Screening may be necessary in some ponds to keep fish from leaving In some cases, it may be necessary to have a hydraulics permit to put inlet or outlet screening in the pond The fish source approval covers an evaluation of the landowner's proposed fish management stocking plan regarding fish species or combination of fish species, stocking rates, potential feeding recommendations, and how those species will match with the pond's habitat The biologist will also review with the owner whether or not state fishing licenses and state fishing regulations apply to the pond Usually private ponds are exempt from these licenses and regulatory requirements Fish must have accompanying documentation showing them to be free from disease-causing organisms J Wisconsin Department of Natural Resources Bureau of Fisheries Management and Habitat Protection (http //www dnr state wi us/) • The Wisconsin Department of Natural Resources (WDNR) is required to review and permit all introductions of non-native fish or fish eggs into the state • Ponds without outlets constructed within 500 feet of a public waterway require an unconnected pond permit • All ponds with open or closed (1 e , piped) outlets to public waters, regardless of the distance to a public waterway, require an ultimately connected pond permit • All ponds connected by a navigable channel to an existing public waterway or any enlargement of any public waterway require a permit These ponds and enlargements are public waters by statute, and permit review requires a public notice and an EA K Wyoming Game and Fish Commission (http //gf state wy us/index asp) • The Wyoming Game and Fish Commission has developed a process to allow waters on privately held lands to be planted with fish from certified disease-free commercial fish hatchery operations The process involves identifying the species to be planted to ensure compliance with management plans for each II drainage, locating the water, its source, and waterways impacted by the private water, and authorizing commercial hatchery sources for the planting of trout Remaining Issues Discussion The studies discussed above demonstrate that small dams and impoundments influence watersheds and natural resources similarly, but possibly to a lesser degree than larger dams However, there appears to be some gap in scientific knowledge on the effects of ponds in particular, therefore, additional study may be warranted North Carolina and other states would benefit from such studies that would more precisely illustrate the effects of ponds constructed on streams Examining the potential for the numerous impoundment effects described above would be beneficial, and in particular, thermal impacts and the effectiveness of coldwater withdrawals on North Carolina's coldwater streams are of interest Research on the efficacy of management practices (e g screening inflows and outflows) to minimize the effects of in-stream impoundments would also be informative Information provided by these studies could guide future recommendations for in-stream impoundments State fish and wildlife agencies vary on their m-stream impoundment recommendations or requirements Many states require private pond licenses and the inlet and outlet of ponds to be screened Some of the more restrictive state agencies require a permit or notification prior to substantial modification to a water body, the completion of a lake or streambed alteration agreement, all ponds to be inspected, or the development of an Environmental Assessment, and some prohibit pond construction on a natural flowing stream A number of agencies also require a fish stocking and transferring permit, only allow certain species to be stocked, and only allow private ponds to be stocked with fish from certified disease-free commercial fish hatchery operations, and some do not allow stocking in private ponds located on natural stream channels The NCWRC may review and consider adopting some of these policies Recommendations The NCWRC will formulate recommendations to help reduce the adverse effects of impoundments on aquatic and terrestrial resources based on information available to the agency, as appropriate under the circumstances presented Therefore, the language of this Guidance should not be interpreted to establish any binding requirements on NCWRC personnel or regulatory agencies These recommendations may be revised as the science upon which they are based improves and areas of uncertainty are resolved, therefore, they should not be regarded as static or inflexible The NCWRC recommends that (1) small impoundments be located off-channel and wetlands and other high quality habitats be avoided and (2) ponds be located on a stream only when all other options have been exhausted The NCWRC strongly 12 recommends against locating ponds in naturally reproducing trout waters, anadromous species waters, and waters that contain state and federally listed species A Project Design Upland (off-channel) pond recommendations Only stock desirable species that are currently found in adjacent waters Screen inflows and outflows of ponds to prevent migration of fish in and out of the pond (provided that this can be accomplished in compliance with dam safety regulations) Locate new ponds away from streams and use surface runoff, springs, or water pumped from wells as water sources Ponds can also be filled by building them adjacent to a stream and diverting or pumping a small portion of the stream water into the pond to fill it Water should only be diverted into the pond continuously while the pond is being filled Once the pond is filled, water should only be diverted into the pond as needed to maintain water levels 2 Impoundment recommendations If after thorough analysis and all other options have been exhausted, the NCWRC recommends that the project be designed to minimize impacts if an in-stream impoundment project is going to proceed The recommendations below present a general list Each project should be considered in its own context, based on project design, stream type and condition, natural resources, and cumulative impacts • Ensure the pond is appropriately sized for the watershed • Sediment and erosion control measures must be used before construction and maintained • Any concrete work must occur in dry areas that are isolated from stream flow to prevent uncured concrete from coming in contact with stream waters and causing a fish kill • Rock, sand, or other materials must not be excavated from the stream channel except in the immediate permitted area • Sandbags, flexible pipe, or other stable diversion structures should be used to avoid excavation in flowing water • All mechanized equipment