This project will collect intermediate watershed load monitoring data on the Bigfork River which is critical to the identification of stressors and assist in defining areas of concern within the Bigfork Watershed and its greater Rainy River Watershed. Itasca County SWCD will closely collaborate with Koochiching SWCD and MPCA on this project.
This project involves the water quality monitoring of, and data analysis for four major watersheds (8-digit Hydrologic Unit Codes) in the Rainy River Basin. This monitoring will assist in providing the water chemistry data needed to calculate annual pollutant loads for the Major Watershed Pollutant Load Monitoring Network (MWPLMN) and provide short term data sets of select parameters to other Agency programs.
The project goal is to assist the Minnesota Pollution Control Agency (MPCA) with meeting the objectives of the Watershed Pollutant Load Monitoring Network (WPLMN). This will be accomplished by providing assistance in 2016 through 2019 to collect water samples, field data, and observations for the Big Fork River near Bigfork at MN6 in Itasca County, and the Big Fork River near Craigsville at MN6 in Koochiching County.
The Koochiching County SWCD staff will collect water chemistry and field parameters at specific times to determine amount of contaminant load into each stream. These sites will coincide with locations where stream flow data is also being collected. This project will focus on watershed load monitoring in both the Big Fork and Little Fork River watersheds.
This project will include analysis of existing and newly collected water quality data to verify the impairments on the currently listed reaches and to determine the status of the remaining river reaches as being either impaired or currently meeting standards. Stakeholder involvement and public participation will be a focus throughout the Watershed Approach Project. The project provides an opportunity to assess and leverage the capacity for the local community to engage in the process of watershed management and to adopt protection and restoration practices.
The goal of this project is to conduct water chemistry monitoring at four subwatershed sites and two basin sites in 2016 and 2017; and six subwatershed sites and three basin sites in 2018-2019 based on flow conditions, targeting runoff events using protocols defined in the Watershed Pollutant Load Monitoring Network (WPLMN) Standard Operating Procedures and Guidance. The data collected will be submitted to the Minnesota Pollution Control Agency (MPCA) and used in the FLUX32 model for calculating pollutant loads.
This project will meet the following goals: develop, implement, and evaluate the impacts civic engagement outcomes for the Rainy River Headwaters and the Cloquet watersheds; create a citizen understanding of the Watershed Restoration & Protection Strategy (WRAPS) process and the role that citizens, lake associations, institutions of higher education, and other stakeholders can play in attaining water quality restoration and protection; provide opportunities for citizens and stakeholders to assist local partners and state agencies in developing priorities for projects to accomplish resto
The purpose of this project is to improve understanding of primary productivity in the Red River and the diversity and population structure of the algal communities occurring along the river system. This will be accomplished through taxonomic identification of periphyton and phytoplankton assemblages necessary for characterizing responses to nutrient gradients along the Red River of the North.
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 2016, 2017, 2018 and 2019. There will also be 5 sites in the Red River Basin where mercury samples will be collected in 2016 and 2017 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.