赵建世

职称:长聘教授 博士生导师
通信地址:北京市海淀区清华大学水利水电工程系
邮编:100084 
电话号码:010-62796539
E-mail:zhaojianshi@tsinghua.edu.cn

教育背景

1998.9-2003.7 清华大学水利系 水文水资源 博士学位

1993.9-1998.7 清华大学水利系 水利水电工程建筑 学士学位

工作履历

2020.7- 新澳门新葡萄娱乐 副院长
2020.6- 清华大学水利水电工程系 长聘教授
2017.8-2020.8 清华大学水利水电工程系水文水资源研究所 所长
2017.1-2020.6 清华大学水利水电工程系 特别研究员 长聘副教授
2010.10- 清华大学跨境河流水与生态安全研究中心 副主任
2009.1-2010.2 美国伊利诺伊大学香槟校区(UIUC) 访问学者/博士后研究助理
2007.12-2016.12 清华大学水利水电工程系 副教授
2003.8-2007.12 清华大学水利水电工程系 讲师



开设课程

1)现代水资源规划 64学时 春季 研究生学位课
2)全球变化与中国水资源 32学时 秋季 本科生大类平台课
3)水文学与水资源管理 32学时 秋季 本科生大类平台课


研究领域

(一) 流域人-水耦合系统演化机理与规律

(二) 水资源风险对冲调度理论方法
(三) 变化环境下的流域综合治理



科研项目

[1]十四五国家重点研发计划课题,灌区水权水价补偿促进机制与复合系统适水协同调控(2022-2025)
[2]国家自然科学基金委黄河水科学研究联合基金,黄河上游梯级开发的生态环境累积效应与适应性协同调控(2022-2025)
[3]国家自然科学基金委重大研究计划集成项目课题,西南河流径流适应性利用与调控(2021-2023)
[4]清华大学--宁夏银川水联网数字治水联合研究院专项统筹重点项目,隆德山水林田湖系统研究及示范设计(2020-2021)
[5]国家自然科学基金委国际合作项目,INFEWS:U.S.-China:食品、能源、水互馈复杂超级系统的耦合代理模型研究(2019-2022)
[6]水沙科学与水利水电工程国家重点实验室项目,南水北调中线水源区水质水量安全保障关键技术(2019-2021)
[7]水利部发展研究中心外委课题,“十四五”水安全保障规划——跨省江河水量分配问题研究(2019-2020)
[8]水利部项目,南水北调工程技术资源管理系统建设(2019)
[9]国家自然科学基金委重点项目,澜沧江流域多利益主体合作博弈机制与径流适应性利用研究(2018-2021)
[10]国家重点研发计划课题,黄河分水方案适应性综合评价(2017-2020)
[11]国家重点研发计划专题,适应多维度用水需求的水库群供水调度技术(2016-2019)
[12]国家自然科学基金面上项目,基于预报及其不确定性的水库风险对冲调度研究(2016-2019)
[13]中国工程院院士咨询项目专题,水资源配置安全保障战略研究-“空间均衡” 下水资源配置战略需求分析(2016-2017)
[14]国家自然科学基金面上项目,耦合水文预报与经济准则的水资源适应性管理研究(2012-2015)
[15]十二五科技支撑专题,水联网多水源利用机制及实时调度关键技术研究(2013-2015)
[16]十二五科技支撑专题,梯级水电开发影响的生态安全调控和生态修复技术与示范(2011-2015)
[17]水利部公益性行业项目,石羊河流域治理水权框架与实施的过程控制关键技术(2011-2013)
[18]水利部公益性行业项目,淮河流域水质管理预警模型研究( 2010-2013)
[19]水利部公益性行业项目, 基于三生用水安全的海河流域水资源调控技术(2011-2013 )
[20]科技部973项目专题,人类活动干扰下的典型单元水循环机理研究(2006-2011)
[21]国家自然科学基金国际(地区)合作交流项目( 合作研究项目NSFC-NSF中美数字政府合作), 水资源决策支持情境、技术与工具比较研究(2007-2008)
[22]国家自然科学基金委员会, 复杂水资源系统的演化动力机制及整体模型研究(2005-2007)
[23]世行GEF海河项目专题,海河GEF流域级知识管理(KM)业务应用系统开发(2007-2008)
[24]世行GEF海河项目子专题,南水北调中线工程实施后北京市不同水源的调配方案研究(2007-2008)
[25]北京市水利规划设计研究院, 密云水库合理安全储备研究(2006)
[26]黄委会水调局项目,黄河水量统一调度实施效果的宏观经济评估(2004)