operated near surface waters should be inspected and maintained regularly to prevent contamination of stream waters from fuels, lubricants, hydraulic fluids or other toxic materials • Discharging hydroseed mixtures and washing out hydroseeders and other equipment in or adjacent to surface waters is prohibited • Any nprap (rock revetment) for outlet stabilization should be clean and limited to the stream bank below the high water mark, and vegetation should be used above • Minimize temperature deviations from upstream ambient conditions 13 • To minimize temperature elevation in waters downstream, native woody vegetation (e g , river birch, sycamore, red maple) should be reestablished wherever possible along the pond, but not on the dam Also, the outflow pipe must be designed to draw water from near the bottom of the pond Coldwater intakes should be within 1-2 feet of the bottom, but not on the bottom This design will prevent buildup of poorly oxygenated water and improve water quality in the pond Also see the NCWRC Fisheries Management Fact Sheet "Environmental impacts caused by ponds" • Stormwater ponds should be planted with local native trees and shrubs to provide a reduction of direct sunlight and restore some lost habitats for birds and small animals • When filling in-line ponds, residual flow in the stream below the dam must be maintained to protect aquatic life This can be accomplished by partially opening the gate valve during the filling process However, turbid water should not be discharged Until the water in the pond is clear, flexible pipe should be used to maintain any stream flow, if applicable, around the pond • A plan should be developed to manage sedimentation behind the dam • Only stock desirable species that are currently found in adjacent waters • It should be demonstrated that there is minimal or no threat to game fish or state or federally listed species in adjacent waters • Upstream and downstream passage of aquatic organisms may be warranted and should be reviewed on a case-by-case basis and viewed in the context of the watershed condition See the U S Fish and Wildlife Website (http //www fws gov/fishenes/FWSMA/FishPassage/) for detailed passage information • Mitigate impacts following a prioritized stepwise approach of avoidance, minimization, rectification, and compensation B Project Planning Prediction of biological, physical, and chemical changes resulting from a dam can be difficult, however, mitigation of those effects may be even more costly and complex Unintended consequences of stream degradation will occur upstream, downstream, and laterally when a river and its floodplam are disconnected (Allan and Flecker 1993, Pringle 1997, Fausch et al 2002)) Longer recovery times have been observed in disturbances that resulted in alterations to physical conditions (Nierm et al 1990, Yount and Niemi 1990, Detenbeck et al 1992) A starting goal would be to preserve a dynamic, geomorphically living stream (Ligon et al 1995) The maintenance of connectivity between habitat patches used by various life stages is critical for the reproduction and survival of fish in lotic systems (Schlosser 1991, Fausch et al 2002) Long-term monitoring may be warranted to determine when a fish assemblage has stabilized following habitat alterations (Quinn and Kwak 2003) 14 Information required to determine the biotic effects of hydrologic alteration include • A quantitative inventory of aquatic habitat • Impounded acreage and length of stream to be inundated • The location of the water body, nearby waterways, and wetlands • The location of floodplain and shoreland boundaries • A description of habitat modification upstream and downstream including any proposed modifications to the waterway (dredging, culverts, structures, outflow modifications, etc ) • Water temperature data (temporal and spatial) • Current lists and abundances of aquatic species from above and below the project • Information on the physical design of the project that allows or prohibits modifications to allow aquatic life passage • An evaluation of the cumulative biotic effects of hydrologic alterations of other sinular projects on a system • A plan to manage sediment behind the impoundment • A list of species that are intended to be stocked Due to the dynamic and unpredictable nature of stream hydrology, the difficulty in predicting stream impoundment effects, and the lengthy recovery time, the NCWRC cautions against relying on restoration to compensate for intentional physical and biotic impacts, and advocates that the best form of habitat mitigation is to avoid or minimize adverse impacts to the environment 15 Literature Cited Allan, J D , and A S Flecker 1993 Biodiversity conservation in running waters Bioscience 43 32-43 Armantrout, N B , compiler 1998 Glossary of aquatic habitat inventory terminology American Fisheries Society, Bethesda, Maryland Bain, M B , J T Finn, and H E Booke 1988 Streamflow regulation and fish community structure Ecology 69 382-392 Baxter, R M 1977 Environmental effects of dams and impoundments Annual Review of Ecology and Systematics 8 255-283 Beasley, C A, and J E Hightower 2000 Effects of a low-head dam on the distribution and characteristics of spawning habitat used by striped bass and American shad Transactions of the American Fisheries Society 129 1316-1330 Benstead, J P , J G March, C M Pringle , and F N Scatena 1999 Effects of a low- head dam and water abstraction on migratory tropical stream biota Ecological Applications 9 656-668 Blough, H , T Bigford, and J Haynes 2004 AFS Policy Statement on Dam Removal 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Midwestern River Transactions of the American Fisheries Society 133 705-717 Tyus, H M 1990 Effects of altered stream flows on fishery resources Fisheries 15(3)18-20 Tyus, H M 1999 AFS Policy Statement on Effects of Altered Stream Flows on Fishery Resources http //www fisheries org Vaughn, C C , and C M Taylor 1999 Impoundments and the decline of freshwater mussels a case study of an extinction gradient Conservation Biology 13 912-920 Vincent, E R 1987 Effects of stocking catchable-size hatchery rainbow trout on two wild trout species in the Madison River and O'Dell Creek, Montana North American Journal of Fisheries Management 7 91-105 Ward, J V , and J A Stanford, editors 1979 The Ecology of Regulated Streams Plenum Press, New York Waters, T F 1983 Replacement of brook trout by brown trout over 15 years in a Minnesota stream production and abundance Transactions of the American Fisheries Society 112 137-146 Watters, T G 1996 Small dams as barriers to freshwater mussels (Bivalvia, 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