Statistical physics and dynamical systems perspectives on geophysical extreme events

D. Faranda; G. Messori; T. Alberti; C. Alvarez-Castro; T. Caby; L. Cavicchia; E. Coppola; R. V. Donner; B. Dubrulle; V. M. Galfi; E. Holmberg; V. Lembo; R. Noyelle; P. Yiou; B. Spagnolo; D. Valenti; S. Vaienti; C. Wormell

doi:10.1103/PhysRevE.110.041001

Statistical physics and dynamical systems perspectives on geophysical extreme events

D. Faranda, G. Messori, T. Alberti, C. Alvarez-Castro, T. Caby, L. Cavicchia, E. Coppola, R. V. Donner, B. Dubrulle, V. M. Galfi, E. Holmberg, V. Lembo, R. Noyelle, P. Yiou, B. Spagnolo, D. Valenti, S. Vaienti, C. Wormell

Water and Climate Risk

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Abstract

Statistical physics and dynamical systems theory are key tools to study high-impact geophysical events such as temperature extremes, cyclones, thunderstorms, geomagnetic storms, and many others. Despite the intrinsic differences between these events, they all originate as temporary deviations from the typical trajectories of a geophysical system, resulting in well-organized, coherent structures at characteristic spatial and temporal scales. While statistical extreme value analysis techniques are capable of providing return times and probabilities of occurrence of certain geophysical events, they are not apt to account for their underlying physics. Their focus is to compute the probability of occurrence of events that are large or small with respect to some specific observable (e.g., temperature, precipitation, solar wind), rather than to relate rare or extreme phenomena to the underlying anomalous geophysical regimes. This paper outlines this knowledge gap, presenting some related challenges, new formalisms and briefly commenting on how stochastic approaches tailored to the study of extreme geophysical events can help to advance their understanding.

Original language	English
Article number	041001
Pages (from-to)	1-33
Number of pages	33
Journal	Physical review E
Volume	110
Issue number	4
Early online date	4 Oct 2024
DOIs	https://doi.org/10.1103/PhysRevE.110.041001
Publication status	Published - Oct 2024

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Publisher Copyright:
© 2024 American Physical Society.

Funding

Funders	Funder number
Laboratoire International Associé
project Dynamics and Information Research Institute
Centro de Matemática Universidade do Porto
Centre National de la Recherche Scientifique
European Union's Horizon 2020 European Research Council
Ministero dell’Istruzione, dell’Università e della Ricerca
European Union's Horizon Europe Research and Innovation program	101081193
European Commission	101065985
Ministère de l'Europe et des Affaires Étrangères	ANR-20-CE01-0008-01
Horizon 2020 Framework Programme	948309
Horizon 2020	101003469
Istituto Nazionale di Alta Matematica "Francesco Severi"	49958WH
Fundação para a Ciência e a Tecnologia	UIDB/00144/2020, ANR-17-EURE-0015
Swedish Research Council Vetenskapsrådet	2022-06599
European Union's Horizon 2020 Marie Sklodowska-Curie	101065985, 956396

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10.1103/PhysRevE.110.041001

Statistical physics and dynamical systems perspectives on geophysical extreme eventsFinal published version, 8.88 MBLicence: Article 25fa Dutch Copyright Act

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Faranda, D., Messori, G., Alberti, T., Alvarez-Castro, C., Caby, T., Cavicchia, L., Coppola, E., Donner, R. V., Dubrulle, B., Galfi, V. M., Holmberg, E., Lembo, V., Noyelle, R., Yiou, P., Spagnolo, B., Valenti, D., Vaienti, S., & Wormell, C. (2024). Statistical physics and dynamical systems perspectives on geophysical extreme events. Physical review E, 110(4), 1-33. Article 041001. https://doi.org/10.1103/PhysRevE.110.041001

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abstract = "Statistical physics and dynamical systems theory are key tools to study high-impact geophysical events such as temperature extremes, cyclones, thunderstorms, geomagnetic storms, and many others. Despite the intrinsic differences between these events, they all originate as temporary deviations from the typical trajectories of a geophysical system, resulting in well-organized, coherent structures at characteristic spatial and temporal scales. While statistical extreme value analysis techniques are capable of providing return times and probabilities of occurrence of certain geophysical events, they are not apt to account for their underlying physics. Their focus is to compute the probability of occurrence of events that are large or small with respect to some specific observable (e.g., temperature, precipitation, solar wind), rather than to relate rare or extreme phenomena to the underlying anomalous geophysical regimes. This paper outlines this knowledge gap, presenting some related challenges, new formalisms and briefly commenting on how stochastic approaches tailored to the study of extreme geophysical events can help to advance their understanding.",

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Faranda, D, Messori, G, Alberti, T, Alvarez-Castro, C, Caby, T, Cavicchia, L, Coppola, E, Donner, RV, Dubrulle, B, Galfi, VM, Holmberg, E, Lembo, V, Noyelle, R, Yiou, P, Spagnolo, B, Valenti, D, Vaienti, S & Wormell, C 2024, 'Statistical physics and dynamical systems perspectives on geophysical extreme events', Physical review E, vol. 110, no. 4, 041001, pp. 1-33. https://doi.org/10.1103/PhysRevE.110.041001

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AU - Cavicchia, L.

AU - Coppola, E.

AU - Donner, R. V.

AU - Dubrulle, B.

AU - Galfi, V. M.

AU - Holmberg, E.

AU - Lembo, V.

AU - Noyelle, R.

AU - Yiou, P.

AU - Spagnolo, B.

AU - Valenti, D.

AU - Vaienti, S.

AU - Wormell, C.

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Statistical physics and dynamical systems perspectives on geophysical extreme events

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