PDF下载

[1]隆院男,张雨林,蒋昌波,等.基于CMIP6的气候变化下资水流域径流响应研究[J].水土保持研究,2024,31(04):114-125.[doi:10.13869/j.cnki.rswc.2024.04.010]
　Long Yuannan,Zhang Yulin,Jiang Changbo,et al.Study on Runoff Response of Zishui Basin Under Climate Change Based on CMIP6[J].Research of Soil and Water Conservation,2024,31(04):114-125.[doi:10.13869/j.cnki.rswc.2024.04.010]

点击复制

基于CMIP6的气候变化下资水流域径流响应研究

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 31 期数: 2024年04期页码: 114-125 栏目: 出版日期: 2024-06-30

Title:: Study on Runoff Response of Zishui Basin Under Climate Change Based on CMIP6

文章编号:: 1005-3409(2024)04-0114-12

作者:: 隆院男^1,2, 张雨林³, 蒋昌波^1,2, 莫军成³, 黄春福^1,2, 宋昕熠^1,2; (1.长沙理工大学水利与环境工程学院, 长沙 410114; 2.洞庭湖水环境治理与生态修复湖南省重点实验室, 长沙 410114; 3.湖南省水利水电勘测设计规划研究总院有限公司, 长沙 410007)

Author(s):: Long Yuannan^1,2, Zhang Yulin³, Jiang Changbo^1,2, Mo Juncheng³, Huang Chunfu^1,2, Song Xinyi^1,2; (1.School of Hydraulic and Environmental Engineering, Changsha University of Science & Technology, Changsha 410114, China; 2.Key Laboratory of Dongting Lake Aquatic Eco-Environmental Control and Restoration of Hunan Province, Changsha 410114, China; 3.Hunan Water Resources & Hydropower Survey, Design, Planning and Research Co., Ltd., Changsha 410007, China)

关键词:: CMIP6; 气候变化; 径流响应; 资水流域; SDSM模型; SWAT模型

Keywords:: CMIP6; climate change; runoff response; Zishui Basin; SDSM model; SWAT model

分类号:: P333.1; P467

DOI:: 10.13869/j.cnki.rswc.2024.04.010

文献标志码:: A

摘要:: [目的]探究未来气候变化情景下资水流域的径流响应情况,为实现流域可持续发展、制定防洪抗旱决策提供科学支持。[方法]基于3个CMIP6全球气候模式,通过构建流域SDSM降尺度模型和SWAT水文模型,预估了SSP1-2.6,SSP2-4.5和SSP5-8.5气候情景下资水流域2030—2089年的气温与降水变化,并进一步探究流域径流对气候变化的响应。[结果]未来资水流域呈较显著暖湿化趋势,空间上流域全范围升温且以新宁、邵阳站附近增幅最大; 降水增加区域主要集中在以冷水江为中心的中下游地区,减少区域位于洞口站以西。在此背景下,未来桃江站与邵阳站年均径流与流域降水的变化趋势基本一致,邵阳站以上的上游区域可利用水资源量减小的可能性较大。枯水期流域水资源将面临更加紧缺的风险,且汛期有提前的趋势,主汛期水资源分配的均匀程度将上升。[结论]在气候暖湿化的背景下,资水流域水资源管理将遭遇更严峻的挑战,应加强水资源保护和流域综合管理。