学术兼职

[1] 2021年4月:担任 Frontiers in Water 领域主编(Specialty Chief Editor)
[2] 2019年5月: 当选ASCE-EWRI Environmental and Water Resources System Committee委员
[3] 2018年10月:当选中国大坝工程学会环境生态工程专委会副主任
[4] 2018年9月:当选中国水利学会水资源专业委员会副主任
[5] 2017年9月:当选ASCE指导委员会联席委员
[6] 2017年8月:当选ASCE-Journal of Water Resources Planning and Management副主编
[7] 2016年2月:当选亚洲国际河流论坛 (Forum of Asian International Rivers, FAIR)秘书长


奖励与荣誉

[1]2022年,面向水资源高效利用的水联网基础理论与关键技术,教育部科学技术进步奖一等奖,排名第2.
[2]2020年,中原城市群高质量发展水资源支撑与提升关键技术,河南省科技进步二等奖,排名第5.
[3]2020年,区域生态-能源-粮食协同发展的水权分级配置与交易关键技术,中国大坝工程学会科技进步一等奖,排名第5.
[4]2019年,旱区水权理论、动态定量关键技术与实践,教育部科技进步二等奖,排名第1
[5]2019年,基于水资源-粮食-能源纽带关系的跨境河流合作机制-以澜沧江-湄公河为例,清华大学挑战杯优秀指导教师
[6]2018年,水资源量质效协同管控关键技术,大禹水利科学技术一等奖,排名第4
[7]2017年,“国际合作、混合研教,探索培养流域管理领军人才国际化模式”全国高度学习水利类专业教学成果奖二等奖,排名第3
[8]2016年,第十四届中国青年科技奖,全国共100人
[9]2016年,“国际合作、混合研教,探索培养流域管理领军人才国际化模式”清华大学教学成果一等奖,排名第5
[10]2014年 “全国水文与水资源工程专业青年教师讲课竞赛奖”一等奖, 排名第1
[11]2014年 “本研贯通国际化水资源课程体系建设”清华大学教学成果一等奖,排名第1
[12]2013年    清华大学“青年教师教学优秀奖”,全校共10人
[13]2013年, “淮河水系生态用水调度研究” 水利部大禹水利科学技术奖二等奖,排名第3
[14]2011年, “水利与国民经济耦合系统的模拟调控技术及应用” 国家科技进步奖二等奖,排名第7
[15]2009年, “水利与国民经济协调发展研究” 水利部大禹水利科学技术奖一等奖,排名第7
[16]2009年, “水资源承载能力评价方法及其应用研究” 水利部大禹水利科学技术奖二等奖,排名第5
[17]2009年, “甘肃河西内陆区水资源战略安全及优化节水技术研究与开发” 甘肃省科技进步奖二等奖,排名第9
[18]2007年, “甘肃省石羊河流域综合治理方案研究” 甘肃省科技进步奖二等奖,排名第8
[19]2006年, “流域水量调控模型及在黄河水量调度中的应用” 国家科技进步奖二等奖,排名第5
[20]2005年, “流域水量调控模型及在黄河水量调度中的应用” 教育部提名国家科学技术奖中的科技进步奖一等奖,排名第5


