The goal of this project is to extend through 2016, calibrate, and validate the existing watershed model using Hydrological Simulation Program FORTRAN (HSPF) for the Pomme de Terre River Watershed. The contractor will produce an HSPF model that can readily be used to provide information to support conventional parameter Total Maximum Daily Load (TMDL) studies.
Certain stretches of the Pomme de Terre River have been identified as impaired. This project will quantify the reductions in pollutant loading that would be necessary to bring water quality in the impaired stretches to an acceptable level. It will also identify strategies that would improve water quality in these impaired stretches. Some funds will support public input activities into the Pomme de Terre River watershed management plan.
The goal of the Pomme de Terre River Association (PDTRA JPB) is to improve the local water resources within the watershed through targeted voluntary efforts and the building of strong relationships with local landowners, producers, and citizens. To further our efforts in strategically working to achieve our reduction goals, listed in our Major Watershed Restoration and Protection Strategies Report and Turbidity Total Maximum Daily Load report, we would like to further define our Priority Management Zones through the development of a hydrological conditioned Digital Elevation Model.
The Pomme de Terre River Association (PDTRA) will use this funding to pursue goals stated in the Comprehensive Watershed Management Plan. PDTRA has identified five priority areas to focus sediment & phosphorus reduction goals: Northern Lakes, Christina/Pelican Lakes, Pomme de Terre River Lakes Chain, Pomme de Terre River Corridor, and Drywood Creek. Plans include but aren't limited to: water & sediment control basins, alternative tile intakes, shoreline restorations/stabilizations, critical area plantings, grass waterways and SSTS upgrades.
This project will develop feasibility analysis, a drawdown plan for Malmedal Lake and an analysis of available options for fish barriers in the watersheds of Malmedal Lake and Strandness Lake.
The project will advance the protection, restoration and enhancement goals for prairie and grassland habitat as described in the 2018 update of the MN Prairie Conservation Plan. It builds upon the highly successful model established in prior Prairie Recovery Phases and seeks to protect approximately 600 acres in fee without PILT obligations to be held by The Nature Conservancy, enhance approximately 10,000 acres of permanently protected grasslands, and restore roughly 200 acres of prairie and wetland habitat.
Phase Four of the MN Prairie Recovery Program resulted in a total of 1,707 acres protected, 37,567 acres enhanced, and 440 acres restored. When combined with Phases 1-3 of the Prairie Recovery Program we have cumulatively protected 5,777 acres, enhanced 95,701 acres and restored 754 acres using Outdoor Heritage Fund dollars. We will continue to implement subsequent Phases toward meeting the conservation goals described in the MN Prairie Conservation Plan.
The project will advance the protection, restoration and enhancement goals for prairie, grassland and wetland habitats as described in the 2018 MN Prairie Conservation Plan. It builds upon the highly successful model established via prior Prairie Recovery Phases and seeks to protect 400 acres in Fee without PILT obligations to be held by The Nature Conservancy, enhance 18,000 acres of permanently protected grasslands, and restore 100 acres of prairie and wetland habitat.
This project will advance the prairie protection, restoration and enhancement goals established in the 2011 MN Prairie Conservation Plan. It builds upon the successful model established in Phases 1 - 6 and seeks to protect 200 acres in fee without PILT obligations to be held by The Nature Conservancy, protect an additional 100 acres with PILT for inclusion in the State's Wildlife Management or Scientific Natural Area systems, enhance 7,500 acres of permanently protected grasslands, and restore 100 acres of prairie habitat.
This project contributed to the goals of the MN Prairie Conservation Plan by protecting 284 acres of native prairie/wetland/savanna; restoring 102 acres prairie/wetland; and enhancing 10,045 acres grassland/savanna. When combined with Phases 1-7 of the Prairie Recovery Program we have cumulatively protected 7,734 acres, enhanced 154,814 acres and restored 2,036 acres using Outdoor Heritage Fund dollars. We will continue to implement subsequent Phases toward meeting the conservation goals described in the MN Prairie Conservation Plan.
The project will advance the protection, restoration and enhancement goals for prairie, grassland and wetland habitats as described in the 2018 MN Prairie Conservation Plan. It builds upon the highly successful model previously established in prior Prairie Recovery Phases and seeks to protect 500 acres in Fee without PILT obligations to be held by The Nature Conservancy, enhance 18,000 acres of permanently protected grasslands, and restore 200 acres of prairie and wetland habitat.
We propose to integrate Minnesota Wildflowers Information, an online tool for plant identification, with the Minnesota Biodiversity Atlas, to preserve and extend this popular ENTRF-supported resource for future use.
This project helps Minnesota entities that directly or indirectly cause PFAS and microplastics contamination stop the flow of the contaminants by developing strategies to manage solid waste streams.
Granite rock outcrops along the Upper Minnesota River are among the oldest exposed rock in North America, dating back approximately 3.6 billion years. These outcrops are also home to rare and specialized plant and animal communities rarely found elsewhere in Minnesota, including several types of cactus and one of Minnesota's only three lizard species, the five-lined skink. However, these rock outcrops are increasingly threatened by mining, overgrazing, and development.
A family dairy farm in the shoreland area of Lake Miltona has a liquid manure storage area that is not up to standards due to sandy soil and a high water table, increasing the likelihood of groundwater contamination. Lake Miltona is connected to the Alexandria Area Chain of Lakes and ultimately the water ends up in the Long Praire River. Groundwater impacts to the Long Prairie River have the potential to be significant.
