Further Development of a Specific Conductivity Approach to Measure Groundwater Discharge Area within Lakes

Stefan M. Bischof; Brian R. Herwig; Stephen D. Sebestyen; Mark A. Hanson; Kyle D. Zimmer; James B. Cotner; Timothy J. Kroeger

doi:10.1111/1752-1688.12730

Further Development of a Specific Conductivity Approach to Measure Groundwater Discharge Area within Lakes

Stefan M. Bischof, Brian R. Herwig, Stephen D. Sebestyen, Mark A. Hanson, Kyle D. Zimmer, James B. Cotner, Timothy J. Kroeger

Ecology, Evolution and Behavior

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Groundwater exchanges with most lakes are rarely quantified because there are many technical challenges to quantification. We investigated a lakebed mapping approach to infer the relative areas of groundwater exchange in 12 prairie shallow lakes and five Laurentian mixed forest shallow lakes in Minnesota, USA in 2011. We used a relatively common approach (seepage meters) to provide baseline information on the magnitude and direction of flow at four locations in each lake. To expand from point measurements to the whole-lake scale, we explored use of specific conductivity as a cheaper and more time efficient proxy for groundwater discharge to lakes. We validated the approach at near shore stations in each lake where seepage meter measurements and specific conductivity surveys overlapped. Specific conductivity surveys provided a similar assessment of groundwater discharge compared to seepage meters for 50% of the lake-sampling period combinations. The lakebed mapping approach, when validated for a lake with a limited number of seepage meter (or alternative methods) measurements, offers the advantages of being more time and labor efficient over the use of a similar number of seepage meter monitoring locations; seepage meters (or piezometers, for example) are costlier in terms of equipment and labor, even for single-lake studies. We show the combined approach could provide useful baselines for understanding and mapping groundwater exchange in shallow lakes.

Original language	English (US)
Pages (from-to)	485-496
Number of pages	12
Journal	Journal of the American Water Resources Association
Volume	55
Issue number	2
DOIs	https://doi.org/10.1111/1752-1688.12730
State	Published - Apr 2019

Bibliographical note

Funding Information:
We thank the Fergus Falls and Morris Wetland Management Districts of the U.S. Fish and Wildlife Service, Minnesota DNR Parks and Trails, and Minnesota DNR Glenwood Area Wildlife Office for access and use of study sites. We thank Matthew Bischof, Markus Bischof, and Winston Allen for assistance with field work. We sincerely appreciate efforts of John Larson and Doris Nelson from the Northern Research Station (NRS) of the USDA Forest Service (Grand Rapids, Minnesota) for guidance on water chemistry analyses. Core funding for this research was provided by the Minnesota Department of Natural Resources, Minnesota Space Grant Consortium, and a Bemidji State University mini-grant. The NRS funded the contributions of SDS and NRS laboratory staff to this project as well as chemical analyses.

Publisher Copyright:
© 2019 American Water Resources Association

Keywords

groundwater
seepage meter instrumentation
shallow lakes
specific conductivity

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abstract = "Groundwater exchanges with most lakes are rarely quantified because there are many technical challenges to quantification. We investigated a lakebed mapping approach to infer the relative areas of groundwater exchange in 12 prairie shallow lakes and five Laurentian mixed forest shallow lakes in Minnesota, USA in 2011. We used a relatively common approach (seepage meters) to provide baseline information on the magnitude and direction of flow at four locations in each lake. To expand from point measurements to the whole-lake scale, we explored use of specific conductivity as a cheaper and more time efficient proxy for groundwater discharge to lakes. We validated the approach at near shore stations in each lake where seepage meter measurements and specific conductivity surveys overlapped. Specific conductivity surveys provided a similar assessment of groundwater discharge compared to seepage meters for 50% of the lake-sampling period combinations. The lakebed mapping approach, when validated for a lake with a limited number of seepage meter (or alternative methods) measurements, offers the advantages of being more time and labor efficient over the use of a similar number of seepage meter monitoring locations; seepage meters (or piezometers, for example) are costlier in terms of equipment and labor, even for single-lake studies. We show the combined approach could provide useful baselines for understanding and mapping groundwater exchange in shallow lakes.",

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Further Development of a Specific Conductivity Approach to Measure Groundwater Discharge Area within Lakes

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Bibliographical note

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