Abstract:: [Objective]The aims of this study are to explore the runoff response of Zishui Basin under future climate change scenarios, and to provide scientific support for the sustainable development of the basin and the decision-making of flood control and drought control. [Methods]Based on three CMIP6 global climate models, the SDSM downscaling model and SWAT hydrological model were constructed to predict the changes of temperature and precipitation in the Zishui Basin during 2030—2089 under SSP1-2.6, SSP2-4.5 and SSP5-8.5 climate scenarios, and to further explore the response of runoff to climate change. [Results]Zishui Basin will present a significant warming and humidification trend in the future, and this trend will increase with the increase of discharge scenario. Spatially, the temperature rise of the whole basin is the largest in the vicinity of Xinning and Shaoyang stations. The increasing areas of precipitation mainly concentrate in the middle and lower reaches with Lengshuijiang as the center, while the decreasing area is located west of Dongkou station. In this context, the future annual runoff of Taojiang station and Shaoyang station will have the same variation trend with the watershed precipitation, and the amount of available water resources in the upstream area above Shaoyang station is more likely to decrease. Water resources in the basin will face the risk of more shortage in the dry season, and the flood season tends to advance, and the evenness of water resources allocation in the main flood season will increase. [Conclusion]Under the background of climate warming and humidification, the management of water resources in Zishui Basin will encounter more severe challenges, and the protection of water resources and the integrated management of Zishui Basin should be strengthened.

参考文献/References:

