Variations of air temperature differences at different temporal scales over the Tibetan Plateau since 1961 and their possible causes

Author:

Lin Jingjing12ORCID,Zhou Guangsheng345ORCID,Zhang Qiang6,Lv Xiaomin3,Fang Feng2,Zhao Guannan7,Miao Ting8

Affiliation:

1. College of Atmospheric Sciences Lanzhou University Lanzhou China

2. Lanzhou Regional Climate Center Gansu Provincial Meteorological Bureau Lanzhou China

3. State Key Laboratory of Severe Weather Chinese Academy of Meteorological Sciences Beijing China

4. Joint Laboratory of Eco‐Meteorology School of Earth Science and Technology, Zhengzhou University Zhengzhou China

5. Collaborative Innovation Center on Forecast Meteorological Disaster Warning and Assessment Nanjing University of Information Science & Technology Nanjing China

6. Key Laboratory of Arid Climate Change and Reducing Disaster of Gansu Province/Key Open Laboratory of Arid Climate Change and Disaster Reduction Institute of Arid Meteorology, China Meteorological Administration Lanzhou China

7. Jiangxi Climate Center Nanchang China

8. The Meteorological Bureau of Jingyuan County Jingyuan China

Abstract

AbstractThe air temperature difference is an essential indicator to measure weather and climate change. The Tibetan Plateau (TP) is a sensitive area to global climate change. The study on its temperature difference variations is of great significance for further understanding the evolution of weather and climate systems, and scientific disaster prevention and mitigation. In this study, the spatio‐temporal evolution characteristics of the temperature difference on daily, monthly, seasonal and annual scales and their possible causes are analysed based on the daily observations at 59 meteorological stations over the TP from 1961 to 2020 and the circulation indexes such as the East Asian summer monsoon, South Asian summer monsoon, midlatitude westerly and TP summer monsoon. The results indicate that the diurnal temperature range (DTR) on the TP tends to decrease from 1961 to 2020. Compared with the situation in the late 20th century, the annual average of the DTR in the eastern TP turns from a nonsignificant increasing trend into a pronounced decreasing trend, while that in the western TP maintains a decreasing trend. This phenomenon is primarily influenced by the minimum and maximum temperature, precipitation and atmospheric circulations. The standardized temperature difference at different temporal scales shows decreasing trends and is distributed in north–south and east–west distribution patterns. The annual temperature range is mainly influenced by the remarkable increase of the minimum temperature, especially in the northern and southeastern TP. Besides, the increases of maximum temperature and precipitation also affect the annual temperature range. In terms of the seasonal temperature range, it is dramatically influenced by different meteorological factors, especially in the northern TP. The monthly temperature range (Mon‐TR) is dramatically influenced by the maximum and minimum temperature in the first and second half years, respectively. Moreover, the circulation systems, such as the midlatitude westerly, South Asian summer monsoon and TP summer monsoon, are the main influencing factors of the temperature difference variations on the TP. The midlatitude westerly have a large influence on Mon‐TR in June and September, and the significantly influenced stations reaches 54.2% and 35.6%. The impact stations of the TP summer monsoon on Mon‐TR is the largest in August, and the significantly influenced stations is 39%. In July, the influenced stations of the TP summer monsoon and South Asian summer monsoon on the Mon‐TR reaches 30.5%–33.9%. The influenced area of the Mon‐TR in June is largest affected by single summer monsoon or westerly index. Previous studies have shown that the warming mechanisms and their influencing factors have changed in the TP since the 21st century. The study results might provide the foundation for a scientific understanding of climate warming on the TP.

Funder

National Natural Science Foundation of China

Publisher

Wiley

Subject

Atmospheric Science

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