学术成果

一、英文期刊论文

[1] Large-scale prediction of stream water quality using an interpretable deep learning approach H Zheng, Y Liu, W Wan, Jianshi Zhao, G Xie, Journal of Environmental Management, 2023, 331, 117309

[2] Optimal operation toward energy efficiency of the long-distance water transfer project, Y Liu, H Zheng, W Wan, Jianshi Zhao, Journal of Hydrology, 2023, 618, 129152

[3] Enable high-resolution, real-time ensemble simulation and data assimilation of flood inundation using distributed GPU parallelization, J Wei, X Luo, W Liao, X Lei, Jianshi Zhao, H Huang, H Wang, Journal of Hydrology, 2023, 129277

[4] Partition of one-dimensional river flood routing uncertainty due to boundary conditions and riverbed roughness, Wang, Jiabiao; Jianshi Zhao*; Zhao, Tongtiegang; Wang, Hao, Journal of Hydrology2022,608, WOS:000791946800001

[5] Prediction of NDVI dynamics under different ecological water supplementation scenarios based on a long short-term memory network in the Zhalong Wetland, ChinaWang, Weize; Hu, Peng; Yang, Zefan; Wang, Jianhua; Zhao, Jianshi; Zeng, Qinghui; Liu, Huan; Yang, Qin, Journal of Hydrology, 2022, 608, WOS:000790506100005

[6] Soft-cooperation via data sharing eases transboundary conflicts in the Lancang-Mekong River Basin, Gao, Jinyu; Castelletti, Andrea; Burlado, Paolo; Wang, Hao; Jianshi Zhao*, Journal of Hydrology, 2022,606, WOS:000752810500005

[7] Release process identification of non-instantaneous point source pollution in rivers via reverse flow and pollution routing, Wang, Jiabiao; Zhao, Jianshi; Lei, Xiaohui; Zhao, Tongtiegang; Wang,Hao, Environmental Research,2022, 213, WOS:000833520400003

[8] Optimizing hydropower generation and sediment transport in Yellow River basin via cooperative game theoryY Wang, F Tang, E Jiang, X Wang, Jianshi Zhao*, Journal of Hydrology614, 128581

[9] Reconstructed eight-century streamflow in the Tibetan Plateau reveals contrasting regional variability and strong nonstationarityY Wu, D Long, U Lall, BR Scanlon, F Tian, X Fu, J Zhao, J Zhang, H Wang, Nature Communications13 (1), 1-13

[10] Optimal Operation Rules for Parallel Reservoir Systems with Distributed Water DemandsW Meng, W Wan, Jianshi Zhao*, Z WangJournal of Water Resources Planning and Management148 (6), 04022020

[11] Modeling Effects of Atmospheric Nitrogen Deposition on the Water Quality of the MR-SNWDPJ Wang, S Cai, J ZhaoAtmosphere13 (4), 553

[12] Effects of ENSO on hydrological process and hydropower across the Lancang‐Mekong River BasinJ Gao, Jianshi Zhao*, P Hou, H WangRiver12),https://doi.org/10.1002/rvr2.25

[13] Location identification of river bathymetric error based on the forward and reverse flow routingWang, Jiabiao; Lei, Xiaohui; Cai, Siyu; Zhao, Jianshi, Water Supply, 2022, WOS:000781606300001

[14] 2Inverse scattering transform of the general three-component nonlinear Schrodinger equation and its multisoliton solutions, Yu, Zong-Bing; Zhu, Chenghao; Zhao, Jian-Shi; Zou, Li, Applied Mathematic Letters, 2022, 128, WOS:000768904600007

[15] Shuyue Wu, Jianshi Zhao*, Hao Wang, and M. Sivapalan (2021), Regional patterns and physical controls of streamflow generation across the conterminous United States. Water Resources Research,57, e2020WR028086. https://doi.org/10.1029/2020WR028086.