[1]IPCC. Climate Change 2021:The physical science basis[M]. Cambridge:Cambridge University Press, 2021.
[2]商放泽,王可昳,黄跃飞,等.基于Budyko假设的三江源径流变化特性及量化分离[J].同济大学学报:自然科学版,2020,48(2):305-316.
Shang F Z, Wang K Y, Huang Y F, et al. Variation characteristics of runoff and the quantitative separation based on Budyko hypothesis in the Three-River Headwaters region[J]. Journal of Tongji University:Natural Science, 2020,48(2):305-316.
[3]Zhao Q D, Ding Y J, Wang J, et al. Projecting climate change impacts on hydrological processes on the Tibetan Plateau with model calibration against the glacier inventory data and observed streamflow[J]. Journal of Hydrology, 2019,573:60-81.
[4]王慧,肖登攀,赵彦茜,等.基于CMIP6气候模式的华北平原极端气温指数评估和预测[J].地理与地理信息科学,2021,37(5):86-94,142.
Wang H, Xiao D P, Zhao Y X, et al. Evaluation and projection of extreme temperature indices in the North China Plain based on CMIP6 models[J]. Geography and Geo-Information Science, 2021,37(5):86-94,142.
[5]张丹,梁瀚续,何小聪,等.基于CMIP6的金沙江流域径流及水文干旱预估[J].水资源保护,2023,39(6):53-62.
Zhang D, Liang H X, He X C, et al. Projections of runoff and hydrological drought in the Jinsha River Basin based on CMIP6[J]. Water Resources Protection, 2023,39(6):53-62.
[6]姜彤,吕嫣冉,黄金龙,等.CMIP6模式新情景(SSP-RCP)概述及其在淮河流域的应用[J].气象科技进展,2020,10(5):102-109.
Jiang T, Lü Y R, Huang J L, et al. New scenarios of CMIP6 model(SSP-RCP)and its application in the Huaihe River Basin[J]. Advances in Meteorological Science and Technology, 2020,10(5):102-109.
[7]周天军,邹立维,陈晓龙.第六次国际耦合模式比较计划(CMIP6)评述[J].气候变化研究进展,2019,15(5):445-456.
Zhou T J, Zou L W, Chen X L. Commentary on the coupled model intercomparison project phase 6(CMIP6)[J]. Climate Change Research, 2019,15(5):445-456.
[8]Adachi S A, Tomita H. Methodology of the constraint condition in dynamical downscaling for regional climate evaluation:A review[J]. Journal of Geophysical Research:Atmospheres, 2020,125(11):e2019JD032166.
[9]徐宗学,姜瑶.变化环境下的径流演变与影响研究:回顾与展望[J].水利水运工程学报,2022(1):9-18.
Xu Z X, Jiang Y. Studies on runoff evolution mechanism under changing environment:A state-of-the-art review[J]. Hydro-Science and Engineering, 2022(1):9-18.
[10]董立俊.雅砻江流域径流对未来气候变化的时空响应研究[D].湖北宜昌:三峡大学,2020.
Dong L J. Spatiotemporal Response of Runoff to Climate Change in Yalongjiang River Basin[D].Yichang, Hubei:China Three Gorges University, 2020.
[11]李彤,胡国华,顾庆福,等.近55年来降水及人类活动对资水流域径流的影响[J].水文,2018,38(6):54-58,88.
Li T, Hu G H, Gu Q F, et al. Impact of precipitation and human activities on runoff in Zishui River in recent 55 years[J]. Journal of China Hydrology, 2018,38(6):54-58,88.
[12]李兵,文强,章新平,等.湖南省资水流域汛期暴雨气候特征分析[J].灌溉排水学报,2020,39(12):136-144.
Li B, Wen Q, Zhang X P, et al. Characteristic analysis of the heavy rains during monsoon season in Zishui Basin of Hunan Province[J]. Journal of Irrigation and Drainage, 2020,39(12):136-144.
[13]虞美秀,刘小龙,邱巍,等.资水流域短期/长期综合干旱指数的构建与应用[J].水资源与水工程学报,2015,26(3):65-71.
Yu M X, Liu X L, Qiu W, et al. Development and application of composited drought index in short and long term at Zishui River Basin[J]. Journal of Water Resources and Water Engineering, 2015,26(3):65-71.
[14]张爱玲,王韶伟,汪萍,等.基于SWAT模型的资水流域径流模拟[J].水文,2017,37(5):38-42,26.
Zhang A L, Wang S W, Wang P, et al. Runoff simulation of Zishui Basin based on SWAT model[J]. Journal of China Hydrology, 2017,37(5):38-42,26.
[15]李兵,章新平,杨令,等.湖南省资水流域极端降水量时空变异特征及重现期极端降水量的推算[J].灌溉排水学报,2019,38(11):117-128.
Li B, Zhang X P, Yang L, et al. Spatial and temporal evolutionary characteristics of extreme precipitation and it's estimation for certain return period in Hunan Zishui River Basin[J]. Journal of Irrigation and Drainage, 2019,38(11):117-128.
