Please use this identifier to cite or link to this item: https://doi.org/10.1029/2021jd034911
Title: The Energy and Mass Balance of Peruvian Glaciers
Authors: Fyffe, Catriona L.
Potter, Emily
Fugger, Stefan
Orr, Andrew
Fatichi, Simone 
Loarte, Edwin
Medina, Katy
Hellström, R.Å.
Bernat, Maud
Aubry-Wake, Caroline
Gurgiser, Wolfgang
Baker Perry, L.
Suarez, Wilson
Quincey, Duncan J.
Pellicciotti, Francesca
Keywords: climate change
Cordillera Blanca
Cordillera Vilcanota
energy balance
mass balance
Peruvian glaciers
Issue Date: 16-Nov-2021
Publisher: John Wiley and Sons Inc
Citation: Fyffe, Catriona L., Potter, Emily, Fugger, Stefan, Orr, Andrew, Fatichi, Simone, Loarte, Edwin, Medina, Katy, Hellström, R.Å., Bernat, Maud, Aubry-Wake, Caroline, Gurgiser, Wolfgang, Baker Perry, L., Suarez, Wilson, Quincey, Duncan J., Pellicciotti, Francesca (2021-11-16). The Energy and Mass Balance of Peruvian Glaciers. Journal of Geophysical Research: Atmospheres 126 (23) : e2021JD034911. ScholarBank@NUS Repository. https://doi.org/10.1029/2021jd034911
Rights: Attribution 4.0 International
Abstract: Peruvian glaciers are important contributors to dry season runoff for agriculture and hydropower, but they are at risk of disappearing due to climate change. We applied a physically based, energy balance melt model at five on-glacier sites within the Peruvian Cordilleras Blanca and Vilcanota. Net shortwave radiation dominates the energy balance, and despite this flux being higher in the dry season, melt rates are lower due to losses from net longwave radiation and the latent heat flux. The sensible heat flux is a relatively small contributor to melt energy. At three of the sites the wet season snowpack was discontinuous, forming and melting within a daily to weekly timescale, and resulting in highly variable melt rates closely related to precipitation dynamics. Cold air temperatures due to a strong La Niña year at Shallap Glacier (Cordillera Blanca) resulted in a continuous wet season snowpack, significantly reducing wet season ablation. Sublimation was most important at the highest site in the accumulation zone of the Quelccaya Ice Cap (Cordillera Vilcanota), accounting for 81% of ablation, compared to 2%–4% for the other sites. Air temperature and precipitation inputs were perturbed to investigate the climate sensitivity of the five glaciers. At the lower sites warmer air temperatures resulted in a switch from snowfall to rain, so that ablation was increased via the decrease in albedo and increase in net shortwave radiation. At the top of Quelccaya Ice Cap warming caused melting to replace sublimation so that ablation increased nonlinearly with air temperature. © 2021. The Authors.
Source Title: Journal of Geophysical Research: Atmospheres
URI: https://scholarbank.nus.edu.sg/handle/10635/233816
ISSN: 2169-897X
DOI: 10.1029/2021jd034911
Rights: Attribution 4.0 International
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