There are 3 million acres of peatland forests in Minnesota. This proposal will identify management actions that maximize ecosystem benefits of peatland forests, including wildlife, water, timber, and native plants.
Provide professional development workshops at three Greater Minnesota locations for 60 teachers to use phenology education curriculum and community science resources, reaching >7,000 students in the first three years.
The study will assess existing phosphorus data records and create a model to explain phosphorus loading into the Red River of the North. Studies have found that the majority of nutrient loading in the stream located in agricultural areas occurs with sediment loading since nutrients are typically bound to sediment particles.
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.
This project contributed to the goals of the MN Prairie Conservation Plan by protecting 698 acres of native prairie/wetland/savanna; restoring 698 acres prairie/wetland; and enhancing 18,839 acres grassland/savanna. When combined with Phases 1-4 of the Prairie Recovery Program we have cumulatively protected 6,475 acres, enhanced 114,595 acres and restored 1,452 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.
This project contributed to the goals of the MN Prairie Conservation Plan by protecting 207 acres of native prairie/wetland/savanna; restoring 353 acres of prairie/wetland; and enhancing 16,377 acres of grassland/savanna. When combined with Phases 1-8 of the Prairie Recovery Program we have cumulatively protected 7,941 acres, enhanced 171,191 acres and restored 2,389 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.
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 539 acres of prairie/wetland/savanna habitat; restoring 151 acres prairie/grassland; and enhancing 24,604 acres grassland/savanna. We will continue to implement subsequent Phases toward meeting the conservation goals described in the MN Prairie Conservation Plan.
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.
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.
This project will collect real-time parameter data for specific conductance, water temperature, pH, dissolved oxygen, turbidity and stream flow at the United States geological Survey (USGS) gaging stations located at Fargo, ND and Grand Forks, ND on the Red River of the North; and publish the data both on the USGS NWIS website and in the USGS Annual Report.
We will characterize environmental drivers contributing to the decline of wild rice using lake sediment cores to reconstruct historical wild rice abundance in relation to lake and watershed stressors.
This is a multi-governmental project funded by the Minnesota Pollution Control Agency, the United States Geological Survey, North Dakota Department of Health, the Cities of Fargo, Moorhead, Grand Forks, and East Grand Forks to monitor river flow and condition parameters to gain an improved understanding of the nature of the chemical and physical attributes of the Red River of the North.
The Red Lake Watershed District will collect water chemistry samples, field measurements, and photos at water quality stations in the Thief River Watershed that have been prioritized for Intensive Watershed Monitoring. This sampling effort will allow for an unbiased assessment of stream conditions for aquatic life and aquatic recreation. Eleven stream monitoring stations have been selected for this monitoring effort. Sampling will be conducted during the years 2022 and 2023 so that data is available for assessment in 2024.
This project will support water quality monitoring and data analysis in nine major watersheds (8-digit Hydrologic Unit Codes) of the Lower Red River Basin. The monitoring will assist in providing water chemistry data needed to calculate annual pollutant loads for the Major Watershed Load Monitoring Program (MWLMP) and provide short term data sets of select parameters to other MPCA programs.
This project will provide land and water managers in the Red River Basin with data and online tools to prioritize actions on the landscape that achieve water quality objectives identified in local and state plans. This will help identify strategically important locations for implementing erosion control and water management practices. Standardized watershed-based data products will be integrated into a web-based planning tool which will be added to the Red River Basin Decision Information Network (RRBDIN) being developed as part of the Red River Watershed Feasibility Study.
The goal of this project is to development a Total Maximum Daily Load (TMDL) study that addresses all of the non-mercury-related impaired reaches along the Red River of the North (RRN). The TMDL study will provide an analytical and strategic foundation for recommending restoration strategies for impaired waters. This phase of the project will also include civic engagement efforts by providing water quality framework and stakeholder activities for civic/citizen engagement and communication.
This project is for Minnesota Legislative Clean Water Fund funding to engage citizens in local watershed monitoring, to work with regional partners to promote understanding and protection of watersheds, and to organize and facilitate gathering of scientific data all for the benefit of water quality in the Red River Basin.
This project is for Minnesota Legislative Clean Water Fund funding to engage citizens in local watershed monitoring, to work with regional partners to promote understanding and protection of watersheds, and to organize and facilitate gathering of scientific data all for the benefit of water quality in the Red River Basin.
The International Water Institute (IWI) will monitor 42 sites (3 basin, 12 major watershed, and 27 subwatershed) in the Red River and Upper Mississippi River Basins intensively during the contract period. There will also be 5 sites in the Red River Basin where mercury samples will be collected and sent to Minnesota Department of Health for analysis. The IWI will collect water samples across the range of flow conditions targeting sample collection at times of moderate to high flow.
This project will develop an effective transferable model to engage and educate watershed residents, stakeholders and others to better understand and protect watershed ecostystems through environmental monitoring, training, and formal and informal education programs in their local watershed. The project will build on the foundation of the existing Red River Basin River Watch program by strengthening three main activity areas: 1) curriculum integration and teacher training, 2) youth leadership and civic engagement, and 3) applied research collaboration and watershed science skills building.
The Red Lake Watershed District will create an inspection database for 103E ditches under their drainage authority. The district will acquire a database software solution to conduct field inspections and to track ditch maintenance projects and use the software to facilitate compliance with state statutes. The project will also develop a process for completing the annual inspection and reporting requirements under Statue 103E.
This project will monitor nine locations in the major watersheds (8-digit Hydrologic Unit Codes) of the Lower Red River Basin. The stream outlet monitoring will provide the water chemistry data needed to calculate annual pollutant loads. Staff from the Red River Watershed Management Board (RRWMB) will conduct the sampling, initially manage the data and provide the data to the Minnesota Pollution Control Agency (MPCA) for load calculations and import into the STORET data system.
The goal of this project is to extend, calibrate, and validate the existing Hydrological Simulation Program – FORTRAN (HSPF) watershed models in the Red Lake River, Thief River, Clearwater River and Red Lake watersheds.
International Water Institute (IWI) staff will monitor 24 sites in the Bois de Sioux, Mustinka (2 sites), Buffalo (8 sites), Red Lake (4 sites), Sandhill (3 sites), Thief (2 sites), and Tamarac River (3 sites) Watersheds intensively over a 2 year period in an attempt to collect 25 samples per year at each site. If conditions allow for the collection of all planned samples, 1200 stream samples will be collected over the time period. Monitoring will include field measurements, observations, and at least three photographs during each site visit.