[16]侯婷娟,高耶.湖南资水水沙变化特征及成因分析[J].水利水电快报,2018,39(12):11-13,48.
Hou T J, Gao Y. Analysis of the characteristics and causes of water and sand changes in Hunan Zishui River Basin[J]. Express Water Resources & Hydropower Information, 2018,39(12):11-13,48.
[17]何朝飞,骆成彦,陈伏龙,等.基于CMIP6多模式的和田河流域未来气候变化预估[J].地学前缘,2023,30(3):515-528.
He C F, Luo C Y, Chen F L, et al. CMIP6 multi-model prediction of future climate change in the Hotan River Basin[J]. Earth Science Frontiers, 2023,30(3):515-528.
[18]邓鹏,徐进超,王欢.基于CMIP6的气候变化对鄱阳湖流域径流影响研究[J].水利水运工程学报,2023(4):71-80.
Deng P, Xu J C, Wang H. Study on the impact of climate change by CMIP6 on the rainfall-runoff process of Poyang Lake Basin[J]. Hydro-Science and Engineering, 2023(4):71-80.
[19]周芷菱,张利平,王惠筠,等.基于CMIP6的莱茵河流域极端水文事件变化特征研究[J].武汉大学学报:工学版,2022,55(4):328-338.
Zhou Z L, Zhang L P, Wang H Y, et al. Change characteristics of extreme hydrological events in the Rhine River Basin based on CMIP6[J]. Engineering Journal of Wuhan University, 2022,55(4):328-338.
[20]Wilby R L, Dawson C W, Barrow E M. SDSM:A decision support tool for the assessment of regional climate change impacts[J]. Environmental Modelling & Software, 2002,17(2):145-157.
[21]陈威霖,江志红,黄强.基于统计降尺度模型的江淮流域极端气候的模拟与预估[J].大气科学学报,2012,35(5):578-590.
Chen W L, Jiang Z H, Huang Q. Projection and simulation of climate extremes over the Yangtze and Huaihe River Basins based on a Statistical Downscaling Model[J]. Transactions of Atmospheric Sciences, 2012,35(5):578-590.
[22]叶加俊.汉江上游流域径流模拟及未来气候变化响应[D].武汉:华中科技大学,2018.
Ye J J. Runoff Simulation of the Upper Reaches of the Hanjiang River and Future Climate Change Response[D].Wuhan:Huazhong University of Science and Technology, 2018.
[23]侯保俭.长江上游流域统计降尺度方法研究[D].重庆:重庆交通大学,2012.
Hou B J. Statistical Downscaling Methods in Upper Reaches of Yangtze River Basin of China[D].Chongqing:Chongqing Jiaotong University, 2012.
[24]Arnold J G, Muttiah R S, Srinivasan R, et al. Regional estimation of base flow and groundwater recharge in the Upper Mississippi River Basin[J]. Journal of Hydrology, 2000,227(1/4):21-40.
[25]Mann H B. Nonparametric tests against trend[J]. Econometrica, 1945,13(3):245.
[26]马小芳,林爱文,方建.1960—2012年长江中下游极端降水与极端径流时空演变研究[J].测绘与空间地理信息,2018,41(2):157-160,163.
Ma X F, Lin A W, Fang J. Research on spatio-temporal variation of extreme precipitation and extreme run off in the middle and lower reaches of Yangtze River from 1960—2010[J]. Geomatics & Spatial Information Technology, 2018,41(2):157-160,163.
[27]代慧慧,杨汉波,胡庆芳.基于SDSM的疏勒河流域气候变化统计降尺度研究[J].水利水运工程学报,2015(5):46-53.
Dai H H, Yang H B, Hu Q F. Prediction of climate change over Shule River Basin based on a statistical downscaling method[J]. Hydro-Science and Engineering, 2015(5):46-53.
[28]刘卫林,熊翰林,刘丽娜,等.基于CMIP5模式和SDSM的赣江流域未来气候变化情景预估[J].水土保持研究,2019,26(2):145-152.
Liu W L, Xiong H L, Liu L N, et al. Estimate of the climate change in Ganjiang River Basin using SDSM method and CMIP5[J]. Research of Soil and Water Conservation, 2019,26(2):145-152.
[29]Huang J, Zhang J C, Zhang Z X, et al. Simulation of extreme precipitation indices in the Yangtze River Basin by using statistical downscaling method(SDSM)[J]. Theoretical and Applied Climatology, 2012,108(3):325-343.
[30]中国气象局气候变化中心.中国气候变化蓝皮书2021[M].北京:科学出版社,2021.
Climate Change Center of the China Meteorological Administration. Blue Book on Climate Change in China 2021[M]. Beijing:Science Press, 2021.

