Pushing the frontiers in climate modelling and analysis with machine learning

Veronika Eyring; William D. Collins; Pierre Gentine; Elizabeth A. Barnes; Marcelo Barreiro; Tom Beucler; Marc Bocquet; Christopher S. Bretherton; Hannah M. Christensen; Katherine Dagon; David John Gagne; David Hall; Dorit Hammerling; Stephan Hoyer; Fernando Iglesias-Suarez; Ignacio Lopez-Gomez; Marie C. McGraw; Gerald A. Meehl; Maria J. Molina; Claire Monteleoni; Juliane Mueller; Michael S. Pritchard; David Rolnick; Jakob Runge; Philip Stier; Oliver Watt-Meyer; Katja Weigel; Rose Yu; Laure Zanna

doi:10.1038/s41558-024-02095-y

Pushing the frontiers in climate modelling and analysis with machine learning

Veronika Eyring
, William D. Collins
, Pierre Gentine
, Elizabeth A. Barnes
, Marcelo Barreiro
, Tom Beucler
, Marc Bocquet
, Christopher S. Bretherton
, Hannah M. Christensen
, Katherine Dagon
, David John Gagne
, David Hall
, Dorit Hammerling
, Stephan Hoyer
, Fernando Iglesias-Suarez
, Ignacio Lopez-Gomez
, Marie C. McGraw
, Gerald A. Meehl
, Maria J. Molina
, Claire Monteleoni

Juliane Mueller, Michael S. Pritchard, David Rolnick, Jakob Runge, Philip Stier, Oliver Watt-Meyer, Katja Weigel, Rose Yu, Laure Zanna

German Aerospace Center
University of Bremen
Lawrence Berkeley National Laboratory
University of California at Berkeley
Columbia University
Colorado State University
Universidad de la República
University of Lausanne
École des Ponts and EdF R & amp;D
The Allen Institute for Artificial Intelligence
University of Oxford
National Center for Atmospheric Research
NVIDIA
Colorado School of Mines
Alphabet Inc.
California Institute of Technology
University of Maryland, College Park
University of Colorado Boulder
INRIA Paris
National Renewable Energy Laboratory
University of California at Irvine
McGill University
Mila - Quebec AI Institute
Technical University of Berlin
University of California at San Diego
University of New York

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

130 Scopus citations

Abstract

Climate modelling and analysis are facing new demands to enhance projections and climate information. Here we argue that now is the time to push the frontiers of machine learning beyond state-of-the-art approaches, not only by developing machine-learning-based Earth system models with greater fidelity, but also by providing new capabilities through emulators for extreme event projections with large ensembles, enhanced detection and attribution methods for extreme events, and advanced climate model analysis and benchmarking. Utilizing this potential requires key machine learning challenges to be addressed, in particular generalization, uncertainty quantification, explainable artificial intelligence and causality. This interdisciplinary effort requires bringing together machine learning and climate scientists, while also leveraging the private sector, to accelerate progress towards actionable climate science.

Original language	English
Pages (from-to)	916-928
Number of pages	13
Journal	Nature Climate Change
Volume	14
Issue number	9
DOIs	https://doi.org/10.1038/s41558-024-02095-y
State	Published - Sep 2024
Externally published	Yes

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Eyring, V., Collins, W. D., Gentine, P., Barnes, E. A., Barreiro, M., Beucler, T., Bocquet, M., Bretherton, C. S., Christensen, H. M., Dagon, K., Gagne, D. J., Hall, D., Hammerling, D., Hoyer, S., Iglesias-Suarez, F., Lopez-Gomez, I., McGraw, M. C., Meehl, G. A., Molina, M. J., ... Zanna, L. (2024). Pushing the frontiers in climate modelling and analysis with machine learning. Nature Climate Change, 14(9), 916-928. https://doi.org/10.1038/s41558-024-02095-y

