Changes in the mean and variability of temperature and precipitation over global land areas

O. Alizadeh
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Abstract

The frequency and intensity of extreme weather and climate events may change in response to shifts in the mean and variability of climate, which pose high risks to societies and natural ecosystems. Gridded near-surface temperature, precipitation, and the number of wet days from the Climatic Research Unit dataset were analyzed for two 30 year periods to explore changes in the mean and variability of temperature and precipitation over global land areas in the recent period (1991–2020) compared to the reference period (1951–1980). Global land areas are characterized by warmer and slightly wetter conditions in the recent period, while the variability of temperature and precipitation has remained nearly unchanged. Changes in the mean and variability of both temperature and precipitation are also analyzed over tropical, subtropical, and midlatitude land areas. The annual mean temperature over all these three latitudinal regions has increased in the recent period compared to the reference period, with the highest increase in subtropical and midlatitude land areas (0.7 ∘C), followed by tropical land areas (0.5 ∘C), while temperature variability has remained nearly unchanged. The annual precipitation has decreased over tropical, subtropical, and midlatitude land areas in the recent period compared to the reference period. Precipitation variability has not changed considerably over subtropical land areas. However, it has substantially increased over tropical land areas, which indicates a higher risk of droughts and periods of excess water in the recent period. In contrast, precipitation variability has decreased over midlatitude land areas, indicating narrower swings between wet and dry conditions, which decrease the risk of droughts and periods of excess water in the recent period.
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全球陆地区域温度和降水的平均和变率变化
极端天气和气候事件的频率和强度可能会随着气候平均值和变率的变化而变化,这对社会和自然生态系统构成了高风险。对气候研究单位数据集的近地表温度、降水和湿日数进行了两个30年周期的网格化分析,以探讨近期(1991-2020年)与参考期(1951-1980年)相比全球陆地区域温度和降水的平均和变率变化。最近一段时期,全球陆地面积的特征是变暖和略湿润,而温度和降水的变率几乎保持不变。还分析了热带、亚热带和中纬度陆地地区温度和降水的平均和变率变化。与参考时期相比,这三个纬度地区的年平均气温最近都有所上升,其中亚热带和中纬度地区的气温上升幅度最大(0.7°C),其次是热带地区(0.5°C),而温度变化几乎保持不变。与参考期相比,近年来热带、亚热带和中纬度陆地地区的年降水量有所减少。在亚热带陆地地区,降水变率没有明显变化。然而,在热带陆地地区,它已经大大增加,这表明在最近一段时间内,干旱和水资源过剩的风险更高。相比之下,中纬度陆地地区的降水变率有所下降,表明干湿条件之间的波动缩小,这降低了最近一段时期发生干旱和水分过剩的风险。
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