Quantifying the resilience of coldwater lake habitat to climate and land use change to prioritize watershed conservation

Gretchen J.A. Hansen; Kevin E. Wehrly; Kelsey Vitense; Jake R. Walsh; Peter C. Jacobson

doi:10.1002/ecs2.4172

Quantifying the resilience of coldwater lake habitat to climate and land use change to prioritize watershed conservation

Gretchen J.A. Hansen, Kevin E. Wehrly, Kelsey Vitense, Jake R. Walsh, Peter C. Jacobson

Fisheries, Wildlife, and Conservation Biology

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

4 Scopus citations

Abstract

Managing ecological systems for resilience can increase their capacity to maintain key functions even under global change. Oxygenated coldwater (oxythermal) habitat in lakes is an important ecological resource that is threatened by both climate change and eutrophication. Here, we quantify the resilience of oxythermal habitat in over 10,000 glacial lakes in the upper Midwestern United States to climate change and watershed disturbance and classify lakes for conservation prioritization based on their current conditions and resilience. Oxythermal habitat was predicted by lake morphometry, July air temperatures, and watershed land use. Temperatures are projected to increase by mid-century, and the magnitude of warming, its effect on oxythermal habitat, and the uncertainty surrounding that effect varied among lakes. Under mid-century climate conditions, the number of lakes containing suitable coldwater habitat was predicted to decline by 67%, while the number of lakes with unsuitable habitat was predicted to increase by over 200%. Lakes varied in the amount of temperature increase that they could sustain without a resultant change in habitat tier (i.e., their climate resilience). Median climate resilience was 4.3°C, with some lakes capable of remaining in their habitat tier even with temperature increases up to 14°C. Changing watershed land use was predicted to influence oxythermal habitat in 24% of lakes (n = 2391). We used the magnitude of increase in watershed development that a lake could sustain while remaining in its current habitat class as a measure of its resilience to watershed disturbance. Conversely, decreased watershed development may improve oxythermal habitat conditions and push a lake into an improved condition, and this value represented a lake's restoration potential. We classified lakes into seven management classes based on their current oxythermal habitat conditions and the resilience of oxythermal habitat to climate and watershed disturbance. To facilitate management on individual lakes, we also assessed the vulnerability and resilience of individual lakes and the uncertainty surrounding these estimates. By quantifying the resilience of lakes and how it is influenced by local action across a multistate region, we can prioritize conservation action across multiple scales to maintain the critical habitat and ecosystem function of glacial lakes.

Original language	English (US)
Article number	e4172
Journal	Ecosphere
Volume	13
Issue number	7
DOIs	https://doi.org/10.1002/ecs2.4172
State	Published - Jul 2022

Bibliographical note

Funding Information:
information United States Fish and Wildlife Service We are grateful to the United States Fish and Wildlife Service through the Midwest Glacial Lake Partnership (MGLP) for funding, supporting the initiation of this work. We also thank the MGLP science and data team: Jim Breck, Zach Feiner, Katie Hein, Joe Nohner, Heidi Rantala, and Jordan Read for their advice and input on this project. Thanks to Heather Baird, Derek Bahr, and Martin Jennings for their work identifying and protecting priority watersheds in Minnesota and for critically assessing our science as it relates to conservation policy. Thanks also to Derek Bahr and Beth Holbrook for help calculating TDO3 from profile data. Finally, thanks to Steve Carpenter and two anonymous reviewers for helpful comments on an earlier version of this manuscript.

Funding Information:
We are grateful to the United States Fish and Wildlife Service through the Midwest Glacial Lake Partnership (MGLP) for funding, supporting the initiation of this work. We also thank the MGLP science and data team: Jim Breck, Zach Feiner, Katie Hein, Joe Nohner, Heidi Rantala, and Jordan Read for their advice and input on this project. Thanks to Heather Baird, Derek Bahr, and Martin Jennings for their work identifying and protecting priority watersheds in Minnesota and for critically assessing our science as it relates to conservation policy. Thanks also to Derek Bahr and Beth Holbrook for help calculating TDO from profile data. Finally, thanks to Steve Carpenter and two anonymous reviewers for helpful comments on an earlier version of this manuscript. 3

Publisher Copyright:
© 2022 The Authors. Ecosphere published by Wiley Periodicals LLC on behalf of The Ecological Society of America.

