Contributions to regional precipitation change and its polar-amplified pattern under warming

D. Bonan, N. Feldl, M. Zelinka, L. Hahn
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引用次数: 1

Abstract

The polar regions are predicted to experience the largest relative change in precipitation in response to increased greenhouse-gas concentrations, where a substantial absolute increase in precipitation coincides with small precipitation rates in the present-day climate. The reasons for this amplification, however, are still debated. Here, we use an atmospheric energy budget to decompose regional precipitation change from climate models under greenhouse-gas forcing into contributions from atmospheric radiative feedbacks, dry-static energy flux divergence changes, and surface sensible heat flux changes. The polar-amplified relative precipitation change is shown to be a consequence of the Planck feedback, which, when combined with larger polar warming, favors substantial atmospheric radiative cooling that balances increases in latent heat release from precipitation. Changes in the dry-static energy flux divergence contribute modestly to the polar-amplified pattern. Additional contributions to the polar-amplified response come, in the Arctic, from the cloud feedback and, in the Antarctic, from both the cloud and water vapor feedbacks. The primary contributor to the intermodel spread in the relative precipitation change in the polar region is also the Planck feedback, with the lapse rate feedback and dry-static energy flux divergence changes playing secondary roles. For all regions, there are strong covariances between radiative feedbacks and changes in the dry-static energy flux divergence that impact the intermodel spread. These results imply that constraining regional precipitation change, particularly in the polar regions, will require constraining not only individual feedbacks but also the covariances between radiative feedbacks and atmospheric energy transport.
变暖下区域降水变化及其极放大型的贡献
由于温室气体浓度的增加,预计极地地区将经历最大的降水相对变化,那里的降水绝对大幅增加与当今气候中较小的降水率相吻合。然而,这种放大的原因仍存在争议。在此,我们利用大气能量收支将温室气体强迫下气候模式的区域降水变化分解为大气辐射反馈、干静态能量通量发散变化和地表感热通量变化的贡献。极地放大的相对降水变化被证明是普朗克反馈的结果,当与较大的极地变暖相结合时,有利于大量的大气辐射冷却,从而平衡降水潜热释放的增加。干静态能量通量散度的变化对极放大型有轻微贡献。在北极,对极地放大响应的额外贡献来自云反馈,在南极,来自云和水蒸气反馈。在极区相对降水变化中,模式间扩展的主要贡献者也是普朗克反馈,而递减率反馈和干静态能量通量散度变化起次要作用。在所有区域,辐射反馈与影响模式间传播的干静态能量通量散度变化之间存在较强的协方差。这些结果表明,限制区域降水变化,特别是在极地地区,不仅需要限制个别反馈,还需要限制辐射反馈与大气能量输运之间的协方差。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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