黑河上游出山径流演变多时间尺度归因分析
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作者单位:

(1.中国科学院西北生态环境资源研究院干旱区生态安全与可持续发展全国重点实验室;2.中国科学院大学资源与环境学院 )

作者简介:

邹星怡(2002—),女,硕士研究生,主要从事寒区水文水资源研究。E-mail:zouxingyi24@mails.ucas.ac. cn

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基金项目:

国家自然科学基金项目(52522901,52379030);中国科学院B类先导项目(XDB0720202);甘肃省科技计划项目(24JRRA079);中国科学院青年创新促进会会员项目(2022435)


Multi-time-scale attribution analysis of runoff evolution at mountain outlet of the upper Heihe River
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(1.State Key Laboratory of Ecological Safety and Sustainable Development in Arid Lands, Northwest Institute of EcoEnvironment and Resources, Chinese Academy of Sciences; 2.College of Resources and Environment, University of Chinese Academy of Sciences)

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    摘要:

    基于黑河上游山区1980—2022年水文气象观测数据,采用Mann-Kendall检验与Yamamoto方法识别水文气象要素的趋势及突变特征,构建耦合融雪模块的ABCD-snow模型,并结合任意时间尺度的Budyko水热耦合平衡框架,在考虑多因子耦合作用的基础上,拓展敏感性归因方法,量化了突变前后气候与下垫面因子对黑河上游径流年、季、月等多时间尺度演变的影响。结果表明:研究时段黑河上游径流在1997年发生突变,突变前年径流量呈不显著下降趋势,夏秋季降幅最大,突变后年径流量呈显著上升趋势,除夏季增幅不显著外,其余季节均呈显著增长态势;ABCD-snow模型可有效提升对寒区关键水文过程的刻画能力,率定期Kling-Gupta效率系数由0.75提高至0.90,较好地再现了春季径流融雪补给特征;1980—1997年,夏秋季降水量减少与蒸散发增强导致径流减少,尤其体现在6月、8月、9月,1998—2022年,降雨与融雪增加成为径流增加的主要影响因素,潜在蒸散发增长趋势减缓与归一化植被指数增强进一步促进了流域产流;径流过程对气候变化响应愈发敏感,其相对贡献率由突变前的56.9%升至70.7%,多因子协同效应普遍低于1.1%。

    Abstract:

    Taking mountainous area of the upper Heihe River as study area, this paper uses Mann-Kendall test and Yamamoto mutation test to identify trend and mutation characteristics of hydrometeorological factors based on hydrometeorological observation data from 1980 to 2022. ABCD-snow model coupled with a snowmelt module is established. Combined with Budyko coupled hydrothermal equilibrium framework at arbitrary time scales and considering coupling effect of multiple factors, an improved sensitivity attribution method is adopted to quantify impacts of climatic and underlying surface factors on multi-time-scale (annual, seasonal and monthly) evolution of runoff in the upper Heihe River before and after the mutation. The results show that runoff in the upper Heihe River experienced an abrupt change in 1997 over past 40 years. Before the mutation, annual runoff presented an insignificant decreasing trend with the largest decline in summer and autumn. After the mutation, annual runoff increased significantly; all seasons showed a remarkable growth trend except summer with an insignificant increase. ABCD snow model effectively improves simulation performance of key hydrological processes in cold regions. Its efficiency coefficient during calibration period rose from 0.75 to 0.90, which well reflects snowmelt recharge characteristics of spring runoff. From 1980 to 1997, decrease of rainfall and rise of reference evapotranspiration in summer and autumn led to runoff reduction, especially in June, August and September. From 1998 to 2022, increased rainfall and snowmelt dominated runoff growth, while slowdown of reference evapotranspiration and improvement of normalized difference vegetation index (NDVI) further promoted watershed runoff generation. Runoff became more sensitive to climate change, with relative contribution rate rising from 56.9% to 70.7% before and after mutation, and synergistic effect of multiple factors was generally lower than 1.1%.

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邹星怡,杨林山,贺王含,等.黑河上游出山径流演变多时间尺度归因分析[J].水资源保护,2026,42(3):198-208, 260.(Zou Xingyi, Yang Linshan, He Wanghan, et al. Multi-time-scale attribution analysis of runoff evolution at mountain outlet of the upper Heihe River[J]. Water Resources Protection,2026,42(3):198-208, 260.(in Chinese))

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  • 在线发布日期: 2026-06-16
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