@article{bbf119b13e75429583feb15d38989831,

title = "Pushing the frontiers in climate modelling and analysis with machine learning",

abstract = "Climate modelling and analysis are facing new demands to enhance projections and climate information. Here we argue that now is the time to push the frontiers of machine learning beyond state-of-the-art approaches, not only by developing machine-learning-based Earth system models with greater fidelity, but also by providing new capabilities through emulators for extreme event projections with large ensembles, enhanced detection and attribution methods for extreme events, and advanced climate model analysis and benchmarking. Utilizing this potential requires key machine learning challenges to be addressed, in particular generalization, uncertainty quantification, explainable artificial intelligence and causality. This interdisciplinary effort requires bringing together machine learning and climate scientists, while also leveraging the private sector, to accelerate progress towards actionable climate science.",

author = "Veronika Eyring and Collins, \{William D.\} and Pierre Gentine and Barnes, \{Elizabeth A.\} and Marcelo Barreiro and Tom Beucler and Marc Bocquet and Bretherton, \{Christopher S.\} and Christensen, \{Hannah M.\} and Katherine Dagon and Gagne, \{David John\} and David Hall and Dorit Hammerling and Stephan Hoyer and Fernando Iglesias-Suarez and Ignacio Lopez-Gomez and McGraw, \{Marie C.\} and Meehl, \{Gerald A.\} and Molina, \{Maria J.\} and Claire Monteleoni and Juliane Mueller and Pritchard, \{Michael S.\} and David Rolnick and Jakob Runge and Philip Stier and Oliver Watt-Meyer and Katja Weigel and Rose Yu and Laure Zanna",

note = "Publisher Copyright: {\textcopyright} Springer Nature Limited 2024.",

year = "2024",

month = sep,

doi = "10.1038/s41558-024-02095-y",

language = "English",

volume = "14",

pages = "916--928",

journal = "Nature Climate Change",

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Eyring, V, Collins, WD, Gentine, P, Barnes, EA, Barreiro, M, Beucler, T, Bocquet, M, Bretherton, CS, Christensen, HM, Dagon, K , Gagne, DJ, Hall, D, Hammerling, D, Hoyer, S, Iglesias-Suarez, F, Lopez-Gomez, I, McGraw, MC, Meehl, GA , Molina, MJ, Monteleoni, C, Mueller, J, Pritchard, MS, Rolnick, D, Runge, J, Stier, P, Watt-Meyer, O, Weigel, K, Yu, R & Zanna, L 2024, 'Pushing the frontiers in climate modelling and analysis with machine learning', Nature Climate Change, vol. 14, no. 9, pp. 916-928. https://doi.org/10.1038/s41558-024-02095-y

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AU - Eyring, Veronika

AU - Collins, William D.

AU - Gentine, Pierre

AU - Barnes, Elizabeth A.

AU - Barreiro, Marcelo

AU - Beucler, Tom

AU - Bocquet, Marc

AU - Bretherton, Christopher S.

AU - Christensen, Hannah M.

AU - Dagon, Katherine

AU - Gagne, David John

AU - Hall, David

AU - Hammerling, Dorit

AU - Hoyer, Stephan

AU - Iglesias-Suarez, Fernando

AU - Lopez-Gomez, Ignacio

AU - McGraw, Marie C.

AU - Meehl, Gerald A.

AU - Molina, Maria J.

AU - Monteleoni, Claire

AU - Mueller, Juliane

AU - Pritchard, Michael S.

AU - Rolnick, David

AU - Runge, Jakob

AU - Stier, Philip

AU - Watt-Meyer, Oliver

AU - Weigel, Katja

AU - Yu, Rose

AU - Zanna, Laure

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AB - Climate modelling and analysis are facing new demands to enhance projections and climate information. Here we argue that now is the time to push the frontiers of machine learning beyond state-of-the-art approaches, not only by developing machine-learning-based Earth system models with greater fidelity, but also by providing new capabilities through emulators for extreme event projections with large ensembles, enhanced detection and attribution methods for extreme events, and advanced climate model analysis and benchmarking. Utilizing this potential requires key machine learning challenges to be addressed, in particular generalization, uncertainty quantification, explainable artificial intelligence and causality. This interdisciplinary effort requires bringing together machine learning and climate scientists, while also leveraging the private sector, to accelerate progress towards actionable climate science.

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SP - 916

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JO - Nature Climate Change

JF - Nature Climate Change

IS - 9

ER -

Pushing the frontiers in climate modelling and analysis with machine learning

Abstract

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