Extreme warming and regime shift toward amplified variability in a far northern lake

Mean annual air temperatures in the High Arctic are rising rapidly, with extreme warming events becoming increasingly common. Little is known, however, about the consequences of such events on the ice‐capped lakes that occur abundantly across this region. Here, we compared 2 years of high‐frequency...

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Bibliographic Details
Published in:Limnology and Oceanography
Main Authors: Bégin, Paschale Noël, Tanabe, Yukiko, Vincent, Warwick F., Kumagai, Michio, Sarrazin, Denis, Culley, Alexander, Paquette, Michel, Uchida, Masaki
Format: Other/Unknown Material
Language:English
Published: Wiley 2020
Subjects:
Climate change
Polar
Oxygen
Winter limnology
Ice cover
Climat > Changements
Inlandsis
Limnologie
Lacs sous-glaciaires
Arctic
Nunavut
Online Access:https://hdl.handle.net/20.500.11794/39977
https://doi.org/10.1002/lno.11546
Description
Summary:Mean annual air temperatures in the High Arctic are rising rapidly, with extreme warming events becoming increasingly common. Little is known, however, about the consequences of such events on the ice‐capped lakes that occur abundantly across this region. Here, we compared 2 years of high‐frequency monitoring data in Ward Hunt Lake in the Canadian High Arctic. One of the years included a period of anomalously warm conditions that allowed us to address the question of how loss of multi‐year ice cover affects the limnological properties of polar lakes. A mooring installed at the deepest point of the lake (9.7 m) recorded temperature, oxygen, chlorophyll a (Chl a ) fluorescence, and underwater irradiance from July 2016 to July 2018, and an automated camera documented changes in ice cover. The complete loss of ice cover in summer 2016 resulted in full wind exposure and complete mixing of the water column. This mixing caused ventilation of lake water heat to the atmosphere and 4°C lower water temperatures than under ice‐covered conditions. There were also high values of Chl a fluorescence, elevated turbidity levels and large oxygen fluctuations throughout fall and winter. During the subsequent summer, the lake retained its ice cover and the water column remained stratified, with lower Chl a fluorescence and anoxic bottom waters. Extreme warming events are likely to shift polar lakes that were formerly capped by continuous thick ice to a regime of irregular ice loss and unstable limnological conditions that vary greatly from year to year.

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