气候变化和人类活动对极端径流的影响研究——以潘家口流域为例

doi:10.19640/j.cnki.jtau.2026.02.015

天津农学院学报 ›› 2026, Vol. 33 ›› Issue (2): 87-93.doi: 10.19640/j.cnki.jtau.2026.02.015

气候变化和人类活动对极端径流的影响研究——以潘家口流域为例

王冰, 陈旭, 王星鹏, 程志奇

天津农学院水利工程学院,天津 300392

收稿日期:2025-03-26 出版日期:2026-04-30 发布日期:2026-05-06
作者简介:王冰（1985—）,女,高级工程师,博士,主要从事全球变化背景下水文水资源研究工作。E-mail：314998707@qq.com。
基金资助:
水利工程智能建设与运维全国重点实验室（HESS-2208）

Study on the impact of climate change and human activities on extreme runoff: A case study of the Panjiakou watershed

Wang Bing, Chen Xu, Wang Xingpeng, Cheng Zhiqi

College of Water Conservancy Engineering, Tianjin Agricultural University, Tianjin 300392, China

Received:2025-03-26 Online:2026-04-30 Published:2026-05-06

摘要/Abstract

摘要： 受全球气候变化与人类活动的双重影响,潘家口流域内极端水文事件频发,入库水量持续减少,对下游地区用水安全构成威胁。为探究全球气候变化和人类活动对极端径流变化的贡献率,采用Mann-Kendall突变检验法分析1960—2017年径流序列的突变年份,划分基准期和变化期;运用SWAT模型法、Budyko假设法和弹性系数法,定量分析气候变化和人类活动对径流的影响程度。结果表明：1960—2017年间潘家口流域降水量、潜在蒸散发量和径流深均呈下降趋势,径流序列突变点发生在1980年;基准期（1960—1979年）和突变期（1980—2017年）多年平均径流深分别为68.40、46.79 mm;在特丰水年,SWAT模型法、Budyko假设法、弹性系数法计算得到的气候变化对径流变化的贡献率分别为42.76%、39.68%和35.14%,人类活动对径流变化的贡献率分别为57.24%、60.32%和64.86%;在特枯水年,气候变化的贡献率分别为30.37%、37.45%和35.64%,人类活动的贡献率分别为69.63%、62.55%和64.36%;三种方法均表明,人类活动是极端径流演变的主导因素。研究结果不仅可为极端径流影响分析方法的选择提供重要参考,也可为潘家口流域水资源的优化调度与可持续开发提供科学依据。

关键词: 气候变化, 人类活动, SWAT模型, Budyko假设法, 弹性系数法

Abstract: Due to the combined impact of global climate change and human activities, extreme hydrological events in the Panjiakou Basin have become more frequent, leading to a continuous reduction in inflow, which poses a significant threat to water security in downstream regions. To explore the contributions of global climate change and human activities to extreme runoff variations, the Mann-Kendall mutation test was used to analyze the mutation years of runoff data from 1960 to 2017, thereby dividing the baseline and change periods. The SWAT model, Budyko hypothesis, and elasticity coefficient method were applied to quantitatively separate the effects of climate change and human activities on runoff. The results indicated that from 1960 to 2017, there was a downward trend in precipitation, potential evapotranspiration, and runoff depth in the Panjiakou watershed. A significant change point in the runoff series occurred in 1980. The average annual runoff depths during the baseline period（1960—1979）and the post-change period（1980—2017）were 68.40 mm and 46.79 mm, respectively. In years with abundant water, the contributions of climate change and human activities—assessed using the SWAT model, Budyko hypothesis, and elasticity coefficient methods—were 42.76% and 57.24%, 39.68% and 60.32%, 35.14% and 64.86%, respectively. In years with drought, the contributions of climate change and human activities were 30.37% and 69.63%, 37.45% and 62.55%, 35.64% and 64.36%, based on the same three methods. All three methods indicate that human activities are the dominant factor in the evolution of extreme runoff. These findings are of significant reference value for selecting appropriate methods for analyzing extreme runoff impacts, and for optimizing water resource scheduling and sustainable development in the Panjiakou Basin.

Key words: climate change, human activity, SWAT model, Budyko hypothesis, elasticity coefficient method

中图分类号:

TV121

王冰, 陈旭, 王星鹏, 程志奇. 气候变化和人类活动对极端径流的影响研究——以潘家口流域为例[J]. 天津农学院学报, 2026, 33(2): 87-93.

Wang Bing, Chen Xu, Wang Xingpeng, Cheng Zhiqi. Study on the impact of climate change and human activities on extreme runoff: A case study of the Panjiakou watershed[J]. Journal of Tianjin Agricultural University, 2026, 33(2): 87-93.

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http://xuebao.tjau.edu.cn/CN/Y2026/V33/I2/87

