A New Thermal Categorization of Ice-Covered Lakes

Bernard Yang; Mathew G. Wells; Bailey C. McMeans; Hilary A. Dugan; James A. Rusak; Gesa A. Weyhenmeyer; Jennifer A. Brentrup; Allison R. Hrycik; Alo Laas; Rachel M. Pilla; Jay A. Austin; Paul J. Blanchfield; Cayelan C. Carey; Matthew M. Guzzo; Noah R. Lottig; Murray D. MacKay; Trevor A. Middel; Don C. Pierson; Junbo Wang; Joelle D. Young

doi:10.1029/2020GL091374

A New Thermal Categorization of Ice-Covered Lakes

Bernard Yang, Mathew G. Wells, Bailey C. McMeans, Hilary A. Dugan, James A. Rusak, Gesa A. Weyhenmeyer, Jennifer A. Brentrup, Allison R. Hrycik, Alo Laas, Rachel M. Pilla, Jay A. Austin, Paul J. Blanchfield, Cayelan C. Carey, Matthew M. Guzzo, Noah R. Lottig, Murray D. MacKay, Trevor A. Middel, Don C. Pierson, Junbo Wang, Joelle D. Young

Physics & Astronomy (Duluth)

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

32 Scopus citations

Abstract

Lakes are traditionally classified based on their thermal regime and trophic status. While this classification adequately captures many lakes, it is not sufficient to understand seasonally ice-covered lakes, the most common lake type on Earth. We describe the inverse thermal stratification in 19 highly varying lakes and derive a model that predicts the temperature profile as a function of wind stress, area, and depth. The results suggest an additional subdivision of seasonally ice-covered lakes to differentiate underice stratification. When ice forms in smaller and deeper lakes, inverse stratification will form with a thin buoyant layer of cold water (near 0°C) below the ice, which remains above a deeper 4°C layer. In contrast, the entire water column can cool to ∼0°C in larger and shallower lakes. We suggest these alternative conditions for dimictic lakes be termed “cryostratified” and “cryomictic.”.

Original language	English (US)
Article number	e2020GL091374
Journal	Geophysical Research Letters
Volume	48
Issue number	3
DOIs	https://doi.org/10.1029/2020GL091374
State	Published - Feb 16 2021

Bibliographical note

Publisher Copyright:
© 2020. American Geophysical Union. All Rights Reserved.

Keywords

ice
stratification
winter limnology

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Yang, B., Wells, M. G., McMeans, B. C., Dugan, H. A., Rusak, J. A., Weyhenmeyer, G. A., Brentrup, J. A., Hrycik, A. R., Laas, A., Pilla, R. M., Austin, J. A., Blanchfield, P. J., Carey, C. C., Guzzo, M. M., Lottig, N. R., MacKay, M. D., Middel, T. A., Pierson, D. C., Wang, J., & Young, J. D. (2021). A New Thermal Categorization of Ice-Covered Lakes. Geophysical Research Letters, 48(3), Article e2020GL091374. https://doi.org/10.1029/2020GL091374

Yang, B, Wells, MG, McMeans, BC, Dugan, HA, Rusak, JA, Weyhenmeyer, GA, Brentrup, JA, Hrycik, AR, Laas, A, Pilla, RM, Austin, JA, Blanchfield, PJ, Carey, CC, Guzzo, MM, Lottig, NR, MacKay, MD, Middel, TA, Pierson, DC, Wang, J & Young, JD 2021, 'A New Thermal Categorization of Ice-Covered Lakes', Geophysical Research Letters, vol. 48, no. 3, e2020GL091374. https://doi.org/10.1029/2020GL091374

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abstract = "Lakes are traditionally classified based on their thermal regime and trophic status. While this classification adequately captures many lakes, it is not sufficient to understand seasonally ice-covered lakes, the most common lake type on Earth. We describe the inverse thermal stratification in 19 highly varying lakes and derive a model that predicts the temperature profile as a function of wind stress, area, and depth. The results suggest an additional subdivision of seasonally ice-covered lakes to differentiate underice stratification. When ice forms in smaller and deeper lakes, inverse stratification will form with a thin buoyant layer of cold water (near 0°C) below the ice, which remains above a deeper 4°C layer. In contrast, the entire water column can cool to ∼0°C in larger and shallower lakes. We suggest these alternative conditions for dimictic lakes be termed “cryostratified” and “cryomictic.”.",

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author = "Bernard Yang and Wells, {Mathew G.} and McMeans, {Bailey C.} and Dugan, {Hilary A.} and Rusak, {James A.} and Weyhenmeyer, {Gesa A.} and Brentrup, {Jennifer A.} and Hrycik, {Allison R.} and Alo Laas and Pilla, {Rachel M.} and Austin, {Jay A.} and Blanchfield, {Paul J.} and Carey, {Cayelan C.} and Guzzo, {Matthew M.} and Lottig, {Noah R.} and MacKay, {Murray D.} and Middel, {Trevor A.} and Pierson, {Don C.} and Junbo Wang and Young, {Joelle D.}",

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AU - Yang, Bernard

AU - Wells, Mathew G.

AU - McMeans, Bailey C.

AU - Dugan, Hilary A.

AU - Rusak, James A.

AU - Weyhenmeyer, Gesa A.

AU - Brentrup, Jennifer A.

AU - Hrycik, Allison R.

AU - Laas, Alo

AU - Pilla, Rachel M.

AU - Austin, Jay A.

AU - Blanchfield, Paul J.

AU - Carey, Cayelan C.

AU - Guzzo, Matthew M.

AU - Lottig, Noah R.

AU - MacKay, Murray D.

AU - Middel, Trevor A.

AU - Pierson, Don C.

AU - Wang, Junbo

AU - Young, Joelle D.

PY - 2021/2/16

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N2 - Lakes are traditionally classified based on their thermal regime and trophic status. While this classification adequately captures many lakes, it is not sufficient to understand seasonally ice-covered lakes, the most common lake type on Earth. We describe the inverse thermal stratification in 19 highly varying lakes and derive a model that predicts the temperature profile as a function of wind stress, area, and depth. The results suggest an additional subdivision of seasonally ice-covered lakes to differentiate underice stratification. When ice forms in smaller and deeper lakes, inverse stratification will form with a thin buoyant layer of cold water (near 0°C) below the ice, which remains above a deeper 4°C layer. In contrast, the entire water column can cool to ∼0°C in larger and shallower lakes. We suggest these alternative conditions for dimictic lakes be termed “cryostratified” and “cryomictic.”.

AB - Lakes are traditionally classified based on their thermal regime and trophic status. While this classification adequately captures many lakes, it is not sufficient to understand seasonally ice-covered lakes, the most common lake type on Earth. We describe the inverse thermal stratification in 19 highly varying lakes and derive a model that predicts the temperature profile as a function of wind stress, area, and depth. The results suggest an additional subdivision of seasonally ice-covered lakes to differentiate underice stratification. When ice forms in smaller and deeper lakes, inverse stratification will form with a thin buoyant layer of cold water (near 0°C) below the ice, which remains above a deeper 4°C layer. In contrast, the entire water column can cool to ∼0°C in larger and shallower lakes. We suggest these alternative conditions for dimictic lakes be termed “cryostratified” and “cryomictic.”.

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KW - winter limnology

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A New Thermal Categorization of Ice-Covered Lakes

Abstract

Bibliographical note

Keywords

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