Spatiotemporal differentiation and evolution trend of critical climatic variables in different ecological regions of China

doi:10.13287/j.1001-9332.202501.024

Abstract

Abstract: Under the background of intensifying global changes, the evolution of climate trends has received signi-ficant attention. Few studies have conducted a comprehensive evaluation of the temporal dynamics of essential climate parameters across diverse ecological zones in China. Based on the data from 1525 stations spanning China’s mainland between 1961 and 2021, we employed the Theil-Sen slope method, Mann-Kendall trend test, and spatial analysis methodologies to analyze the spatiotemporal patterns and trends of critical climate parameters within four ecological regions: the northeast humid and semi-humid ecological region (Ⅰ), the southern humid ecological region (Ⅱ), the northern arid and semi-arid ecological region (Ⅲ), and the Qinghai-Tibet Plateau ecological region (Ⅳ). The findings revealed that the spatial heterogeneity of climate variables across the four regions was more pronounced than their temporal variability, with the former exhibiting moderate to strong variability and the latter predominantly showing weak variability. Except for relative humidity, the intra-annual variations of other climate variables (precipitation, air temperature, vapor pressure deficit, net surface radiation, and potential evapotranspiration) all follow unimodal curves, with peaks typically occurring between May and August. The highest probability of peak occurred in July. From 1961 to 2021, temporal trends in climate variables showed significant differences among different regions. Precipitation increased in all four regions, but was only significant in Region Ⅳ (0.62 mm·a^-1). Air temperature significantly increased in all regions, with annual rises ranging from 0.02 (Region Ⅱ) to 0.03 ℃ (Regions Ⅰ, Ⅲ, and Ⅳ). Relative humidity significantly declined by 0.03%·a^-1 (Regions Ⅰ and Ⅳ) to 0.05%·a^-1 (Region Ⅲ). The vapor pressure deficit increased by 0.5 (Region Ⅰ) to 0.8 Pa·a^-1 (Region Ⅲ). The net radiation significantly decreased by 2.1 (Region Ⅳ) to 4.4 MJ·m^-2·a^-1 (Region Ⅰ). Annual potential evapotranspiration significantly decreased by 0.99 mm·a^-1 in Region Ⅰ and significantly increased by 0.40 mm·a^-1 in Region Ⅳ. China was experiencing a “warming and drying” trend as indicated by air temperature and relative humidity, while changes in air temperature and precipitation indicated an overall “warming and wetting” trend, particularly in Region Ⅳ.

Key words: climate change, meteorological factor, spatiotemporal differentiation, trend analysis, ecological region

ZHONG Yong, GAO Lei, PENG Xinhua, ZHANG Shuaipu, GAN Lei. Spatiotemporal differentiation and evolution trend of critical climatic variables in different ecological regions of China[J]. Chinese Journal of Applied Ecology, 2025, 36(1): 249-258.