[16] Wenhua Wan, Jianshi Zhao, E. Popat, C. Herbert, and P. Döll* (2021), Analyzing the impact of streamflow drought on hydroelectricity production: A global scale study. Water Resources Research, 57, e2020WR028087. https://doi.org/10.1029/2020WR028087.

[17] Hang Zheng, Yueyi Liu, Jianshi Zhao*(2021), Understanding water rights and water trading systems in China: A systematic framework, Water Security, 13 (2021) 100094.

[18] Jinyu Gao, Jianshi Zhao*, Hao Wang (2021), Dam-Impacted Water–Energy–Food Nexus in Lancang-Mekong River Basin. ASCE-Journal of Water Resources Planning and Management, 2021, 147(4): 04021010.

[19] Jiabiao Wang, Tongtiegang Zhao, Jianshi Zhao*, Hao Wang, Xiaohui Lei(2021), Improving real-time reservoir operation during flood season by making the most of streamflow forecasts. Journal of Hydrology, doi: https://doi.org/10.1016/j.jhydrol.2021.126017.

[20] Wenhua Wan* , Xiaohui Lei, Jianshi Zhao, Mingna Wang*, Soon-Thiam Khu, and Chao Wang (2021), Forecast-Skill-Based Dynamic Pre-Storm Level Control for Reservoir Flood-Control Operation. Water, 2021, 13, 556. https://doi.org/10.3390/w13040556

[21] Huanyu Chang, Guohua He*, Qingming Wang, Haihong Li, Jiaqi Zhai, Yiyang Dong, Yong Zhao *, and Jianshi Zhao (2021), Use of sustainability index and cellular automata-Markov model to determine and predict long-term spatio-temporal variation of drought in China. Journal of Hydrology, 598 (2021) 126248.

[22] Yan Bo, Feng Zhou*, Jianshi Zhao, Junguo Liu, Jiahong Liu, Philippe Ciais, Jinfeng Chang, Lei Chen (2021), Additional surface-water deficit to meet global universal water accessibility by 2030, Journal of Cleaner Production, 320 (2021) 128829.

[23] Wenhua Wan, Hao Wang, and Jianshi Zhao*(2020), Hydraulic potential energy model for hydropower operation in mixed reservoir systems. Water Resources Research, 56, e2019WR026062. https://doi.org/10.1029/2019WR026062.

[24] Di Long*, Wenting Yang, Bridget R. Scanlon, Jianshi Zhao, Dagen Liu, Peter Burek, Yun Pan, Liangzhi You & Yoshihide Wada (2020). South-to-North Water Diversion stabilizing Beijing’s groundwater levels. Nature Communications, 11, 3665. https://doi.org/10.1038/s41467-020-17428-6.

[25] Feng Zhou*, YAN BO, Philippe Ciais, Patrice Dumas, Qiuhong Tang, Xuhui Wang, Junguo Liu, Chunmiao Zheng, Jan polcher, Zun YIN, Matthieu Guimberteau, Shushi Peng, Catherine Ottle, Xining ZHAO, Jianshi Zhao, QIAN TAN, LEI CHEN, Huizhong Shen, HUI YANG, Shilong Piao, Hao Wang, and Yoshihide Wada (2020). Deceleration of China’s human water use and its key drivers, Proceedings of the National Academy of Sciences of the United States of America, 2020, 117(14): 1-10.

[26] Zhi Xu , Jing Ma*, Hao Wang, and Jianshi Zhao (2020), Influence of River Discharge on the Transport of the Saltwater Group from the North Branch in the Yangtze River Estuary, International Journal of Environmental Research and Public Health 2020, 17, 9156, doi:10.3390/ijerph17249156

[27] Weize Wang, Peng Hu*, Jianhua Wang, Jianshi Zhao, Huan Liu, Zefan Yang (2020), Scenario analysis for the sustainable development of agricultural water in the Wuyuer River basin based on the WEP model with a reservoir and diversion engineering module, Science of The Total Environment, https://doi.org/10.1016/j.scitotenv.2020.143668.