Keywords

climate change
eutrophication
lake
land use
oxygen
oxythermal habitat
resilience
temperature
watershed

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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abstract = "Managing ecological systems for resilience can increase their capacity to maintain key functions even under global change. Oxygenated coldwater (oxythermal) habitat in lakes is an important ecological resource that is threatened by both climate change and eutrophication. Here, we quantify the resilience of oxythermal habitat in over 10,000 glacial lakes in the upper Midwestern United States to climate change and watershed disturbance and classify lakes for conservation prioritization based on their current conditions and resilience. Oxythermal habitat was predicted by lake morphometry, July air temperatures, and watershed land use. Temperatures are projected to increase by mid-century, and the magnitude of warming, its effect on oxythermal habitat, and the uncertainty surrounding that effect varied among lakes. Under mid-century climate conditions, the number of lakes containing suitable coldwater habitat was predicted to decline by 67%, while the number of lakes with unsuitable habitat was predicted to increase by over 200%. Lakes varied in the amount of temperature increase that they could sustain without a resultant change in habitat tier (i.e., their climate resilience). Median climate resilience was 4.3°C, with some lakes capable of remaining in their habitat tier even with temperature increases up to 14°C. Changing watershed land use was predicted to influence oxythermal habitat in 24% of lakes (n = 2391). We used the magnitude of increase in watershed development that a lake could sustain while remaining in its current habitat class as a measure of its resilience to watershed disturbance. Conversely, decreased watershed development may improve oxythermal habitat conditions and push a lake into an improved condition, and this value represented a lake's restoration potential. We classified lakes into seven management classes based on their current oxythermal habitat conditions and the resilience of oxythermal habitat to climate and watershed disturbance. To facilitate management on individual lakes, we also assessed the vulnerability and resilience of individual lakes and the uncertainty surrounding these estimates. By quantifying the resilience of lakes and how it is influenced by local action across a multistate region, we can prioritize conservation action across multiple scales to maintain the critical habitat and ecosystem function of glacial lakes.",

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note = "Funding Information: information United States Fish and Wildlife Service We are grateful to the United States Fish and Wildlife Service through the Midwest Glacial Lake Partnership (MGLP) for funding, supporting the initiation of this work. We also thank the MGLP science and data team: Jim Breck, Zach Feiner, Katie Hein, Joe Nohner, Heidi Rantala, and Jordan Read for their advice and input on this project. Thanks to Heather Baird, Derek Bahr, and Martin Jennings for their work identifying and protecting priority watersheds in Minnesota and for critically assessing our science as it relates to conservation policy. Thanks also to Derek Bahr and Beth Holbrook for help calculating TDO3 from profile data. Finally, thanks to Steve Carpenter and two anonymous reviewers for helpful comments on an earlier version of this manuscript. Funding Information: We are grateful to the United States Fish and Wildlife Service through the Midwest Glacial Lake Partnership (MGLP) for funding, supporting the initiation of this work. We also thank the MGLP science and data team: Jim Breck, Zach Feiner, Katie Hein, Joe Nohner, Heidi Rantala, and Jordan Read for their advice and input on this project. Thanks to Heather Baird, Derek Bahr, and Martin Jennings for their work identifying and protecting priority watersheds in Minnesota and for critically assessing our science as it relates to conservation policy. Thanks also to Derek Bahr and Beth Holbrook for help calculating TDO from profile data. Finally, thanks to Steve Carpenter and two anonymous reviewers for helpful comments on an earlier version of this manuscript. 3 Publisher Copyright: {\textcopyright} 2022 The Authors. Ecosphere published by Wiley Periodicals LLC on behalf of The Ecological Society of America.",

