Near‐bed stratification controls bottom hypoxia in ice‐covered alpine lakes

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Ressource 1Download: Limnology Oceanography - 2023 - Perga.pdf (2773.83 [Ko])
State: Public
Version: Final published version
License: CC BY-NC 4.0
Serval ID
serval:BIB_55B1F503D7CA
Type
Article: article from journal or magazin.
Collection
Publications
Institution
Title
Near‐bed stratification controls bottom hypoxia in ice‐covered alpine lakes
Journal
Limnology and Oceanography
Author(s)
Perga Marie-Elodie, Minaudo Camille, Doda Tomy, Arthaud Florent, Beria Harsh, Chmiel Hannah E., Escoffier Nicolas, Lambert Thibault, Napolleoni Raphaelle, Obrador Biel, Perolo Pascal, Rüegg Janine, Ulloa Hugo, Bouffard Damien
ISSN
0024-3590
1939-5590
Publication state
Published
Issued date
06/2023
Peer-reviewed
Oui
Volume
68
Number
6
Pages
1232-1246
Language
english
Abstract
In ice-covered lakes, near-bottom oxygen concentration decreases for most of the wintertime, sometimes down to the point that bottom waters become hypoxic. Studies insofar have reached divergent conclusions on whether climate change limits or reinforces the extent and duration of hypoxia under ice, raising the need for a comprehensive understanding of the drivers of the dissolved oxygen (DO) dynamics under lake ice. Using high-temporal resolution time series of DO concentration and temperature across 14 mountain lakes, we showed that the duration of bottom hypoxia under ice varies from 0 to 236 d within lakes and among years. The variability of hypoxia duration was primarily explained by changes in the decay rate of DO above the lake bottom rather than by differences in DO concentration at the ice onset or in the ice-cover duration. We observed that the DO decay rate was primarily linked to physical controls (i.e., deep-water warming) rather than biogeochemical drivers (i.e., proxies for lake or catchment productivity). Using a simple numerical model, we provided a proof-of-concept that the near-bed stratification can be the mechanism tying the DO decay rate to the sediment heat release under the ice. We ultimately showed that the DO decay rate and hypoxia duration are driven by the summer light climate, with faster oxygen decline found under the ice of clearer cryostratified alpine lakes. We derived a framework theorizing how the hypoxia duration might change under the ice of alpine lakes in a warmer climate.
Keywords
Aquatic Science, Oceanography
Web of science
Open Access
Yes
Create date
01/09/2023 11:26
Last modification date
30/01/2024 7:19
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