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.
This project will accelerate production of County Geologic Atlases (part A). An atlas is a set of geologic maps and associated databases for a county that facilitate informed management of natural resources, especially water and minerals.
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 complete a Total Maximum Daily Load Implementation Plan for the watersheds of Big Sandy and Minnewawa Lakes. This restoration plan will provide pollution reduction and watershed management strategies that are developed with input from stakeholders in the watersheds.
The goal of this project is to develop and complete the Watershed Restoration and Protection (WRAP) process and report, while also enlarging and sustaining a public participation process that encourages local ownership of water quality problems and solutions (civic engagement).
On behalf of the Metropolitan Council, Environmental Financial Group Inc. generated a matrix of water conservation programs with detailed information about the costs and benefits of the programs. Tools were also developed to allow users to calculate potential water savings, estimate program implementation costs, and test the effects of various water conservation programs and rate structures.
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 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.
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 provide fiscal resources for South St. Louis County Soil and Water Conservation District (SSLCSWCD) to participate and lead efforts to attain geomorphic data sets, dissolved oxygen assessments, culvert inventory, and civic engagement activities in three major watersheds, Nemadji River, South Lake Superior and St. Louis River. This work is currently being worked on as a part of the MPCA’s Watershed Restoration and Protection Planning efforts.
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 complete a pollutant source identification and subwatershed information report and support the development of a Draft Restoration and Protection Plan (RAPP). It will also support the devlopment of a Implementation Plan that will identify target areas for BMP implementation for bacteria reductions.
This project will complete spatial and temporal revisions , recalibration and validation of 7 watershed HSPF models. These fully functioning calibrated validated executable models will simulate hydrology, sediment (sand, silt, and clay), temperature, phosphorus, nitrogen, dissolved oxygen, biochemical oxygen demand, and algae at the 12-digit HUC subbasin scale (or finer).
This project will set water quality goals for the Minnesota portions of the watershed, recommend allocations for achieving total maximum daily loads where waters do not meet Minnesota state standards and are listed as impaired, and recommend management strategies for those Minnesota waters meeting state standards. This project also recognizes that as monitoring continues in the watershed, additional impairments may be identified.
This project will construct, calibrate, a set of HSPF watershed models covering the entire area of the Lake of the Woods drainage, including the Rainy River watershed. The consultant will produce HSPF models that can readily be used to provide information to support conventional parameter TMDLs. The consultant will clearly demonstrate that these models generate predicted output timeseries for hydrology which are consistent with available sets of observed data.
This project will determine the magnitude and sources of pollutants in Little Rock Creek and will estimate the reductions in loadings that are needed in order for the stream reaches to support cold water fish assemblages and attain water quality standards.
This project will complete a TMDL equation and report and an implementation plan for Deer Creek. The TMDL report will describe turbidity impacts to aquatic life uses of Deer Creek, correlate turbidity to other pollutants (sediment, suspended solids, etc.), describe and quantify unique turbidity/sediment stressors which include groundwater influences, legacy impacts of the watershed and stream channel, significant in-stream and near stream sources (slumps, bank erosion, etc.) and upland contributions.
This project will respond to public notice comments received after a 2nd comment opportunity and several requests for changes to the Total Maximum Daily Load (TMDL) report and petition for contested case hearings (CCH). Additional review work must be completed and if necessary, edits or updates to the TMDL and Watershed Restoration and Protection Strategy (WRAPS) reports. If there are substantial changes to both documents another public noticing will be necessary.
Four beaches along the North Shore of Lake Superior and within the Duluth Harbor have aquatic recreation impairments due to high concentrations of E. coli, a bacterial indicator of fecal contamination. The project area includes portions of the Lake Superior South and St. Louis River watersheds near Duluth. Several of the beaches are also listed as impaired for beneficial use (due to fecal bacteria) as part of the St. Louis River Area of Concern.
Ballast water - water carried in tanks on ships to help provide stability and aid steering - is likely the single greatest source for introduction of non-native and invasive aquatic species. Ballast water is collected in one body of water and discharged into another body of water, usually large distances apart. At least one new invasive species is found in the Great Lakes every year, with Lake Superior being particularly at risk. Scientists from the U.S.
This project will support Minnesota's condition monitoring strategy through the collection of water quality data on streams and rivers in the Nemadji River watershed. The Nemadji River watershed is located in southeastern Carlton County and northeastern Pine County. Water quality samples will be collected primarily during weather-related events that affect stream flow such as snowmelt and rainfalls.
This project will maximize the utility and usefulness of three HSPF models that have been constructed and calibrated for hydrology. The contractor will identify and reduce parameterization errors in the following three HSPF models: 1) Buffalo River Watershed, 2 ) Thief River Watershed, 3) Bois de Sioux-Mustinka Watersheds. This will result, not only in a better hydrology calibration, but will also improve each of the models’ ability to more accurately estimate sediment and pollutant loads and concentrations.
The goal of this project is to construct, calibrate, and validate three HSPF watershed models. The project will result in HSPF models that can readily be used to provide information to support conventional parameter TMDLs. The models are expected to generate predicted output timeseries for hydrology, sediment, nutrients, and dissolved oxygen which are consistent with available sets of observed data.
The goal of this project is to construct, calibrate, and validate five Hydrologic Simulation Program FORTRAN (HSPF) watershed models. The outcome will be HSPF models that can readily be used to provide information to support conventional parameter TMDLs. These models will generate predicted output timeseries for hydrology, sediment, nutrients, and dissolved oxygen which are consistent with available sets of observed data.
The goal of this project is to supplement and refine the Deer Creek Watershed TMDL Report and Implementation Plan project with detailed determinations of critical source areas and prioritization of the associated management practices, facilitated by additional meetings with local resource managers and validated with a field survey. Completed work will more fully inform the TMDL report and TMDL implementation plan on critical source areas of sediment and quantify those sources.
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.
This project will support construction of three watershed framework models built using the Hydrologic Simulation Program FORTRAN (HSPF). These executable models will simulate hydrology at the subbasin scale. An HSPF model will be built for each of these major watersheds: Crow Wing River, Redeye River, and Long Prairie River.
This project will finalize HSPF watershed model construction and complete the calibration/validation process for the following three watersheds: North Fork Crow River, South Fork Crow River, and Sauk River.
This project will complete the development of two watershed HSPF models for the Mustinka River and Bois de Sioux River watersheds. These calibrated and validated executable models will simulate hydrology at the 12-digit HUC subbasin scale.
This project will continue HSPF watershed model construction beyond the initial framework development. The consultant will add representation of point source discharges to the model. The consultant will also compile flow data for the purposes of calibration and validation. Finally, an initial hydrologic calibration will be performed and submitted for approval.
The goal of this project is to extend the existing HSPF models through 2012 in the Chippewa Watershed (07020005) and Hawk-Yellow Medicine Watershed (07020004) to incorporate recent monitoring data to support current MPCA business needs and sediment source investigations.
This project will complete spatial and temporal revisions of 6 Hydrologic Simulation Program FORTRAN (HSPF) models, the recalibration and validation of 7 watershed HSPF models, and the revision of the drainage network and point source representation of the Pomme de Terre HSPF model.