The goal of this project is to continue and finalize Hydrologic Simulation Program FORTRAN (HSPF) watershed model construction and complete the calibration/validation process. The project will add representation of point source discharges to the model, compile flow and water quality data for the purposes of calibration and validation. The end result will be an HSPF watershed model that can readily be used to provide information to support conventional parameter TMDLs.
The goal of the project is the development of an overall strategy for reduction of turbidity/TSS, with sets of sediment reduction initiatives and actions for various sources, to address the Minnesota River Turbidity TMDL and the South Metro Mississippi River TSS TMDL.
This project will support the monitoring of two sites on the Cannon River throughout the field seasons of 2013 and 2014 during storm events and baseflow conditions to capture 25 samples per year at each site according to the WPLMN objectives. The information gathered from these samples and site visits will be compiled for reporting purposes and for use in calculating pollutant loading using the FLUX32 model.
The MPCA has identified 13 stream sites in the watershed to characterize watershed water quality. This project will supplement and complement the identification of the top 50 sites in the watershed that are contributing to water impairment and also help in identification of priority watersheds in the re-write of the watershed comprehensive plan. Water samples and field measurements will be collected at each monitoring location ranging from baseline events to high flow events.
The goal of this project is to collect data, water chemistry and field parameters, which will be paired with biological data collected by the MPCA to assess water quality conditions at seven sites along targeted reaches within the Snake River Watershed and five sites in the Two River Watershed.
The overall goal of this project is to perform water quality monitoring duties to accomplish MPCA’s SWAG monitoring efforts at the four sites listed in Section IV of this application for the Middle Minnesota River stream sites selected in Renville, Redwood and Brown counties and allow for the assessment of aquatic life and aquatic recreation use for those reaches of the minor streams.
The Zumbro River Watershed Pollutant Load Monitoring Network (WPLMN) project will continue existing efforts to calculate seasonal pollutant loads for the Root River. The Zumbro Watershed Partnership (ZWP) along with Olmsted County Environmental Services will assist the Minnesota Pollution Control Agency (MPCA) with water quality monitoring and pollutant load calculations of four sub-watershed sites. Approximately 50 grab samples per site (total of 200) between ice-out and October 31 of 2016 and 2017 will be collected along with field measurements and observations.
Peer Engineering, Inc. (Peer) will evaluate and recommend to MPCA groundwater monitoring staff prospective sites/locations for the installation of groundwater monitoring wells to evaluate contaminant/pollutant concentrations from various sources. Peer will oversee the installation of monitoring wells by retaining a state drilling contractor or preparing bid documents to retain well driller through the Department of Administration. Superfund staff will assist in the project by providing oversight of contractual requirements and provide technical assistance as needed.
The goal of this project is to use the We Are Water MN exhibit and their technical knowledge in relationship-building and storytelling to increase community capacity for sustainable watershed management in the Cannon River, Cedar River, Mississippi-Headwaters, Mississippi-Grand Rapids, Mississippi-Twin Cities, Red Lake River, Rum River and St. Louis River watersheds.
This project will use the We Are Water MN traveling exhibit and the Minnesota Humanities Center's approach to community engagement, relationship building, and storytelling, to increase community capacity for sustainable watershed management in six Minnesota watersheds.
This project will provide condition monitoring and problem investigation monitoring at the following sites.
Mississippi River: Tributaries include Bassett Creek, Cannon River, Crow River, and Minnehaha Creek.
Minnesota River: Tributaries include Eagle Creek,Riley Creek, and Valley Creek tributary to the St. Croix River
This project will develop a Final TMDL report and Implementation Plan for the Bluff Creek Watershed. The main outcomes of this project are the development of a Final TMDL Report approved by MPCA and EPA and a Final Implementation Plan approved by MPCA.
This Total Maximum Daily Load (TMDL) project will develop a TMDL Report and Implementation Plan defining the sources contributing to the impairments and outlining the steps necessary to bring Bluff Creek back to meeting water quality standards.
The goal of this project is to apply the Hydrological Simulation Program FORTRAN (HSPF) model to evaluate scenarios to support potential management actions and implementation in the watershed, construct Total Maximum Daily Load (TMDL) studies, and to develop a conceptual site model of the lakes for understanding phosphorus release.
This project will assess the ability of using cover crops as a best management practice to reduce nitrate leaching loss from corn and soybean acres. This contract provides funding for the coordination, outreach and field work to support implementation of the Cannon River Watershed Restoration and Protection Strategy (WRAPS) nitrogen strategy (cover crop application) in Rice Creek. Funding for the actual best management practice (BMP)cost-sharing has been secured via other sources.
This project is to refresh the Cannon River Watershed Hydrologic Simulation Program FORTRAN (HSPF) model. The previous model was developed for the time period of 1995-2012. This phase will extend the model to include data through 2019. All time series data will be updated through 2019, land classification zones will be restructured, hydrology calibration will be updated as needed, and final reporting including technical memo and model package.
This monitoring project includes lake and stream monitoring and encompasses all of Cass County, and surrounding counties. The project will obtain water quality data for streams; in 2009, lakeshed assessments indicated that many surface waters throughout the county were data deficient. This project will address the need for sufficient data on a county-wide basis and fulfill the State’s intensive watershed monitoring program goals by obtaining water quality data at targeted lake and stream sites.
The Villa Park Wetland Restoration Project proposes sediment removal from 6 contiguous stormwater wetland treatment cells within the Villa Park Wetland system resulting in an additional 118lbs/yr of total phosphorus(TP) removal from water entering Lake McCarrons.