相似文献/References:

[1]谢胜金,刘永和,姚风欣.1998-2015年北京市NDVI时空变化及其与气候因子的响应关系[J].水土保持研究,2020,27(03):190.
　XIE Shengjin,LIU Yonghe,YAO Fengxin.Spatial-Temporal Characteristics of NDVI and Its Relationship with Climate Change in Beijing from 1998 to 2015[J].Research of Soil and Water Conservation,2020,27(04):190.
[2]田义超,王世杰,白晓永,等.桐梓河流域径流对气候和人类活动的响应[J].水土保持研究,2020,27(03):76.
　TIAN Yichao,WANG Shijie,BAI Xiaoyong,et al.Response of Runoff to Climate and Human Activities in Tongzi River Basin[J].Research of Soil and Water Conservation,2020,27(04):76.
[3]张凯,鲁克新,李鹏,等.近60年汾河中上游水沙变化趋势及其驱动因素[J].水土保持研究,2020,27(04):54.
　ZHANG Kai,LU Kexin,LI Peng,et al.Trend of Runoff and Sediment Change and Its Driving Factors in the Middle and Upper Reaches of Fenhe River in the Past 60 Years[J].Research of Soil and Water Conservation,2020,27(04):54.
[4]孔蕊,张增信,张凤英,等.长江流域森林碳储量的时空变化及其驱动因素分析[J].水土保持研究,2020,27(04):60.
　KONG Rui,ZHANG Zengxin,ZHANG Fengying,et al.Spatial and Temporal Dynamics of Forest Carbon Storage and Its Driving Factors in the Yangtze River Basin[J].Research of Soil and Water Conservation,2020,27(04):60.
[5]李丹,吴秀芹,张靖宙,等.西南喀斯特断陷盆地植被物候动态变化及其与气候因子的响应[J].水土保持研究,2020,27(06):168.
　LI Dan,WU Xiuqin,ZHANG Jingzhou,et al.Vegetation Phenology Change and Response to Climate Change in the Karst Faulted Basin of Southwest China[J].Research of Soil and Water Conservation,2020,27(04):168.
[6]同琳静,刘洋洋,章钊颖,等.定量评估气候变化与人类活动对西北地区草地变化的相对作用[J].水土保持研究,2020,27(06):202.
　TONG Linjing,LIU Yangyang,ZHANG Zhaoying,et al.Quantitative Assessment on the Relative Effects of Climate Variation and Human Activities on Grassland Dynamics in Northwest China[J].Research of Soil and Water Conservation,2020,27(04):202.
[7]李婷婷,马超,郭增长.2004-2015年贺兰山自然保护区植被NPP时空变化与气候响应[J].水土保持研究,2020,27(06):254.
　LI Tingting,MA Chao,GUO Zengzhang.Response of Spatiotemporal Change of NPP to Climate in Helanshan Mountain Nature Reserve from 2004 to 2015[J].Research of Soil and Water Conservation,2020,27(04):254.
[8]李思楠,赵筱青,谭琨,等.孟加拉国博多河流域NDVI时空变化及其与气候因子的相关性[J].水土保持研究,2021,28(01):139.
　LI Sinan,ZHAO Xiaoqing,TAN Kun,et al.Spatiotemporal Variation of NDVI and Its Relationship with Climate in Padma River Basin of Bangladesh.[J].Research of Soil and Water Conservation,2021,28(04):139.
[9]薛晓玉,王晓云,段含明,等.北方农牧交错带植被NPP的时空变化及其驱动因子分析[J].水土保持研究,2021,28(02):190.
　XUE Xiaoyu,WANG Xiaoyun,DUAN Hanming,et al.Temporal and Spatial Changes of NPP and Its Causes in the Agricultural Pastoral Ecotone of Northern China[J].Research of Soil and Water Conservation,2021,28(04):190.
[10]王丽霞,丁慧兰,刘招,等.基于CASA模型探究泾河流域植被NPP时空动态及其对气候变化的响应[J].水土保持研究,2022,29(01):190.
　WANG Lixia,DING Huilan,LIU Zhao,et al.Spatiotemporal Change of NPP Based on CASA Model and Its Response to Climate Change in Jing River Basin[J].Research of Soil and Water Conservation,2022,29(04):190.

备注/Memo

收稿日期:2023-08-15 修回日期:2023-10-10
资助项目:国家自然科学基金面上项目(52079010); 湖南省重点研发计划(2020SK2130); 湖南省研究生科研创新资助项目(CX20220910); 湖南省水利科技项目(XSKJ2019081-09)
第一作者:隆院男(1985—),男,湖南宁乡人,博士,副教授,主要从事水文遥感和流域水文模型研究。E-mail:lynzhb@csust.edu.cn
通信作者:蒋昌波(1970—),男,陕西石泉人,博士,教授,主要从事水动力过程及其数值模拟研究。E-mail:jcb36@163.com

更新日期/Last Update: 2024-06-30