EBTJV

Removal of Two Dams in the Wetmore Run Watershed, Potter County, PA: This project will remove the only two dams in the Wetmore Run Watershed in Potter County, Pennsylvania opening 8.5 miles of habitat for brook trout. Removal of the dams will also eliminate thermal pollution and restore lotic ecosystem function.
Located in Funded Projects / EBTJV Projects
Restoration of a backwater of the Arkansas River, Rector Chute: The Rector Chute backwater will be restored to prevent conversion of aquatic habitat to terrestrial habitat through sedimentation. Select areas will be dredged with a Mudcat hydraulic dredge.
Located in Funded Projects / SARP Projects W2B
Restoration of Connectivity to Coal Pile, a Backwater of the Arkansas River: In order to restore connectivity to Coal Pile, the canals from the Arkansas River into Coal Pile will be dredged with a Mudcat hydraulic dredge, which was recently obtained from federal surplus equipment for use on this project.
Located in Funded Projects / SARP Projects W2B
Restoration of Essential Habitats for Juvenile Tarpoon and Snook: Habitat loss and degradation are major threats to coastal fisheries, especially alterations of freshwater flow into estuarine habitats. This project will restore natural topography and hydrology to 229 acres of coastal land that includes juvenile habitat for economically and recreationally important tarpon and snook. Monitoring of water quality and fishes within mangrove creeks will quantify the changes resulting from restoration. An established education program will be used to disseminate project results to the public, and the project site will be protected and managed as a public park and nature preserve in perpetuity. This project is currently on-going.
Located in Funded Projects / SARP Projects W2B
Restoration of Native Charr in Big Wadleigh Pond Maine: This project will restore 157 acres of habitat for native brook trout and arctic charr in Big Wadleigh Pond in northwest Maine by collecting eggs/brook stock from the dwindling adult populations and rearing them in a private hatchery while the pond is chemically treated to eliminate an illegal introduction of rainbow smelt. Restoration will also benefit anglers at this unique and popular fishing destination.
Located in Projects / 2006 - 2018 Projects / 2012 Projects
Restoration of Native Charr in Big Wadleigh Pond Maine: This project will restore 157 acres of habitat for native brook trout and arctic charr in Big Wadleigh Pond in northwest Maine by collecting eggs/brook stock from the dwindling adult populations and rearing them in a private hatchery while the pond is chemically treated to eliminate an illegal introduction of rainbow smelt. Restoration will also benefit anglers at this unique and popular fishing destination.
Located in Funded Projects / EBTJV Projects
Restoring Aquatic Organism Passage within Wolf Laurel Branch, NC: This project will replace the existing double culverts with a bottomless structure to provide passage for brook trout and native nongame species. Replacement of these culverts will eliminate all artificial barriers within the Sand Creek drainage and reconnect existing populations of southern strain brook trout within approximately 2 miles of suitable habitat.
Located in Projects / 2006 - 2018 Projects / 2012 Projects
Restoring Aquatic Organism Passage within Wolf Laurel Branch, NC: This project will replace the existing double culverts with a bottomless structure to provide passage for brook trout and native nongame species. Replacement of these culverts will eliminate all artificial barriers within the Sand Creek drainage and reconnect existing populations of southern strain brook trout within approximately 2 miles of suitable habitat.
Located in Funded Projects / EBTJV Projects
Sampling strategies for estimating brook trout effective population size: The influence of sampling strategy on estimates of effective population size (Ne) from single-sample genetic methods has not been rigorously examined, though these methods are increasingly used. For headwater salmonids, spatially close kin association among age-0 individuals suggests that sampling strategy (number of individuals and location from which they are collected) will influence estimates of Ne through family representation effects. We collected age-0 brook trout by completely sampling three headwater habitat patches, and used microsatellite data and empirically parameterized simulations to test the effects of different combinations of sample size (S = 25, 50, 75, 100, 150, or 200) and number of equally-spaced sample starting locations (SL = 1, 2, 3, 4, or random) on estimates of mean family size and effective number of breeders (Nb). Both S and SL had a strong influence on estimates of mean family size and ^ Nb; however the strength of the effects varied among habitat patches that varied in family spatial distributions. The sampling strategy that resulted in an optimal balance between precise estimates of Nb and sampling effort regardless of family structure occurred with S = 75 and SL = 3. This strategy limited bias by ensuring samples contained individuals from a high proportion of available families while providing a large enough sample size for precise estimates. Because this sampling effort performed well for populations that vary in family structure, it should provide a generally applicable approach for genetic monitoring of iteroparous headwater stream fishes that have overlapping generations.
Located in Science and Data / Brook Trout Related Publications / Stream Assessment and Monitoring
Sampling strategies for estimating brook trout effective population size - Whitely et al. 2012: This research examined the influence of sampling strategy on estimates of effective population size.
Located in Science and Data / Brook Trout Related Publications / Chesapeake Bay Brook Trout Management Strategy-References

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