观测到的水文气象变化归因于人类作用力

D. A. Herrera, B. I. Cook, John Fasullo, K. Anchukaitis, Marc Alessi, Carlos J. Martinez, Colin P. Evans, Xiaolu Li, Kelsey N. Ellis, Rafael Mendez, T. Ault, A. Centella, Tannecia S. Stephenson, Michael A. Taylor
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摘要

观测和建模研究表明,在二十世纪和二十一世纪初,由于人为气候变化,全球水文气候发生了显著变化。在这篇综述中,我们分析了有关可归因于人为强迫的水文气候观测变化、这些变化背后的物理和生物机制以及当前探测和归因方法的优势和局限性的最新文献。降水量减去蒸发量(P-E)的大小和空间模式的变化与温度升高导致的水汽含量增加是一致的。虽然热力学解释了大部分观测到的变化,但由于观测和气候模型的局限性,动力学的贡献尚未得到很好的制约,特别是在区域和地方尺度上。人为气候变化也增加了北美西南部、南美西南部、地中海和加勒比地区同期干旱的严重性和可能性。极端降水事件频率的增加和物候的变化也被归因于人为气候变化。虽然植物生理在调节水文气候和反向调节水文气候方面的作用仍存在很大的不确定性,但新出现的证据表明,冠层需水量的增加和生长季节的延长抵消了用水效率提高所带来的节水效果。
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Observed changes in hydroclimate attributed to human forcing
Observational and modeling studies indicate significant changes in the global hydroclimate in the twentieth and early twenty-first centuries due to anthropogenic climate change. In this review, we analyze the recent literature on the observed changes in hydroclimate attributable to anthropogenic forcing, the physical and biological mechanisms underlying those changes, and the advantages and limitations of current detection and attribution methods. Changes in the magnitude and spatial patterns of precipitation minus evaporation (P–E) are consistent with increased water vapor content driven by higher temperatures. While thermodynamics explains most of the observed changes, the contribution of dynamics is not yet well constrained, especially at regional and local scales, due to limitations in observations and climate models. Anthropogenic climate change has also increased the severity and likelihood of contemporaneous droughts in southwestern North America, southwestern South America, the Mediterranean, and the Caribbean. An increased frequency of extreme precipitation events and shifts in phenology has also been attributed to anthropogenic climate change. While considerable uncertainties persist on the role of plant physiology in modulating hydroclimate and vice versa, emerging evidence indicates that increased canopy water demand and longer growing seasons negate the water-saving effects from increased water-use efficiency.
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