Emergence of steeply stratified permafrost thaw ponds changes zooplankton ecology in subarctic freshwaters

Climate change and associated permafrost thaw are creating new shallow waterbodies in vast regions of the circumpolar Arctic. These thaw ponds are characterized by high concentrations of colored dissolved organic matter originating from the degrading watershed, inducing a strong vertical thermal and...

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Bibliographic Details
Published in:Arctic, Antarctic, and Alpine Research
Main Authors: Maxime Wauthy, Milla Rautio
Format: Article in Journal/Newspaper
Language:English
Published: Taylor & Francis Group 2020
Subjects:
thaw ponds
zooplankton
stratification
hypoxia
top-down predation
phytoplankton
Environmental sciences
GE1-350
Ecology
QH540-549.5
Arctic
Browning
Antarctic and Alpine Research
Climate change
permafrost
Phytoplankton
Subarctic
Zooplankton
Online Access:https://doi.org/10.1080/15230430.2020.1753412
https://doaj.org/article/a69a3da20a814fffacc50fbf6014373d
Description
Summary:Climate change and associated permafrost thaw are creating new shallow waterbodies in vast regions of the circumpolar Arctic. These thaw ponds are characterized by high concentrations of colored dissolved organic matter originating from the degrading watershed, inducing a strong vertical thermal and oxygen (O2) stratification. We investigated the zooplankton community and biomass in eight subarctic thaw ponds and evaluated how zooplankton respond to this stratification. In a subset of three ponds, we further examined how other environmental variables, including essential fatty acids (EFA) concentration and phytoplankton, bacteria, and larval phantom midge Chaoborus biomass stratify and contribute to the vertical distribution of zooplankton in this increasingly common type of arctic freshwater system. The zooplankton community was extremely abundant in all ponds (up to 3,548 ind Lāˆ’1) and dominated mainly by rotifers (35ā€“93 percent of the biomass). Most zooplankton aggregated at the interface between the shallow well-oxygenated mixed surface layer and the deeper hypoxic but algal-rich stratified layer, and their distribution was affected by a combination of O2, Chaoborus, phytoplankton, and EFA that were supplied from opposite directions. Our findings show how water column stratification deeply affects the ecology of planktonic organisms in circumpolar freshwaters and indicate Arctic zooplankton species composition is expected to deeply change with the ongoing warming and browning.

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