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N2 - Managing ecological systems for resilience can increase their capacity to maintain key functions even under global change. Oxygenated coldwater (oxythermal) habitat in lakes is an important ecological resource that is threatened by both climate change and eutrophication. Here, we quantify the resilience of oxythermal habitat in over 10,000 glacial lakes in the upper Midwestern United States to climate change and watershed disturbance and classify lakes for conservation prioritization based on their current conditions and resilience. Oxythermal habitat was predicted by lake morphometry, July air temperatures, and watershed land use. Temperatures are projected to increase by mid-century, and the magnitude of warming, its effect on oxythermal habitat, and the uncertainty surrounding that effect varied among lakes. Under mid-century climate conditions, the number of lakes containing suitable coldwater habitat was predicted to decline by 67%, while the number of lakes with unsuitable habitat was predicted to increase by over 200%. Lakes varied in the amount of temperature increase that they could sustain without a resultant change in habitat tier (i.e., their climate resilience). Median climate resilience was 4.3°C, with some lakes capable of remaining in their habitat tier even with temperature increases up to 14°C. Changing watershed land use was predicted to influence oxythermal habitat in 24% of lakes (n = 2391). We used the magnitude of increase in watershed development that a lake could sustain while remaining in its current habitat class as a measure of its resilience to watershed disturbance. Conversely, decreased watershed development may improve oxythermal habitat conditions and push a lake into an improved condition, and this value represented a lake's restoration potential. We classified lakes into seven management classes based on their current oxythermal habitat conditions and the resilience of oxythermal habitat to climate and watershed disturbance. To facilitate management on individual lakes, we also assessed the vulnerability and resilience of individual lakes and the uncertainty surrounding these estimates. By quantifying the resilience of lakes and how it is influenced by local action across a multistate region, we can prioritize conservation action across multiple scales to maintain the critical habitat and ecosystem function of glacial lakes.

AB - Managing ecological systems for resilience can increase their capacity to maintain key functions even under global change. Oxygenated coldwater (oxythermal) habitat in lakes is an important ecological resource that is threatened by both climate change and eutrophication. Here, we quantify the resilience of oxythermal habitat in over 10,000 glacial lakes in the upper Midwestern United States to climate change and watershed disturbance and classify lakes for conservation prioritization based on their current conditions and resilience. Oxythermal habitat was predicted by lake morphometry, July air temperatures, and watershed land use. Temperatures are projected to increase by mid-century, and the magnitude of warming, its effect on oxythermal habitat, and the uncertainty surrounding that effect varied among lakes. Under mid-century climate conditions, the number of lakes containing suitable coldwater habitat was predicted to decline by 67%, while the number of lakes with unsuitable habitat was predicted to increase by over 200%. Lakes varied in the amount of temperature increase that they could sustain without a resultant change in habitat tier (i.e., their climate resilience). Median climate resilience was 4.3°C, with some lakes capable of remaining in their habitat tier even with temperature increases up to 14°C. Changing watershed land use was predicted to influence oxythermal habitat in 24% of lakes (n = 2391). We used the magnitude of increase in watershed development that a lake could sustain while remaining in its current habitat class as a measure of its resilience to watershed disturbance. Conversely, decreased watershed development may improve oxythermal habitat conditions and push a lake into an improved condition, and this value represented a lake's restoration potential. We classified lakes into seven management classes based on their current oxythermal habitat conditions and the resilience of oxythermal habitat to climate and watershed disturbance. To facilitate management on individual lakes, we also assessed the vulnerability and resilience of individual lakes and the uncertainty surrounding these estimates. By quantifying the resilience of lakes and how it is influenced by local action across a multistate region, we can prioritize conservation action across multiple scales to maintain the critical habitat and ecosystem function of glacial lakes.

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KW - land use

KW - oxygen

KW - oxythermal habitat

KW - resilience

KW - temperature

KW - watershed

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Quantifying the resilience of coldwater lake habitat to climate and land use change to prioritize watershed conservation

Abstract

Bibliographical note

Keywords

UN SDGs

Access

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