[28] Yiyang Dong, Yong Zhao*, Jiaqi Zhai, Jianshi Zhao, Jingyan Han, Qingming Wang, Guohua He, Huanyu Chang (2020), Changes in reference evapotranspiration over the non-monsoon region of China during 1961-2017: Relationships with atmospheric circulation and attributions, International Journal of Climatology, DOI: 10.1002/joc.6722.

[29] Yu, Yang, Pingzhong Tang, Jianshi Zhao*, Bo Liu, Dennis Mclaughlin (2019). Evolutionary cooperation in transboundary river basins. Water Resources Research, 55, 9977–9994. https://doi.org/10.1029/2019WR025608

[30] Jiabiao Wang, Jianshi Zhao*, Xiaohui Lei, and Hao Wang (2019), An effective method for point pollution source identification in rivers with performance-improved ensemble Kalman filter, Journal of Hydrology, 577,123991, https://doi.org/10.1016/j.jhydrol.2019.123991

[31] Dongnan Li, Jianshi Zhao*, Rao S. Govindaraju (2019), Water benefits sharing under transboundary cooperation in the Lancang-Mekong River Basin, Journal of Hydrology, 577 123989, https://doi.org/10.1016/j.jhydrol.2019.123989.

[32] Wenhua Wan, Jianshi Zhao*, Jianbiao Wang (2019), Revisiting Water Supply Rule Curves with Hedging Theory for Climate Change Adaptation, Sustainability, 2019(11),1827; doi:10.3390/su11071827.

[33] Yang Yu, Jianshi Zhao*, Dongnan Li, Zhongjing Wang (2019), Effects of Hydrologic Conditions and Reservoir Operation on Transboundary Cooperation in the Lancang–Mekong River BasinJournal of Water Resources Planning and Management, 145(6): 04019020.

[34] Xiaowen Lei, Jianshi Zhao*, Yi-Chen Ethan Yang, Zhongjing Wang(2019), Comparing the economic and environmental effects of different water management schemes using a coupled agent-hydrologic model, Journal of Water Resources Planning and Management, 145(6): 05019010.

[35] Zhilei Zheng; Zhongjing Wang*; Jianshi Zhao, Hang Zheng (2019), Constrained Model Predictive Control Algorithm for Cascaded Irrigation Canals, Journal of Irrigation and Drainage Engineering, 145(6): 04019009.

[36] Tingting Xu, Zheng, Hang, Zhao, Jianshi*, Liu, Yicheng, Tang, Pingzhong, Yang, Yichen  Ethan, and Wang, Zhongjing (2018). A two-phase model for trade matching and price setting in double auction water markets. Water Resources Research, 54. https://doi.org/10.1002/2017WR021231

[37] Xiaowen Lei, Zhao, Jianshi*,Dingbao Wang, Murugesu Sivapalan (2018), A Budyko-type model for human water consumption, Journal of Hydrology, 567 (2018), 212–226. https://doi.org/10.1016/j.jhydrol.2018.10.021

[38] Dongnan Li, Wenhua Wan, Jianshi Zhao*(2018). Optimizing environmental flow operations based on explicit quantification of IHA parameters. Journal of Hydrology, 563,510-522. https://doi.org/10.1016/j.jhydrol.2018.06.031

[39] Jiabiao Wang, Jianshi Zhao*, Xiaohui Lei, Hao Wang(2018). New approach for point pollution source identification in rivers based on the backward probability method. Environmental Pollution, 241,759-774. https://doi.org/10.1016/j.envpol.2018.05.093

[40] Wenhua Wan, Jianshi Zhao, Hong-Yi Li*, Ashok Mishra, Mohamad Hejazi, Hui Lu,Yonas Demissie, and Hao Wang(2018). A Holistic View of Water Management Impacts on Future Droughts: A Global Multimodel Analysis. Journal of Geophysical Research: Atmospheres, 123. https://doi.org/10.1029/2017JD027825