参考文献

[1] HE N,GUO W,LAN J,et al.The impact of human activities and climate change on the eco-hydrological processes in the Yangtze River basin[J]. Journal of Hydrology:Regional Studies,2024,53:101753.
[2] LU H,ZHAO R,ZHAO L,et al.Impact of climate change and human activities on the spatiotemporal dynamics of surface water area in Gansu Province,China[J]. Journal of Arid Land,2024,16(6):798-815.
[3] HE S,CHEN K,LIU Z,et al.Exploring the impacts of climate change and human activities on future runoff variations at the seasonal scale[J]. Journal of Hydrology,2023,619:129382.
[4] DAN D,CHUN X,ZHOU H,et al.Quantitative impacts of climate change and human activities on runoff in the Huolin River catchment[J]. Journal of Water and Climate Change,2022,13(11):3851-3866.
[5] WANG X,ZHANG S,TIAN Y.Assessment of runoff changes in the sub-basin of the upper reaches of the Yangtze River basin,China based on multiple methods[J]. Journal of Arid Land,2024,16(4):461-482.
[6] XU Y,CHEN Y,REN Y,et al.Attribution of streamflow changes considering spatial contributions and driver interactions based on hydrological modeling[J]. Water Resources Management,2023,37(5):1859-1877.
[7] SHAHID M,RAHMAN K U,HAIDER S,et al.Quantitative assessment of regional land use and climate change impact on runoff across Gilgit watershed[J]. Environmental Earth Sciences,2021,80(22):743-761.
[8] XUE D,ZHOU J,ZHAO X,et al.Impacts of climate change and human activities on runoff change in a typical arid watershed,NW China[J]. Ecological Indicators,2021,121:107013.
[9] ZHU Y,LI B,LIAN L,et al.Quantifying the effects of climate variability,land-use changes,and human activities on drought based on the SWAT-PDSI model[J]. Remote Sensing,2022,14(16):3895.
[10] 魏诗泉,任雪娟. 京津冀地区7—9月极端降水分型及趋势分析[J]. 气象科学,2024,44(2):235-245.
[11] 庄园煌,陈宏,孙密娜,等. 气候变化背景下海河流域极端降水特征及不同重现期降水量估计[J]. 大气科学学报,2025,48(2):278-288.
[12] 刘彦宏,李泽霖,张磊,等. 1961—2020年陕南地区极端降水的时空变化特征[J]. 西北林学院学报,2024,39(6):207-215.
[13] DONG M,LIU M,YIN L,et al.Concept and practices involved in comprehensive river control based on the synergy among flood control,ecological restoration,and urban development:A case study on a valley reach of Luanhe River in a semiarid region in North China[J]. Water,2022,14(9):1413.
[14] 陈治荣,陈克龙,曹广超,等. 1956—2016年祁连山南坡河流径流变化特征研究[J]. 生态科学,2024,43(3):153-160.
[15] WU J,ZHENG H,XI Y.SWAT-based runoff simulation and runoff responses to climate change in the headwaters of the Yellow River,China[J]. Atmosphere,2019,10(9):509.
[16] NEITSCH S L,ARNOLD J G,KINIRY J R,et al.Soil and water assessment tool theoretical documentation version 2009[Z]. Texas Water Resources Institute,2011.
[17] 宋增芳,曾建军,金彦兆,等. 基于SWAT模型和SUFI-2算法的石羊河流域月径流分布式模拟[J]. 水土保持通报,2016,36(5):172-177.
[18] ECKHARDT K,ARNOLD J G.Automatic calibration of a distributed catchment model[J]. Journal of Hydrology,2001,251(1/2):103-109.
[19] LIU T,HUANG H Q,SHAO M A,et al.Integrated assessment of climate and human contributions to variations in streamflow in the Ten Great Gullies Basin of the Upper Yellow River,China[J]. Journal of Hydrology and Hydromechanics,2020,68(3):249-259.
[20] DZHAMALOV R G,ZEKTSER I S,KRICHEVETS G N,et al.Changes in groundwater runoff under the effect of climate and anthropogenic impact[J]. Water Resources,2008,35(1):15-22.
[21] SU T,WANG S,SUN S,et al.Analysis of actual evapotranspiration changes in China based on multi- source data and assessment of the contribution of driving factors using an extended Budyko framework[J]. Theoretical and Applied Climatology,2024,155(3):1653-1666.
[22] CHOUDHURY B.Evaluation of an empirical equation for annual evaporation using field observations and results from a biophysical model[J]. Journal of Hydrology,1999,216(1/2):99-110.
[23] MELO P A,ALVARENGA L A,TOMASELLA J,et al.Uncertainty analysis on long-term runoff projection from the Budyko framework and a conceptual hydrological model[J]. Journal of Water and Climate Change,2024,15(8):3850-3866.
[24] YANG H,YANG D,LEI Z,et al. New analytical derivation of the mean annual water-energy balance equation[J]. Water Resources Research,2008,44(3):2007WR006135.
[25] HOU T,ZHU Y,LÜ H,et al.Parameter sensitivity analysis and optimization of Noah land surface model with field measurements from Huaihe River Basin,China[J]. Stochastic Environmental Research and Risk Assessment,2015,29(5):1383-1401.
[26] ZHAN C,ZENG S,JIANG S,et al.An integrated approach for partitioning the effect of climate change and human activities on surface runoff[J]. Water Resources Management,2014,28(11):3843-3858.
[27] 吴大光,王高旭,魏俊彪,等. 海河流域径流演变规律及其对气候变化的响应[J]. 水科学与工程技术,2011(6):11-14.
[28] 李东龙,王文圣,李跃清. 中国主要江河年径流变化特性分析[J]. 水电能源科学,2011,29(11):1-5.
[29] 鲁菲儿,王冰,陈旭. 全球气候变化和人类活动对潘家口流域径流影响的研究[J]. 北京水务,2024(3):66-72.
[30] 王婧雯,冉佳琳,吴伟,等. 人类活动与气候变化对海河流域径流影响的尺度效应[J]. 生态与农村环境学报,2024,40(6):757-765.
[31] 王磊. 气候变化和人类活动对海河流域径流变化的影响[J]. 水利科技与经济,2019,25(4):49-55.

气候变化和人类活动对极端径流的影响研究——以潘家口流域为例

Study on the impact of climate change and human activities on extreme runoff: A case study of the Panjiakou watershed

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