Atmospheric rivers in Antarctica

Jonathan D. Wille; Vincent Favier; Irina V. Gorodetskaya; Cécile Agosta; Rebecca Baiman; J. E. Barrett; Léonard Barthelemy; Burcu Boza; Deniz Bozkurt; Mathieu Casado; Anastasiia Chyhareva; Kyle R. Clem; Francis Codron; Rajashree Tri Datta; Claudio Durán-Alarcón; Diana Francis; Andrew O. Hoffman; Marlen Kolbe; Svitlana Krakovska; Gabrielle Linscott; Michelle L. Maclennan; Kyle S. Mattingly; Ye Mu; Benjamin Pohl; Christophe Leroy Dos Santos; Christine A. Shields; Emir Toker; Andrew C. Winters; Ziqi Yin; Xun Zou; Chen Zhang; Zhenhai Zhang

doi:10.1038/s43017-024-00638-7

Atmospheric rivers in Antarctica

Jonathan D. Wille^*, Vincent Favier, Irina V. Gorodetskaya, Cécile Agosta, Rebecca Baiman, J. E. Barrett, Léonard Barthelemy, Burcu Boza, Deniz Bozkurt, Mathieu Casado, Anastasiia Chyhareva, Kyle R. Clem, Francis Codron, Rajashree Tri Datta, Claudio Durán-Alarcón, Diana Francis, Andrew O. Hoffman, Marlen Kolbe, Svitlana Krakovska, Gabrielle LinscottMichelle L. Maclennan, Kyle S. Mattingly, Ye Mu, Benjamin Pohl, Christophe Leroy Dos Santos, Christine A. Shields, Emir Toker, Andrew C. Winters, Ziqi Yin, Xun Zou, Chen Zhang, Zhenhai Zhang

^*Corresponding author for this work

Eurasia Institute of Earth Sciences

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

Abstract

Antarctic atmospheric rivers (ARs) are a form of extreme weather that transport heat and moisture from the Southern Hemisphere subtropics and/or mid-latitudes to the Antarctic continent. Present-day AR events generally have a positive influence on the Antarctic ice-sheet mass balance by producing heavy snowfall, yet they also cause melt of sea ice and coastal ice sheet areas, as well as ice shelf destabilization. In this Review, we explore the atmospheric dynamics and impacts of Antarctic ARs over their life cycle to better understand their net contributions to ice-sheet mass balance. ARs occur in high-amplitude pressure couplets, and those strong enough to reach the Antarctic are often formed within Rossby waves initiated by tropical convection. Antarctic ARs are rare events (~3 days per year per location) but have been responsible for 50–70% of extreme snowfall events in East Antarctica since the 1980s. However, they can also trigger extensive surface melting events, such as the final ice shelf collapse of Larsen A in 1995 and Larsen B in 2002. Climate change will likely cause stronger ARs as anthropogenic warming increases atmospheric water vapour. Future research must determine how these climate change impacts will alter the relationship among Antarctic ARs, net ice-sheet mass balance and future sea-level rise.

Original language	English
Article number	e2020JD033788
Journal	Nature Reviews Earth and Environment
DOIs	https://doi.org/10.1038/s43017-024-00638-7
Publication status	Accepted/In press - 2025

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Publisher Copyright:
© Springer Nature Limited 2025.

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Wille, J. D., Favier, V., Gorodetskaya, I. V., Agosta, C., Baiman, R., Barrett, J. E., Barthelemy, L., Boza, B., Bozkurt, D., Casado, M., Chyhareva, A., Clem, K. R., Codron, F., Datta, R. T., Durán-Alarcón, C., Francis, D., Hoffman, A. O., Kolbe, M., Krakovska, S., ... Zhang, Z. (Accepted/In press). Atmospheric rivers in Antarctica. Nature Reviews Earth and Environment, Article e2020JD033788. https://doi.org/10.1038/s43017-024-00638-7

@article{c67befb2608b441ebec40c008ddb179e,

title = "Atmospheric rivers in Antarctica",

abstract = "Antarctic atmospheric rivers (ARs) are a form of extreme weather that transport heat and moisture from the Southern Hemisphere subtropics and/or mid-latitudes to the Antarctic continent. Present-day AR events generally have a positive influence on the Antarctic ice-sheet mass balance by producing heavy snowfall, yet they also cause melt of sea ice and coastal ice sheet areas, as well as ice shelf destabilization. In this Review, we explore the atmospheric dynamics and impacts of Antarctic ARs over their life cycle to better understand their net contributions to ice-sheet mass balance. ARs occur in high-amplitude pressure couplets, and those strong enough to reach the Antarctic are often formed within Rossby waves initiated by tropical convection. Antarctic ARs are rare events (~3 days per year per location) but have been responsible for 50–70% of extreme snowfall events in East Antarctica since the 1980s. However, they can also trigger extensive surface melting events, such as the final ice shelf collapse of Larsen A in 1995 and Larsen B in 2002. Climate change will likely cause stronger ARs as anthropogenic warming increases atmospheric water vapour. Future research must determine how these climate change impacts will alter the relationship among Antarctic ARs, net ice-sheet mass balance and future sea-level rise.",

