Current Magnitude and Mechanisms of Groundwater Discharge in the Arctic: Case Study from Alaska

Natasha T. Dimova; Adina Paytan; John D. Kessler; Katy J. Sparrow; Fenix Garcia-Tigreros Kodovska; Alanna L. Lecher; Joseph Murray; Slawomir M. Tulaczyk

doi:10.1021/acs.est.5b02215

Current Magnitude and Mechanisms of Groundwater Discharge in the Arctic: Case Study from Alaska

Natasha T. Dimova^*, Adina Paytan, John D. Kessler, Katy J. Sparrow, Fenix Garcia-Tigreros Kodovska, Alanna L. Lecher, Joseph Murray, Slawomir M. Tulaczyk

^*Corresponding author for this work

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

Abstract

To better understand groundwater-surface water dynamics in high latitude areas, we conducted a field study at three sites in Alaska with varying permafrost coverage. The natural groundwater tracer (222Rn, radon) was used to evaluate groundwater discharge, and electrical resistivity tomography (ERT) was used to examine subsurface mixing dynamics. Different controls govern groundwater discharge at these sites. In areas with sporadic permafrost (Kasitsna Bay), the major driver of submarine groundwater discharge is tidal pumping, due to the large tidal oscillations, whereas at Point Barrow, a site with continuous permafrost and small tidal amplitudes, fluxes are mostly affected by seasonal permafrost thawing. Extended areas of low resistivity in the subsurface alongshore combined with high radon in surface water suggests that groundwater-surface water interactions might enhance heat transport into deeper permafrost layers promoting permafrost thawing, thereby enhancing groundwater discharge.

Original language	American English
Pages (from-to)	12036-12043
Number of pages	8
Journal	Environmental Science and Technology
Volume	49
Issue number	20
Early online date	Oct 6 2015
DOIs	https://doi.org/10.1021/acs.est.5b02215
State	Published - Oct 20 2015
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2015 American Chemical Society.

ASJC Scopus Subject Areas

General Chemistry
Environmental Chemistry

Keywords

Alaska
Bays
Groundwater/analysis
Hydrology/methods
Permafrost
Radon/analysis
Water Movements

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10.1021/acs.est.5b02215

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title = "Current Magnitude and Mechanisms of Groundwater Discharge in the Arctic: Case Study from Alaska",

abstract = "To better understand groundwater-surface water dynamics in high latitude areas, we conducted a field study at three sites in Alaska with varying permafrost coverage. The natural groundwater tracer (222Rn, radon) was used to evaluate groundwater discharge, and electrical resistivity tomography (ERT) was used to examine subsurface mixing dynamics. Different controls govern groundwater discharge at these sites. In areas with sporadic permafrost (Kasitsna Bay), the major driver of submarine groundwater discharge is tidal pumping, due to the large tidal oscillations, whereas at Point Barrow, a site with continuous permafrost and small tidal amplitudes, fluxes are mostly affected by seasonal permafrost thawing. Extended areas of low resistivity in the subsurface alongshore combined with high radon in surface water suggests that groundwater-surface water interactions might enhance heat transport into deeper permafrost layers promoting permafrost thawing, thereby enhancing groundwater discharge.",

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AU - Paytan, Adina

AU - Kessler, John D.

AU - Sparrow, Katy J.

AU - Garcia-Tigreros Kodovska, Fenix

AU - Lecher, Alanna L.

AU - Murray, Joseph

AU - Tulaczyk, Slawomir M.

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AB - To better understand groundwater-surface water dynamics in high latitude areas, we conducted a field study at three sites in Alaska with varying permafrost coverage. The natural groundwater tracer (222Rn, radon) was used to evaluate groundwater discharge, and electrical resistivity tomography (ERT) was used to examine subsurface mixing dynamics. Different controls govern groundwater discharge at these sites. In areas with sporadic permafrost (Kasitsna Bay), the major driver of submarine groundwater discharge is tidal pumping, due to the large tidal oscillations, whereas at Point Barrow, a site with continuous permafrost and small tidal amplitudes, fluxes are mostly affected by seasonal permafrost thawing. Extended areas of low resistivity in the subsurface alongshore combined with high radon in surface water suggests that groundwater-surface water interactions might enhance heat transport into deeper permafrost layers promoting permafrost thawing, thereby enhancing groundwater discharge.

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KW - Water Movements

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Current Magnitude and Mechanisms of Groundwater Discharge in the Arctic: Case Study from Alaska

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

Access to Document

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