Dominant imprint of rossby waves in the climate network

Yang Wang; Avi Gozolchiani; Yosef Ashkenazy; Yehiel Berezin; Oded Guez; Shlomo Havlin

doi:10.1103/PhysRevLett.111.138501

Dominant imprint of rossby waves in the climate network

Yang Wang
, Avi Gozolchiani
, Yosef Ashkenazy
, Yehiel Berezin
, Oded Guez
, Shlomo Havlin

Department of Physics - at Bar-Ilan University

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

66 Scopus citations

Abstract

The connectivity pattern of networks based on ground level temperature records shows a dense stripe of links in the extra tropics of the southern hemisphere. We show that statistical categorization of these links yields a clear association with the pattern of an atmospheric Rossby wave, one of the major mechanisms associated with the weather system and with planetary scale energy transport. It is shown that alternating densities of negative and positive links are arranged in half Rossby wave distances around 3500, 7000, and 10 000 km and are aligned with the expected direction of energy flow, distribution of time delays, and the seasonality of these waves. In addition, long distance links that are associated with Rossby waves are the most dominant in the climate network.

Original language	English
Article number	138501
Journal	Physical Review Letters
Volume	111
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.111.138501
State	Published - 27 Sep 2013

Funding

Funders	Funder number
Seventh Framework Programme	289447

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action

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10.1103/PhysRevLett.111.138501

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abstract = "The connectivity pattern of networks based on ground level temperature records shows a dense stripe of links in the extra tropics of the southern hemisphere. We show that statistical categorization of these links yields a clear association with the pattern of an atmospheric Rossby wave, one of the major mechanisms associated with the weather system and with planetary scale energy transport. It is shown that alternating densities of negative and positive links are arranged in half Rossby wave distances around 3500, 7000, and 10 000 km and are aligned with the expected direction of energy flow, distribution of time delays, and the seasonality of these waves. In addition, long distance links that are associated with Rossby waves are the most dominant in the climate network.",

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AU - Ashkenazy, Yosef

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AU - Guez, Oded

AU - Havlin, Shlomo

PY - 2013/9/27

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N2 - The connectivity pattern of networks based on ground level temperature records shows a dense stripe of links in the extra tropics of the southern hemisphere. We show that statistical categorization of these links yields a clear association with the pattern of an atmospheric Rossby wave, one of the major mechanisms associated with the weather system and with planetary scale energy transport. It is shown that alternating densities of negative and positive links are arranged in half Rossby wave distances around 3500, 7000, and 10 000 km and are aligned with the expected direction of energy flow, distribution of time delays, and the seasonality of these waves. In addition, long distance links that are associated with Rossby waves are the most dominant in the climate network.

AB - The connectivity pattern of networks based on ground level temperature records shows a dense stripe of links in the extra tropics of the southern hemisphere. We show that statistical categorization of these links yields a clear association with the pattern of an atmospheric Rossby wave, one of the major mechanisms associated with the weather system and with planetary scale energy transport. It is shown that alternating densities of negative and positive links are arranged in half Rossby wave distances around 3500, 7000, and 10 000 km and are aligned with the expected direction of energy flow, distribution of time delays, and the seasonality of these waves. In addition, long distance links that are associated with Rossby waves are the most dominant in the climate network.

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Dominant imprint of rossby waves in the climate network

Abstract

Funding

UN SDGs

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