[41] Yueyi Liu, Jianshi Zhao, and Hang Zheng* (2018). Piecewise-Linear Hedging Rules for Reservoir Operation with Economic and Ecologic Objectives. Water, 10, 865, doi:10.3390/w10070865

[42] Wenhua Wan, Jianshi Zhao, Hongyi Li*, A. Mishra, L. Ruby Leung, M. Hejazi, Hao  Wang.(2017). Hydrological drought in the Anthropocene: Impacts of local water extraction and reservoir regulation in the U.S. Journal of Geophysical Research: Atmospheres, 122, 11,313–11,328. https://doi.org/10.1002/2017JD026899.

[43] Wei Wang, Hongyi Li*, L. R. Leung, W. Yigzaw, Jianshi Zhao, Hui Lu, G. Bl€oschl (2017). Nonlinear filtering effects of reservoirs on flood frequency curves at the regional scale. Water Resources Research, 53. https://doi.org/10.1002/2017WR020871

[44] Wei Wang, Hui Lu*, L. R. Leung, Hongyi Li, Jianshi Zhao, Fuqiang Tian, Kun Yang, & K.Sothea(2017). Dam construction in Lancang-Mekong River Basin could mitigate future flood risk from warming-induced intensified rainfall. Geophysical Research Letters, 44. https://doi.org/10.1002/2017GL075037

[45] Dongnan Li, Di Long, Jianshi Zhao*, Hui Lu, and Yang Hong (2017), Observed changes in flow regimes in the Mekong River basin, Journal of Hydrology, 551, 217–232,doi: http://dx.doi.org/10.1016/j.jhyd rol.2017.05.061

[46] Tongtiegang Zhao, Jianshi Zhao*, Xiaohui Lei, Xu Wang, and Bisheng Wu (2017), Improved Dynamic Programming for Reservoir Flood Control Operation, Water Resources Management, 31(7):2047-2063.

[47] Jianshi Zhao*, Dingbao Wang, Hanbo Yang, and M. Sivapalan (2016), Unifying catchment water balance models for different time scales through the maximum entropy production principle, Water Resources Research, 52, doi:10.1002/2016WR018977

[48] Cao Huang, Jianshi Zhao, Zhongjing Wang*, and Wenxiu Shang (2016), Optimal Hedging Rule for Two-objective Reservoir Operation: Balancing Water Supply and Environmental Flow, ASCE-Journal of Water Resources Planning and Management. 142(12): 04016053

[49] Wenhua Wan, Jianshi Zhao*, Jay R. Lund, Tongtiegang Zhao, Xiaohui Lei, and Hao Wang (2016), Optimal Hedging Rule for Reservoir Refill, ASCE-Journal of Water Resources Planning and Management. 142 (11) :04016051.

[50] Rui Hui, Jay Lund*, Jianshi Zhao, and Tongtiegang Zhao (2016), Optimal Pre-storm Flood Hedging Releases for a Single Reservoir, Water Resources Management, DOI 10.1007/s11269-016-1472-x

[51] Tongtiegang Zhao*, Jianshi Zhao, and Guangheng Ni (2016), Source of atmospheric moisture and precipitation over China’s major river basins, Frontier of Earth Science, 10(1): 159–170.

[52] Tongtiegang Zhao, Q.J. Wang*, James C. Bennett, David E. Robertson, Quanxi Shao, Jianshi Zhao (2015), Quantifying predictive uncertainty of streamflow forecasts based on a Bayesian joint probability model, Journal of Hydrology, 528, 329–340.

[53] Tongtiegang Zhao, Jianshi Zhao*, Pan Liu, and Xiaohui Lei(2015), Evaluating the marginal utility principle for long-term hydropower scheduling, Energy Conversion and Management, 106 , 213–223.

