Evaluating uncertainty in aerosol forcing of tropical precipitation shifts

A. Peace, B. Booth, L. Regayre, K. Carslaw, D. Sexton, C. Bonfils, J. Rostron
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Abstract

Abstract. An observed southward shift in tropical rainfall over land between 1950 and 1985, followed by a weaker recovery post-1985, has been attributed to anthropogenic aerosol radiative forcing and cooling of the Northern Hemisphere relative to the Southern Hemisphere. We might therefore expect models that have a strong historic hemispheric contrast in aerosol forcing to simulate a further northward tropical rainfall shift in the near-term future when anthropogenic aerosol emission reductions will predominantly warm the Northern Hemisphere. We investigate this paradigm using a perturbed parameter ensemble (PPE) of transient coupled ocean–atmosphere climate simulations that span a range of aerosol radiative forcing comparable to multi-model studies. In the 20th century, in our single-model ensemble, we find no relationship between the magnitude of pre-industrial to 1975 inter-hemispheric anthropogenic aerosol radiative forcing and tropical precipitation shifts. Instead, tropical precipitation shifts are associated with major volcanic eruptions and are strongly affected by internal variability. However, we do find a relationship between the magnitude of pre-industrial to 2005 inter-hemispheric anthropogenic aerosol radiative forcing and future tropical precipitation shifts over 2006 to 2060 under scenario RCP8.5. Our results suggest that projections of tropical precipitation shifts will be improved by reducing aerosol radiative forcing uncertainty, but predictive gains may be offset by temporary shifts in tropical precipitation caused by future major volcanic eruptions.
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评估气溶胶强迫热带降水转变的不确定性
摘要观测到的1950年至1985年期间热带陆地降水向南移动,随后在1985年后出现较弱的恢复,这可归因于人为气溶胶辐射强迫和北半球相对于南半球的冷却。因此,我们可以预期,在气溶胶强迫方面具有强烈历史半球对比的模式,将在近期模拟进一步向北的热带降雨转移,届时人为气溶胶排放减少将主要使北半球变暖。我们利用一个瞬态耦合海洋-大气气候模拟的扰动参数集合(PPE)来研究这一范式,该模拟涵盖了一系列可与多模式研究相比较的气溶胶辐射强迫。在20世纪,在我们的单模式综合中,我们发现工业化前至1975年半球间人为气溶胶辐射强迫的大小与热带降水变化之间没有关系。相反,热带降水变化与大型火山爆发有关,并受到内部变率的强烈影响。然而,我们确实发现在RCP8.5情景下,工业化前至2005年半球间人为气溶胶辐射强迫的强度与2006年至2060年未来热带降水变化之间存在关系。我们的研究结果表明,通过降低气溶胶辐射强迫的不确定性,热带降水变化的预测将得到改善,但预测的收益可能会被未来主要火山爆发引起的热带降水的暂时变化所抵消。
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