author = "Wille, {Jonathan D.} and Vincent Favier and Gorodetskaya, {Irina V.} and C{\'e}cile Agosta and Rebecca Baiman and Barrett, {J. E.} and L{\'e}onard Barthelemy and Burcu Boza and Deniz Bozkurt and Mathieu Casado and Anastasiia Chyhareva and Clem, {Kyle R.} and Francis Codron and Datta, {Rajashree Tri} and Claudio Dur{\'a}n-Alarc{\'o}n and Diana Francis and Hoffman, {Andrew O.} and Marlen Kolbe and Svitlana Krakovska and Gabrielle Linscott and Maclennan, {Michelle L.} and Mattingly, {Kyle S.} and Ye Mu and Benjamin Pohl and Santos, {Christophe Leroy Dos} and Shields, {Christine A.} and Emir Toker and Winters, {Andrew C.} and Ziqi Yin and Xun Zou and Chen Zhang and Zhenhai Zhang",

note = "Publisher Copyright: {\textcopyright} Springer Nature Limited 2025.",

year = "2025",

doi = "10.1038/s43017-024-00638-7",

language = "English",

journal = "Nature Reviews Earth and Environment",

issn = "2662-138X",

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Wille, JD, Favier, V, Gorodetskaya, IV, Agosta, C, Baiman, R, Barrett, JE, Barthelemy, L, Boza, B, Bozkurt, D, Casado, M, Chyhareva, A, Clem, KR, Codron, F, Datta, RT, Durán-Alarcón, C, Francis, D, Hoffman, AO, Kolbe, M, Krakovska, S, Linscott, G, Maclennan, ML, Mattingly, KS, Mu, Y, Pohl, B, Santos, CLD, Shields, CA, Toker, E, Winters, AC, Yin, Z, Zou, X, Zhang, C & Zhang, Z 2025, 'Atmospheric rivers in Antarctica', Nature Reviews Earth and Environment. https://doi.org/10.1038/s43017-024-00638-7

TY - JOUR

T1 - Atmospheric rivers in Antarctica

AU - Wille, Jonathan D.

AU - Favier, Vincent

AU - Gorodetskaya, Irina V.

AU - Agosta, Cécile

AU - Baiman, Rebecca

AU - Barrett, J. E.

AU - Barthelemy, Léonard

AU - Boza, Burcu

AU - Bozkurt, Deniz

AU - Casado, Mathieu

AU - Chyhareva, Anastasiia

AU - Clem, Kyle R.

AU - Codron, Francis

AU - Datta, Rajashree Tri

AU - Durán-Alarcón, Claudio

AU - Francis, Diana

AU - Hoffman, Andrew O.

AU - Kolbe, Marlen

AU - Krakovska, Svitlana

AU - Linscott, Gabrielle

AU - Maclennan, Michelle L.

AU - Mattingly, Kyle S.

AU - Mu, Ye

AU - Pohl, Benjamin

AU - Santos, Christophe Leroy Dos

AU - Shields, Christine A.

AU - Toker, Emir

AU - Winters, Andrew C.

AU - Yin, Ziqi

AU - Zou, Xun

AU - Zhang, Chen

AU - Zhang, Zhenhai

PY - 2025

Y1 - 2025

N2 - Antarctic atmospheric rivers (ARs) are a form of extreme weather that transport heat and moisture from the Southern Hemisphere subtropics and/or mid-latitudes to the Antarctic continent. Present-day AR events generally have a positive influence on the Antarctic ice-sheet mass balance by producing heavy snowfall, yet they also cause melt of sea ice and coastal ice sheet areas, as well as ice shelf destabilization. In this Review, we explore the atmospheric dynamics and impacts of Antarctic ARs over their life cycle to better understand their net contributions to ice-sheet mass balance. ARs occur in high-amplitude pressure couplets, and those strong enough to reach the Antarctic are often formed within Rossby waves initiated by tropical convection. Antarctic ARs are rare events (~3 days per year per location) but have been responsible for 50–70% of extreme snowfall events in East Antarctica since the 1980s. However, they can also trigger extensive surface melting events, such as the final ice shelf collapse of Larsen A in 1995 and Larsen B in 2002. Climate change will likely cause stronger ARs as anthropogenic warming increases atmospheric water vapour. Future research must determine how these climate change impacts will alter the relationship among Antarctic ARs, net ice-sheet mass balance and future sea-level rise.

AB - Antarctic atmospheric rivers (ARs) are a form of extreme weather that transport heat and moisture from the Southern Hemisphere subtropics and/or mid-latitudes to the Antarctic continent. Present-day AR events generally have a positive influence on the Antarctic ice-sheet mass balance by producing heavy snowfall, yet they also cause melt of sea ice and coastal ice sheet areas, as well as ice shelf destabilization. In this Review, we explore the atmospheric dynamics and impacts of Antarctic ARs over their life cycle to better understand their net contributions to ice-sheet mass balance. ARs occur in high-amplitude pressure couplets, and those strong enough to reach the Antarctic are often formed within Rossby waves initiated by tropical convection. Antarctic ARs are rare events (~3 days per year per location) but have been responsible for 50–70% of extreme snowfall events in East Antarctica since the 1980s. However, they can also trigger extensive surface melting events, such as the final ice shelf collapse of Larsen A in 1995 and Larsen B in 2002. Climate change will likely cause stronger ARs as anthropogenic warming increases atmospheric water vapour. Future research must determine how these climate change impacts will alter the relationship among Antarctic ARs, net ice-sheet mass balance and future sea-level rise.

UR - http://www.scopus.com/inward/record.url?scp=85217521310&partnerID=8YFLogxK

U2 - 10.1038/s43017-024-00638-7

DO - 10.1038/s43017-024-00638-7

M3 - Review article

AN - SCOPUS:85217521310

SN - 2662-138X

JO - Nature Reviews Earth and Environment

JF - Nature Reviews Earth and Environment

M1 - e2020JD033788

ER -

Atmospheric rivers in Antarctica

Abstract

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