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Fast and slow shifts of the zonal‐mean intertropical convergence zone in response to an idealized anthropogenic aerosol
Author(s) -
Voigt Aiko,
Pincus Robert,
Stevens Bjorn,
Bony Sandrine,
Boucher Olivier,
Bellouin Nicolas,
Lewinschal Anna,
Medeiros Brian,
Wang Zhili,
Zhang Hua
Publication year - 2017
Publication title -
journal of advances in modeling earth systems
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.03
H-Index - 58
ISSN - 1942-2466
DOI - 10.1002/2016ms000902
Subject(s) - intertropical convergence zone , aerosol , convergence zone , environmental science , climatology , atmospheric sciences , forcing (mathematics) , radiative forcing , equator , climate model , climate change , meteorology , geology , latitude , precipitation , geography , oceanography , geodesy
Abstract Previous modeling work showed that aerosol can affect the position of the tropical rain belt, i.e., the intertropical convergence zone (ITCZ). Yet it remains unclear which aspects of the aerosol impact are robust across models, and which are not. Here we present simulations with seven comprehensive atmosphere models that study the fast and slow impacts of an idealized anthropogenic aerosol on the zonal‐mean ITCZ position. The fast impact, which results from aerosol atmospheric heating and land cooling before sea‐surface temperature (SST) has time to respond, causes a northward ITCZ shift. Yet the fast impact is compensated locally by decreased evaporation over the ocean, and a clear northward shift is only found for an unrealistically large aerosol forcing. The local compensation implies that while models differ in atmospheric aerosol heating, this does not contribute to model differences in the ITCZ shift. The slow impact includes the aerosol impact on the ocean surface energy balance and is mediated by SST changes. The slow impact is an order of magnitude more effective than the fast impact and causes a clear southward ITCZ shift for realistic aerosol forcing. Models agree well on the slow ITCZ shift when perturbed with the same SST pattern. However, an energetic analysis suggests that the slow ITCZ shifts would be substantially more model‐dependent in interactive‐SST setups due to model differences in clear‐sky radiative transfer and clouds. We also discuss implications for the representation of aerosol in climate models and attributions of recent observed ITCZ shifts to aerosol.

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