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Relationship of extreme precipitation, surface air temperature, and dew point temperature across the Tibetan Plateau

Author

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  • Zhiwei Yong

    (Southwest Petroleum University)

  • Junnan Xiong

    (Southwest Petroleum University
    Chinese Academy of Sciences)

  • Zegen Wang

    (Southwest Petroleum University)

  • Weiming Cheng

    (Chinese Academy of Sciences)

  • Jiawei Yang

    (Southwest Petroleum University)

  • Quan Pang

    (Southwest Petroleum University)

Abstract

Global warming is expected to have profound socio-economic and environmental consequences, and one of the key concerns is extreme precipitation. The classic theory indicates that the variation of extreme precipitation will follow the thermodynamically based Clausius-Clapeyron relation (increasing at a rate of approximately 7%/°C). However, the interaction and the seasonal variation of the relationship between extreme precipitation and temperature has not been thoroughly integrated. Here, we use quantile regression and the binning method to process meteorological station data and the reanalysis data from 78 stations on the Tibetan Plateau (TP), and estimate the sensitivity and dependency of extreme precipitation to both surface air temperature and dew point temperature. The results indicate that the majority of the meteorological stations experience a positive scaling between extreme precipitation and surface air temperature, with the median of surface air temperature scaling close to 2.5%/°C. With regard to scaling during individual seasons, 80% of stations possess negative scaling of the 99th percentile of extreme precipitation with temperature in summer, while 63 stations (81% of the total) display positive trends in winter, and the other 19% have negative scaling. A stronger scaling (3.5%/°C) occurs between dewpoint temperature and extreme precipitation. For surface air temperature 8 °C, relative humidity decreases with increasing temperature and dewpoint depression increases, so dewpoint temperature increases more slowly than temperature, resulting in the stronger scaling relationship with dewpoint temperature. The depression of dewpoint temperature presents a slight decrease in −3–8 °C interval, but dewpoint temperature increases faster than other intervals, and the scaling relationship of dewpoint temperature is consistently larger than with surface air temperature due to the small increasing rate with dewpoint temperature and increasing extreme precipitation intensity. Our results emphasize that the increasing temperature has clear scaling and seasonal relationship with extreme precipitation on the TP, and the atmospheric humidity variation has an effect on the overall difference in the scaling relationships of extreme precipitation with surface air temperature and dewpoint temperature. The variations of seasonality and the effects of atmospheric humidity for extreme precipitation should also be carefully considered in future research.

Suggested Citation

  • Zhiwei Yong & Junnan Xiong & Zegen Wang & Weiming Cheng & Jiawei Yang & Quan Pang, 2021. "Relationship of extreme precipitation, surface air temperature, and dew point temperature across the Tibetan Plateau," Climatic Change, Springer, vol. 165(1), pages 1-22, March.
    • Handle: RePEc:spr:climat:v:165:y:2021:i:1:d:10.1007_s10584-021-03076-2
    DOI: 10.1007/s10584-021-03076-2
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    References listed on IDEAS

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    1. Seung-Ki Min & Xuebin Zhang & Francis W. Zwiers & Gabriele C. Hegerl, 2011. "Human contribution to more-intense precipitation extremes," Nature, Nature, vol. 470(7334), pages 378-381, February.
    2. Jiawei Bao & Steven C. Sherwood & Lisa V. Alexander & Jason P. Evans, 2017. "Future increases in extreme precipitation exceed observed scaling rates," Nature Climate Change, Nature, vol. 7(2), pages 128-132, February.
    3. Junnan Xiong & Chongchong Ye & Weiming Cheng & Liang Guo & Chenghu Zhou & Xiaolei Zhang, 2019. "The Spatiotemporal Distribution of Flash Floods and Analysis of Partition Driving Forces in Yunnan Province," Sustainability, MDPI, vol. 11(10), pages 1-18, May.
    4. Conrad Wasko & Rory Nathan, 2019. "The local dependency of precipitation on historical changes in temperature," Climatic Change, Springer, vol. 156(1), pages 105-120, September.
    5. Jane Qiu, 2007. "Riding on the roof of the world," Nature, Nature, vol. 449(7161), pages 398-402, September.
    6. Nathan Forsythe & Hayley J. Fowler & Xiao-Feng Li & Stephen Blenkinsop & David Pritchard, 2017. "Karakoram temperature and glacial melt driven by regional atmospheric circulation variability," Nature Climate Change, Nature, vol. 7(9), pages 664-670, September.
    7. V. Kharin & F. Zwiers & X. Zhang & M. Wehner, 2013. "Changes in temperature and precipitation extremes in the CMIP5 ensemble," Climatic Change, Springer, vol. 119(2), pages 345-357, July.
    8. Wei Zhang & Gabriele Villarini & Michael Wehner, 2019. "Contrasting the responses of extreme precipitation to changes in surface air and dew point temperatures," Climatic Change, Springer, vol. 154(1), pages 257-271, May.
    9. Robert J. Allen & Rainer Luptowitz, 2017. "El Niño-like teleconnection increases California precipitation in response to warming," Nature Communications, Nature, vol. 8(1), pages 1-15, December.
    10. Myles R. Allen & William J. Ingram, 2002. "Constraints on future changes in climate and the hydrologic cycle," Nature, Nature, vol. 419(6903), pages 224-232, September.
    11. Wei Zhang & Gabriele Villarini, 2017. "Heavy precipitation is highly sensitive to the magnitude of future warming," Climatic Change, Springer, vol. 145(1), pages 249-257, November.
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