The overall goal is to develop a Watershed Restoration and Protection Strategy (WRAPS) Report and Total Maximum Daily Load (TMDL) Study that will address water quality impairments and maintain or improve water quality throughout the Clearwater River watershed. The study will identify sources of pollutants to the streams and lakes, allocate pollution reduction goals, and prioritize and identify implementation strategies to maintain or improve water quality in key lakes and streams in the watershed.
This project will collect a complete Trophic Site Index (TSI) data set for Crow Wing County lakes and a complete data set for streams and rivers for the Intensive Monitoring Program (IMP). Crow Wing County, Cass County, Wadena County, Morrison County and Hubbard County are partnering to ensure that all target lakes and rivers within the Crow Wing River watershed are monitored efficiently.
This project will provide Stressor ID work and assistance for the development of a work plan for the Major Watershed Project. The Major Watershed Project will include a plan for civic engagement and outreach, with assistance from ten Local Government Units from the Crow Wing River Watershed.
This project will develop a TMDL for all impaired lakes within the Crow Wing Watershed by furthering data collection in the watershed, analysis of data, allocation calculations, and introducing outreach and stakeholder participation activities.
This project will conduct a 2017 revision of the South Fork Crow River, North Fork Crow River and Sauk River Watershed Hydrological Simulation Program FORTRAN (HSPF) models and review of the Pine River Watershed HSPF model.
This first year of the project will collect available data relevant to the TMDL development, determine the data sets best suited for the TMDL development. Gain a better understanding of the watershed and impaired lakes, and assessment of all potential sources (internal and external) of the causes of lake impairment. EOR will also review the data produced by the MPCA for the impairment assessment for each of the lakes during year 1 of the project.
The project goal is to conduct water chemistry monitoring at five subwatershed sites and two basin sites annually from 2016-2019, 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 Minnesota Pollution Control Agency (MPCA) and used in the FLUX32 model for calculating pollutant loads.
This project willl complete a final TMDL document that will be submitted to EPA for approval. Document will include Lake Osakis, Clifford Lake, Faille Lake, and Smith Lake impairments. A final technical memorandum describing the elements of the model framework and any deviations from the recommended construction methodology will be also be provided with the submission of the watershed models.
This project will construct three watershed framework models built using the Hydrologic Simulation Program FORTRAN. These executable models will simulate hydrology at the 12-digit HUC subbasin scale. An HSPF model will be built for each of the following 8-HUC watersheds: Red Lake River (09020303) and the Clearwater River (09020305).
This project will complete a comprehensive study, following a rational, step-wise process of data analysis, response modeling and comparison to the water quality standards, followed by impairment diagnosis, modeling of improvement and protection options, and development of a WRAP Report and Implementation Plan for Sunfish lake, Thompson lake, Pickerel lake, and Rogers lake.
This project covers activities necessary to complete the major watershed restoration and projection project. The major objectives this project covers include contract administration, watershed coordination, stressor ID activities, identifying priority management zones, engage watershed citizens, and the creation of watershed restoration and protection plans.
This project will finalize HSPF watershed model construction by incorporating internal phosphorus loading in modeled lakes, run a suite of implementation scenarios and generate a GenScn project containing model output. The consultant will produce HSPF watershed models that can readily be used to provide information to support conventional parameter TMDLs. The consultant will deliver all modeling files for baseline and implementation scenarios and provide a GenScn project containing model output.
This project will consist of identifying the candidate causes of biological stress and to develop and implement a public and stakeholder participation process that encourages local ownership of water quality problems and solutions. The Stressor ID process will be done using existing data, identifying data gaps, gathering new data, developing load duration curves, and refinement of the candidate causes. The civic engagement work will include compiling and reviewing existing data on community capacity and assessing that information.
This project will provide Agency staff, local partners and the citizen volunteers with a framework for building local capacity to design civic engagement and communication / outreach efforts. This will contribute to meaningful and sustained public participation in surface water protection and restoration activities throughout the watershed. MPCA staff, local partners and citizen volunteers will also be able to integrate the results of the biophysical and community assessment into strategies for improving water bodies on the MN 303d List of Impaired Waters
This project will build network and the skill set of local resource professionals to do effective civic engagement work for water restoration and protection in Southeast Minnesota. The cohort will be administered through the Southeast Minnesota Water Resources Board (SE MN WRB) which is an area wide Joint Powers Board (JPB) established to help improve and protect the water resources of the area through coordinating local water planning efforts. This JPB has successfully administered water quality grants in the past that have positively impacted the water resources of this region.
This project includes project planning, coordination, stream reconnaissance, and begins the effort towards civic engagement/outreach components of the South Fork Crow River Watershed project. Phase I will focus towards the development of project teams, identifying stakeholders, developing an initial civic engagement strategic plan and conducting limited lake and stream monitoring.
This project will construct, calibrate, and validate an HSPF watershed model for the Zumbro River watershed. The consultant will produce HSPF watershed models that can readily be used to provide information to support conventional parameter Total Maximum Daily Load (TMDLs). The consultant will clearly demonstrate that the models generate predicted output timeseries for hydrology, sediment, nutrients, and dissolved oxygen that are consistent with available sets of observed data.
This project will provide the MPCA, CCWD, and all other stakeholders the information and tools necessary to improve the water quality within Coon Creek Watershed District. The improvements will take place using targeted activities throughout the watershed to reduce the primary biological and chemical stressors. In turn, the reduction of these stressors will help to reduce overall loadings of sediment, turbidity, total phosphorus, and E. coli bacteria.