[54] Dingbao Wang*, Jianshi Zhao, Y. Tang, and M. Sivapalan (2015), A thermodynamic interpretation of Budyko and L’vovich formulations of annual water balance: Proportionality Hypothesis and maximum entropy production, Water Resources Research,51, doi:10.1002/2014WR016857.

[55] Wenzhao Xu, Jianshi Zhao*,Tongtiegang Zhao, and Zhongjing Wang (2015), An adaptive reservoir operation model incorporating nonstationary inflow prediction, ASCE-Journal of Water Resources Planning and Management, 141(8): 04014099.

[56] Yueyi Liu, Jianshi Zhao*, and Zhongjing Wang (2015), Identifying Determinants of Urban Water Use Using Data Mining Approach, Urban Water Journal, 12(8), 618-630.

[57] Tongtiegang Zhao, Jianshi Zhao*, Jay R. Lund, and Dawen Yang (2014), Optimal Hedging Rules for Reservoir Flood Operation from Forecast UncertaintiesJournal of Water Resources Planning and Management, 140(12), 04014041.

[58] Tongtiegang Zhao, and Jianshi Zhao*, (2014), Joint and respective effects of long- and short-term forecast uncertainties on reservoir operations, Journal of Hydrology, 517, 83–94.  

[59] Tongtiegang Zhao, and Jianshi Zhao* (2014), Forecast-skill-based Simulation of Streamflow Forecasts, Advances in Water Resources, 71, 55–64 , doi: 10.1016/j.advwatres.2014.05.011, 2014.

[60] Tongtiegang Zhao, Jianshi Zhao* (2014), Improved multiple-objective dynamic programming model for reservoir operation optimization, Journal of Hydroinformatics, 16(5),1142-1157.

[61] Tongtiegang Zhao, and Jianshi Zhao* (2014), Optimizing Operation of Water Supply Reservoir: the Role of Constraints, Mathematical Problems in Engineering, 2014,1-15.

[62] Tongtiegang Zhao, Jianshi Zhao*, and Dawen Yang (2014)Improved Dynamic Programming for Hydropower Reservoir OperationASCE-Journal of Water Resources Planning and Management, 140(3), 365-374.

[63] Jianshi Zhao*, Ximing Cai, and Zhongjing Wang (2013), Comparing administered and market-based water allocation systems through a consistent agent-based modeling framework, Journal of Environmental Management,123,120-130.

[64] Tongtiegang Zhao, Jianshi Zhao*, Dawen Yang, and Hao Wang(2013), Generalized martingale model of the uncertainty evolution of streamflow forecasts, Advances in Water Resources, 57,41-51.

[65] Ethan Yang, Jianshi Zhao, and Ximing Cai* (2012), Decentralized Optimization Method for Water Allocation Management in the Yellow River Basin, ASCE-Journal of Water Resources Planning and Management, 2012.138:313-325.

[66] Tongtiegang Zhao, Dawen Yang*, Ximing Cai, Jianshi Zhao, and Hao Wang(2012), Identifying effective forecast horizon for real-time reservoir operation under a limited inflow forecast, Water Resources Research, 48, W01540.

[67] Jianshi Zhao*, Ximing Cai, and Zhongjing Wang (2011), Optimality conditions for a two-stage reservoir operation problem, Water Resources Research, 47, W08503.

[68] Ximing Cai*, Yi-Chen E. Yang, Claudia Ringler, Jianshi Zhao, and Liangzhi You (2011),  Agricultural water productivity assessment for the Yellow River Basin, Agricultural Water Management 98 (2011) 1297–1306.

[69] Claudia Ringler*, Ximing Cai, Jinxia Wang, Akhter Ahmeda, Yunpeng Xue, Zongxue Xue, Ethan Yang, Jianshi Zhao, Tingju Zhu, Lei ChengYongfengd, Fu Xinfeng, Gu Xiaowei, and Liangzhi You2010, Yellow River basin: living with scarcity, Water International, 35(5), 681-701.

