Groundwater Buffers Decreasing Glacier Melt in an Andean Watershed—But Not Forever

Lauren D. Somers; Jeffrey M. McKenzie; Bryan G. Mark; Pablo Lagos; Gene Hua Crystal Ng; Andrew D. Wickert; Christian Yarleque; Michel Baraër; Yamina Silva

doi:10.1029/2019GL084730

Groundwater Buffers Decreasing Glacier Melt in an Andean Watershed—But Not Forever

Lauren D. Somers, Jeffrey M. McKenzie, Bryan G. Mark, Pablo Lagos, Gene Hua Crystal Ng, Andrew D. Wickert, Christian Yarleque, Michel Baraër, Yamina Silva

Earth and Environmental Sciences-Twin Cities

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43 Scopus citations

Abstract

Accelerating mountain glacier recession in a warming climate threatens the sustainability of mountain water resources. The extent to which groundwater will provide resilience to these water resources is unknown, in part due to a lack of data and poorly understood interactions between groundwater and surface water. Here we address this knowledge gap by linking climate, glaciers, surface water, and groundwater into an integrated model of the Shullcas Watershed, Peru, in the tropical Andes, the region experiencing the most rapid mountain-glacier retreat on Earth. For a range of climate scenarios, our model projects that glaciers will disappear by 2100. The loss of glacial meltwater will be buffered by relatively consistent groundwater discharge, which only receives minor recharge (~2%) from glacier melt. However, increasing temperature and associated evapotranspiration, alongside potential decreases in precipitation, will decrease groundwater recharge and streamflow, particularly for the RCP 8.5 emission scenario.

Original language	English (US)
Pages (from-to)	13016-13026
Number of pages	11
Journal	Geophysical Research Letters
Volume	46
Issue number	22
DOIs	https://doi.org/10.1029/2019GL084730
State	Published - Nov 28 2019

Bibliographical note

Publisher Copyright:
©2019. The Authors.

Keywords

Andes
integrated modeling
mountain hydrogeology
mountain hydrology
tropical glaciers
water resources

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title = "Groundwater Buffers Decreasing Glacier Melt in an Andean Watershed—But Not Forever",

abstract = "Accelerating mountain glacier recession in a warming climate threatens the sustainability of mountain water resources. The extent to which groundwater will provide resilience to these water resources is unknown, in part due to a lack of data and poorly understood interactions between groundwater and surface water. Here we address this knowledge gap by linking climate, glaciers, surface water, and groundwater into an integrated model of the Shullcas Watershed, Peru, in the tropical Andes, the region experiencing the most rapid mountain-glacier retreat on Earth. For a range of climate scenarios, our model projects that glaciers will disappear by 2100. The loss of glacial meltwater will be buffered by relatively consistent groundwater discharge, which only receives minor recharge (~2%) from glacier melt. However, increasing temperature and associated evapotranspiration, alongside potential decreases in precipitation, will decrease groundwater recharge and streamflow, particularly for the RCP 8.5 emission scenario.",

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AU - Ng, Gene Hua Crystal

AU - Wickert, Andrew D.

AU - Yarleque, Christian

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AU - Silva, Yamina

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AB - Accelerating mountain glacier recession in a warming climate threatens the sustainability of mountain water resources. The extent to which groundwater will provide resilience to these water resources is unknown, in part due to a lack of data and poorly understood interactions between groundwater and surface water. Here we address this knowledge gap by linking climate, glaciers, surface water, and groundwater into an integrated model of the Shullcas Watershed, Peru, in the tropical Andes, the region experiencing the most rapid mountain-glacier retreat on Earth. For a range of climate scenarios, our model projects that glaciers will disappear by 2100. The loss of glacial meltwater will be buffered by relatively consistent groundwater discharge, which only receives minor recharge (~2%) from glacier melt. However, increasing temperature and associated evapotranspiration, alongside potential decreases in precipitation, will decrease groundwater recharge and streamflow, particularly for the RCP 8.5 emission scenario.

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Groundwater Buffers Decreasing Glacier Melt in an Andean Watershed—But Not Forever

Abstract

Bibliographical note

Keywords

UN SDGs

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