Deepwater dissolved oxygen shows little ecological memory between lake phenological seasons
Pilla, Rachel M.; Williamson, Craig E.; Overholt, Erin P.; Rose, Kevin C.; Berger, Stella Angela; Couture, Raoul-Marie; de Wit, Heleen; Granados, Ignacio; Grossart, Hans-Peter F.; Kirillin, Georgiy B.; Laas, Alo; Nejstgaard, Jens Christian; Rusak, James A.; Swinton, Mark W.; Toro, Manuel; Yao, Huaxia
Peer reviewed, Journal article
Accepted version
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Date
2023Metadata
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Abstract
Depletion of deepwater dissolved oxygen (DO) in lakes has become increasingly prevalent and severe because of many external stressors, potentially threatening human-derived ecosystem services ranging from drinking water quality to fisheries. Using year-round, high-frequency DO data from 12 dimictic lakes, we compared 3 measures of deepwater DO depletion during winter and summer: DO depletion rate, DO minimum, and hypoxia duration. Hypoxia (DO < 3 mg L−1) occurred in over half of the lakes and persisted an average of 83% longer in summer than in winter. While we found no difference in DO depletion rates between winter versus summer, these rates were significantly related to lake morphology in winter but trophic state in summer. In assessing cross-seasonal linkages, we found limited evidence for significant legacy effects in deepwater DO availability. Only fall mixing efficacy significantly responded to the previous summer’s minimum DO saturation, but it always reached moderate to high DO replenishment levels (>65%) regardless of the previous summer’s DO depletion severity. This lack of ecological memory in deepwater DO depletion across seasons suggests that deepwater DO largely resets during spring and fall mixing periods in most years in these dimictic lakes. Understanding the patterns and drivers in deepwater DO depletion in both winter and summer is a key step forward for predicting future chemical and biological consequences of seasonal DO depletion and managing lake ecosystem health, as well as the effects that climate change may have on these patterns.