Glacier-Atmosphere Interactions and Feedbacks in High-Mountain Regions - A Review

Tobias Sauter; B. W. Brock; Emily Collier; Brigitta Goger; Alexander R. Groos; K. F. Haualand; Richard Mott; Lindsey Nicholson; Rainer Prinz; Thomas Shaw; Ivana Stiperski; Alexander Georgi; Michael Haugeneder; Arindan Mandal; Dylan Reynolds; Manuel Saigger; Jean Emmanuel Sicart; Annelies Voordendag

doi:10.1029/2024RG000869

Glacier-Atmosphere Interactions and Feedbacks in High-Mountain Regions - A Review

Tobias Sauter^*, B. W. Brock, Emily Collier, Brigitta Goger, Alexander R. Groos, K. F. Haualand, Richard Mott, Lindsey Nicholson, Rainer Prinz, Thomas Shaw, Ivana Stiperski, Alexander Georgi, Michael Haugeneder, Arindan Mandal, Dylan Reynolds, Manuel Saigger, Jean Emmanuel Sicart, Annelies Voordendag

^*Corresponding author for this work

School of Geography and Natural Sciences

Research output: Contribution to journal › Review article › peer-review

Abstract

Mountain glaciers are among the natural systems most vulnerable to climate change. However, their interactions with the atmosphere are complex and not fully understood. These interactions can trigger rapid adjustments and climate feedbacks that either amplify or attenuate atmospheric signals, influencing both glacier response and large-scale atmospheric circulation. Observing this functional coupling in nature is challenging because the key processes occur over a wide range of spatial and temporal scales. However, recent advances in observational techniques and modeling have provided new insights into these interactions. In this review, we summarize the current state of knowledge on glacier-atmosphere interactions in high-mountain regions at different scales, and highlight recent advances in observational and numerical modeling. We also highlight important knowledge gaps and outline future research directions to improve the prediction of glacier change in a warming world.

Original language	English
Article number	e2024RG000869
Number of pages	41
Journal	Reviews of Geophysics
Volume	64
Issue number	1
Early online date	5 Jan 2026
DOIs	https://doi.org/10.1029/2024RG000869
Publication status	Published - 1 Mar 2026

Keywords

glacier
atmosphere
feedbacks
interactions
mountains

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10.1029/2024RG000869Licence: CC BY

Reviews of Geophysics - 2026 - Sauter - Glacier‐Atmosphere Interactions and Feedbacks in High‐Mountain Regions ‐ A ReviewFinal published version, 2.87 MBLicence: CC BY

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Sauter, T., Brock, B. W., Collier, E., Goger, B., Groos, A. R., Haualand, K. F., Mott, R., Nicholson, L., Prinz, R., Shaw, T., Stiperski, I., Georgi, A., Haugeneder, M., Mandal, A., Reynolds, D., Saigger, M., Sicart, J. E., & Voordendag, A. (2026). Glacier-Atmosphere Interactions and Feedbacks in High-Mountain Regions - A Review. Reviews of Geophysics, 64(1), Article e2024RG000869. https://doi.org/10.1029/2024RG000869

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abstract = "Mountain glaciers are among the natural systems most vulnerable to climate change. However, their interactions with the atmosphere are complex and not fully understood. These interactions can trigger rapid adjustments and climate feedbacks that either amplify or attenuate atmospheric signals, influencing both glacier response and large-scale atmospheric circulation. Observing this functional coupling in nature is challenging because the key processes occur over a wide range of spatial and temporal scales. However, recent advances in observational techniques and modeling have provided new insights into these interactions. In this review, we summarize the current state of knowledge on glacier-atmosphere interactions in high-mountain regions at different scales, and highlight recent advances in observational and numerical modeling. We also highlight important knowledge gaps and outline future research directions to improve the prediction of glacier change in a warming world.",

keywords = "glacier, atmosphere, feedbacks, interactions, mountains",

author = "Tobias Sauter and Brock, \{B. W.\} and Emily Collier and Brigitta Goger and Groos, \{Alexander R.\} and Haualand, \{K. F.\} and Richard Mott and Lindsey Nicholson and Rainer Prinz and Thomas Shaw and Ivana Stiperski and Alexander Georgi and Michael Haugeneder and Arindan Mandal and Dylan Reynolds and Manuel Saigger and Sicart, \{Jean Emmanuel\} and Annelies Voordendag",

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Sauter, T, Brock, BW, Collier, E, Goger, B, Groos, AR, Haualand, KF, Mott, R, Nicholson, L, Prinz, R, Shaw, T, Stiperski, I, Georgi, A, Haugeneder, M, Mandal, A, Reynolds, D, Saigger, M, Sicart, JE & Voordendag, A 2026, 'Glacier-Atmosphere Interactions and Feedbacks in High-Mountain Regions - A Review', Reviews of Geophysics, vol. 64, no. 1, e2024RG000869. https://doi.org/10.1029/2024RG000869

TY - JOUR

T1 - Glacier-Atmosphere Interactions and Feedbacks in High-Mountain Regions - A Review

AU - Sauter, Tobias

AU - Brock, B. W.

AU - Collier, Emily

AU - Goger, Brigitta

AU - Groos, Alexander R.

AU - Haualand, K. F.

AU - Mott, Richard

AU - Nicholson, Lindsey

AU - Prinz, Rainer

AU - Shaw, Thomas

AU - Stiperski, Ivana

AU - Georgi, Alexander

AU - Haugeneder, Michael

AU - Mandal, Arindan

AU - Reynolds, Dylan

AU - Saigger, Manuel

AU - Sicart, Jean Emmanuel

AU - Voordendag, Annelies

PY - 2026/3/1

Y1 - 2026/3/1

N2 - Mountain glaciers are among the natural systems most vulnerable to climate change. However, their interactions with the atmosphere are complex and not fully understood. These interactions can trigger rapid adjustments and climate feedbacks that either amplify or attenuate atmospheric signals, influencing both glacier response and large-scale atmospheric circulation. Observing this functional coupling in nature is challenging because the key processes occur over a wide range of spatial and temporal scales. However, recent advances in observational techniques and modeling have provided new insights into these interactions. In this review, we summarize the current state of knowledge on glacier-atmosphere interactions in high-mountain regions at different scales, and highlight recent advances in observational and numerical modeling. We also highlight important knowledge gaps and outline future research directions to improve the prediction of glacier change in a warming world.

AB - Mountain glaciers are among the natural systems most vulnerable to climate change. However, their interactions with the atmosphere are complex and not fully understood. These interactions can trigger rapid adjustments and climate feedbacks that either amplify or attenuate atmospheric signals, influencing both glacier response and large-scale atmospheric circulation. Observing this functional coupling in nature is challenging because the key processes occur over a wide range of spatial and temporal scales. However, recent advances in observational techniques and modeling have provided new insights into these interactions. In this review, we summarize the current state of knowledge on glacier-atmosphere interactions in high-mountain regions at different scales, and highlight recent advances in observational and numerical modeling. We also highlight important knowledge gaps and outline future research directions to improve the prediction of glacier change in a warming world.

KW - glacier

KW - atmosphere

KW - feedbacks

KW - interactions

KW - mountains

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U2 - 10.1029/2024RG000869

DO - 10.1029/2024RG000869

M3 - Review article

SN - 8755-1209

VL - 64

JO - Reviews of Geophysics

JF - Reviews of Geophysics

IS - 1

M1 - e2024RG000869

ER -

Glacier-Atmosphere Interactions and Feedbacks in High-Mountain Regions - A Review

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