Slower snowmelt in a warmer world

Keith N. Musselman; Martyn P. Clark; Changhai Liu; Kyoko Ikeda; Roy Rasmussen

doi:10.1038/nclimate3225

Slower snowmelt in a warmer world

Keith N. Musselman, Martyn P. Clark, Changhai Liu, Kyoko Ikeda, Roy Rasmussen

National Center for Atmospheric Research

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

465 Scopus citations

Abstract

There is general consensus that projected warming will cause earlier snowmelt, but how snowmelt rates will respond to climate change is poorly known. We present snowpack observations from western North America illustrating that shallower snowpack melts earlier, and at lower rates, than deeper, later-lying snow-cover. The observations provide the context for a hypothesis of slower snowmelt in a warmer world. We test this hypothesis using climate model simulations for both a control time period and re-run with a future climate scenario, and find that the fraction of meltwater volume produced at high snowmelt rates is greatly reduced in a warmer climate. The reduction is caused by a contraction of the snowmelt season to a time of lower available energy, reducing by as much as 64% the snow-covered area exposed to energy sufficient to drive high snowmelt rates. These results have unresolved implications on soil moisture deficits, vegetation stress, and streamflow declines.

Original language	English
Pages (from-to)	214-219
Number of pages	6
Journal	Nature Climate Change
Volume	7
Issue number	3
DOIs	https://doi.org/10.1038/nclimate3225
State	Published - Mar 1 2017

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AU - Musselman, Keith N.

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AU - Liu, Changhai

AU - Ikeda, Kyoko

AU - Rasmussen, Roy

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AB - There is general consensus that projected warming will cause earlier snowmelt, but how snowmelt rates will respond to climate change is poorly known. We present snowpack observations from western North America illustrating that shallower snowpack melts earlier, and at lower rates, than deeper, later-lying snow-cover. The observations provide the context for a hypothesis of slower snowmelt in a warmer world. We test this hypothesis using climate model simulations for both a control time period and re-run with a future climate scenario, and find that the fraction of meltwater volume produced at high snowmelt rates is greatly reduced in a warmer climate. The reduction is caused by a contraction of the snowmelt season to a time of lower available energy, reducing by as much as 64% the snow-covered area exposed to energy sufficient to drive high snowmelt rates. These results have unresolved implications on soil moisture deficits, vegetation stress, and streamflow declines.

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Slower snowmelt in a warmer world

Abstract

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