References

[1] World Meteorological Organization (WMO). State of the Global Climate 2023 (WMO-No. 1347). Geneva: WMO, 2024
[2] Liu L, Xu H, Liu S, et al. China’s response to extreme weather events must be long term. Nature Food, 2023, 4: 1022-1023
[3] Rezaei EE, Webber H, Asseng S, et al. Climate change impacts on crop yields. Nature Reviews Earth & Environment, 2023, 4: 831-846
[4] Zhang Y, Zhang YJ, Cheng L, et al. Have China’s drylands become wetting in the past 50 years? Journal of Geographical Sciences, 2023, 33: 99-120
[5] 陈璐, 蒋明伟, 杨彬林, 等. 黄河上游气象水文要素演化规律分析. 高原农业, 2024, 8(2): 127-134
[6] 谭希贤, 段明铿. 我国气温和降水局地同期相关的时空变化特征. 地球物理学进展, 2024, 39(3): 905-915
[7] 袁瑞瑞, 黄萧霖, 郝璐. 近40年中国饱和水汽压差时空变化及影响因素分析. 气候与环境研究, 2021, 26(4): 413-424
[8] 白鹏, 蔡常鑫. 1982—2019年中国陆地蒸散发变化的归因分析. 地理学报, 2023, 78(11): 2750-2762
[9] 高江波, 黄姣, 李双成, 等. 中国自然地理区划研究的新进展与发展趋势. 地理科学进展, 2010, 29(11): 1400-1407
[10] 傅伯杰, 刘国华, 陈利顶, 等. 中国生态区划方案. 生态学报, 2001, 21(1): 1-6
[11] 孙然好, 李卓, 陈利顶. 中国生态区划研究进展: 从格局、功能到服务. 生态学报, 2018, 38(15): 5271-5278
[12] 谢高地, 张昌顺, 张林波, 等. 保持县域边界完整性的中国生态区划方案. 自然资源学报, 2012, 27(1): 154-162
[13] 朱光磊, 佟守正, 赵春子. 嫩江流域参考作物蒸散量时空变化及其气候归因. 应用生态学报, 2022, 33(1): 201-209
[14] Allen RG, Pereira LS, Raes D, et al. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO Irrigation and Drainage Paper 56. Rome: Food and Agriculture Organization of the United Nations, 1998
[15] 童成立, 张文菊, 汤阳, 等. 逐日太阳辐射的模拟计算. 中国农业气象, 2005, 26(3): 165-169
[16] 左大康, 王懿贤, 陈建绥. 中国地区太阳总辐射的空间分布特征. 气象学报, 1963(1): 78-96
[17] 吴燕锋, 巴克巴特尔, 李维, 等. 基于综合气象干旱指数的1961—2012年阿勒泰地区干旱时空演变特征. 应用生态学报, 2015, 26(2): 512-520
[18] Nielsen DR, Bouma J. Soil Spatial Variability. Wageningen: Pudoc, 1985
[19] 姜晓剑, 刘小军, 黄芬, 等. 逐日气象要素空间插值方法的比较. 应用生态学报, 2010, 21(3): 624-630
[20] 蒋帅, 张黎, 景元书, 等. 1981—2015年中国区域极端气候事件的时空分布特征. 水土保持研究, 2023, 30(6): 295-306
[21] 张一然, 周德刚, 郭晓峰. 变暖背景下黄河源区气候响应特征及对径流的影响. 中国科学: 地球科学, 2024, 54(3): 862-873
[22] 陈峪, 高歌, 任国玉, 等. 中国十大流域近40多年降水量时空变化特征. 自然资源学报, 2005, 20(5): 637-643
[23] 黄辉, 郑昌玲, 张劲松, 等. 1980—2019年南太行地区气候变化趋势. 应用生态学报, 2022, 33(8): 2139-2145
[24] Yao N, Li Y, Lei TJ, et al. Drought evolution, severity and trends in China’s mainland over 1961-2013. Science of the Total Environment, 2018, 616-617: 73-89
[25] 吴清源. 亚洲夏季风对全球变暖的响应及其反馈归因. 博士论文. 南京: 南京信息工程大学, 2023
[26] 李颖辉, 齐贵增, 冯荣荣, 等. 秦岭北麓油松径向生长对气候变化的响应. 应用生态学报, 2022, 33(8): 2043-2050
[27] 琚玉枫, 高演辰, 张戈, 等. 华北平原正向“暖干化”演变. 生态学报, 2024, 44(17): 7631-7645
[28] Sun F, Li YP, Chen YN, et al. The dominant warming season shifted from winter to spring in the arid region of Northwest China. NPJ Climate and Atmospheric Science, 2024, 7: 178
[29] 中国气象局气候变化中心. 中国气候变化蓝皮书(2024). 北京: 科学出版社, 2024
[30] 于水, 张晓龙, 刘志娟, 等. 1961—2020年松花江流域极端气候指数的时空变化特征. 应用生态学报, 2023, 34(4): 1091-1101
[31] 徐荣潞, 李宝富, 廉丽姝. 1960—2015年西北干旱区相对湿度时空变化与气候要素的定量关系. 水土保持研究, 2020, 27(6): 233-239
[32] 谢云, 张汝正, 殷水清, 等. 1961—2010年全球变暖背景下中国空气湿度长期变化特征. 水科学进展, 2020, 31(5): 674-684
[33] 苑全治, 吴绍洪, 戴尔阜, 等. 1961—2015年中国气候干湿状况的时空分异. 中国科学: 地球科学, 2017, 47(11): 1339-1348
[34] 陈发虎, 谢亭亭, 杨钰杰, 等. 我国西北干旱区“暖湿化”问题及其未来趋势讨论. 中国科学: 地球科学, 2023, 53(6): 1246-1262
[35] Wang H, Sun FB, Wang TT, et al. On the pattern and attribution of pan evaporation over China (1951-2021). Journal of Hydrometeorology, 2023, 24: 2023-2033
[36] Li ZJ, Su BD, Gao MN, et al. Will the ‘evapotranspiration paradox’ phenomenon exist across China in the future? International Journal of Climatology, 2023, 43: 7132-7151
[37] Brutsaert W, Parlange MB. Hydrologic cycle explains the evaporation paradox. Nature, 1998, 396: 30
[38] 刘昌明, 张丹. 中国地表潜在蒸散发敏感性的时空变化特征分析. 地理学报, 2011, 66(5): 579-588
[39] Hu JF, Zhao GJ, Li PL, et al. Variations of pan evaporation and its attribution from 1961 to 2015 on the Loess Plateau, China. Natural Hazards, 2021, 111: 1199-1217
[40] Qin MS, Hao L, Sun L, et al. Climatic controls on watershed reference evapotranspiration varied during 1961-2012 in Southern China. Journal of the American Water Resources Association, 2018, 55: 189-208
[41] Zhong ZQ, He B, Wang YP, et al. Disentangling the effects of vapor pressure deficit on northern terrestrial vegetation productivity. Science Advances, 2023, 9: eadf3166
[42] Yuan WP, Zheng YZ, Piao SL, et al. Increased atmospheric vapor pressure deficit reduces global vegetation growth. Science Advances, 2019, 5: eaax1396