The influence of the precipitation recycling process on the shift to heavy precipitation over the Tibetan Plateau in the summer

Zhang, Boyuan; He, Yongli; Ren, Yu; Huang, Bo; Peng, Yangrui; Wang, Shanshan; Guan, Xiaodan

doi:10.3389/feart.2023.1078501

Cited by 2 publications

(2 citation statements)

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“…In addition to the increasing atmospheric moisture content under a warming climate (Allen & Ingram, 2002; Trenberth, 1999), extreme precipitation is also influenced by other thermodynamic and dynamic properties such as intensified water recycling (Nie & Sun, 2022; Zhang et al., 2023), changes in the temperature lapse rate and vertical wind velocities (Pfahl et al., 2017; Sugiyama et al., 2010; O'Gorman & Schneider, 2009). On regional scales, dynamic factors and local factors such as topography can make the response of precipitation extremes more complex, especially when convection is important (O’Gorman, 2015).…”

Section: Discussionmentioning

confidence: 99%

Subdaily Extreme Precipitation and Its Linkage to Global Warming Over the Tibetan Plateau

Ma,

Tang,

et al. 2023

JGR Atmospheres

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The spatiotemporal characteristics of sub‐daily extreme precipitation over the Tibetan Plateau (TP) have undergone significant changes due to global warming. In this study, we employed the high‐resolution Weather Research and Forecasting regional climate model to conduct a series of historical and projection simulations under representative concentration pathways (RCPs), especially RCP4.5 and RCP8.5. The aim was to investigate the past and future climatologies and spatiotemporal evolution of sub‐daily precipitation extremes using newly proposed sub‐daily extreme precipitation indices (EPIs). The results show that projected changes in precipitation amount, particularly during wet hours, exhibit spatial disparaties. Notably, there are significant decreases along the southern border of the TP and over the western TP, while obvious increases are observed over the inner TP. The southeastern TP, western TP, and southern border of the TP are expected to experience less frequent, shorter duration, and more intense precipitation on an hourly basis. The TP, as a whole, has demonstrated significantly increasing trends in moderate‐to‐heavy precipitation frequencies, along with consistent decreasing trends in precipitation events with short, medium, and long durations. Furthermore, it is predicted that the relationship between extreme precipitation and temperature will deviate from the Clausius‐Clapeyron (C‐C) relationship toward the double C‐C relationship in the far‐future under RCP8.5, particularly over the southeastern TP. Additionally, there are robust correlations between the intensity‐related EPIs and elevation. This indicates that, at the local scale, the complex topography of the region may play a crucial role in shaping the non‐uniform distribution of precipitation extremes by modulating associated upward motion.

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Section: Discussionmentioning

confidence: 99%

Subdaily Extreme Precipitation and Its Linkage to Global Warming Over the Tibetan Plateau

Ma,

Tang,

et al. 2023

JGR Atmospheres

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“…The external input water vapor dominates the water vapor source of the plateau precipitation. A recent study in the same region indicates that the internal cycle (87.2%) contributes more to the precipitation shift than the external cycle (12.8%), and precipitation recycling contributes more to heavy precipitation than to light precipitation [38].…”

Section: Introductionmentioning

confidence: 91%

Contribution of Evaporation to Precipitation Changes in the Yangtze River Basin—Precipitation Recycling

2023

Water

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Locally evaporated water vapor is an important source of precipitation in China. The spatiotemporal variation characteristics of the precipitation recycling ratio (ρ) in the Yangtze River Basin (YRB) in 1979–2020 were calculated and analyzed, and the contribution of internal and external cycling precipitation changes to the total precipitation changes in YRB under climate change was studied. The results show that the annual average ρ in YRB is approximately 10.3%, with the highest value of 21.8% in summer, lower than 10% in spring and autumn, and the lowest in winter, with only approximately 3.5%. Over the past 40 years, the annual average ρ in YRB has shown an increasing trend, with an increased rate of 0.4%/10a, especially in summer, with an increasing rate of 1.2%/10a. In terms of spatial distribution, ρ in YRB shows an obvious difference between the eastern and western regions, with that in the upstream western region being significantly higher than that in the downstream eastern region. The annual average ρ in the upstream region was 15–35% and can reach 20–50% in summer. The annual average ρ in the downstream region is below 10%. In general, precipitation formed by advection moisture accounts for the majority of the total precipitation in YRB. From 1979 to 2020, the annual precipitation in YRB showed an increasing trend. The cumulative increase is about 47.4 mm, of which 68.9% was contributed by local evaporation, and 31.1% was contributed by external moisture.

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The influence of the precipitation recycling process on the shift to heavy precipitation over the Tibetan Plateau in the summer

Cited by 2 publications

References 56 publications

Subdaily Extreme Precipitation and Its Linkage to Global Warming Over the Tibetan Plateau

Subdaily Extreme Precipitation and Its Linkage to Global Warming Over the Tibetan Plateau

Contribution of Evaporation to Precipitation Changes in the Yangtze River Basin—Precipitation Recycling

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