[70] Jianshi Zhao*, Zhongjing Wang, Daoxi Wang, and Dangxian Wang2009),Evaluation of Economic and Hydrologic Impacts of Unified Water Flow Regulation in the Yellow River Basin, Water Resources Management, 23(7) ,1387-1401.

[71] Li-Tang Hu, ZhongJing Wang*, Wei Tian, and Jianshi Zhao2009, Coupled surface water-groundwater model and its application in the arid Shiyang River basin, China, Hydrologic Processes. 23, 2033–2044.

[72] Jianshi Zhao*, Wang Zhongjing, and Weng Wenbin (2004), Study on the holistic model for water resources system, Science in China Ser. E Engineering & Materials Science, Vol.47 Supp.I 72—89.

二、中文期刊论文
[1] 杨文静;赵建世;赵勇;王庆明,基于结构方程模型的蒸散发归因分析,清华大学学报(自然科学版),2022,62(3),200-207
[2] 王淏;高进宇;于洋; 赵建世*,南方电网水-火电合作博弈及关键影响要素分析,水力发电学报, 2022,1,94-104
[3] 王家彪, 赵建世*, 雷晓辉, 王浩, 廖卫红(2020). 基于旋转x-t平面的河渠水流反向演算[J]. 清华大学学报(自然科学版), 2020, 60(10), 855-863.
[4] 刘寒青,刘静,赵建世,等.基于水资源系统可持续性的南水北调进京规模分析[J].水资源保护,2020,36(6):99-105.
[5] 苏心玥,于洋,赵建世,李铁键(2019),南水北调中线通水后北京市辖区间水资源配置的博弈均衡,应用基础与工程科学学报,2019,27(02),239-251.
[6] 王家彪,赵建世,雷晓辉,王浩,魏隽煜,廖卫红(2019),基于EnKF 的无实测资料区间支流反分析,水利学报,50(10),1189-1199.
[7] 王昱丁,郑航,赵建世* (2019),人类活动干扰下西北干旱区绿洲迁移演化研究,水力发电学报,38(3),40-51.
[8] 徐志,马静,王浩,赵建世,胡雅杰,杨贵羽(2019),长江口影响水资源承载力关键指标与临界条件, 清华大学学报(自然科学版), 2019, 59 (5),364-372.
[9] 王家彪,沈子寅,赵建世*,王浩,雷晓辉(2019),关于低影响开发设施设计雨量确定方法的讨论,中国给水排水,35(1),1-7.
[10] 王家彪;赵建世;沈子寅;王浩;雷晓辉(2017),关于海绵城市两种降雨控制模式的讨论,水利学报,48(12),1490-1498.
[11] 于洋,韩宇,李栋楠,赵建世*(2017),澜沧江-湄公河流域跨境水量-水能-生态互馈关系模拟,水利学报,48(6),720-729.
[12] 吴书悦,赵建世*,雷晓辉,王忠静,王浩(2017),气候变化对新安江水库调度影响与适应性对策 ,水力发电学报,36 (1): 50-58.
[13] 林旭,赵建世,雷晓辉,王浩(2017),工农业经济增加值—污染物排放量函数,清华大学学报(自然科学版),57(4),357-361.
[14] 刘悦忆,朱金峰,赵建世*(2016),河流生态流量研究发展历程与前沿,水力发电学报, 35(12) , 23-34.
[15] 赵建世*,王君,赵铜铁钢 (2016), 非稳态条件下的中长期径流耦合预报方法, 南水北调与水利科技, 2016, 14(5),7-12.    
[16] 李栋楠,赵建世*(2016),梯级水库调度的发电–生态效益均衡分析,水力发电学报, 35.2,37-44.    
[17] 万文华 , 尹骏翰 , 赵建世, 雷晓辉 , 廖卫红 , 秦 韬 (2016), 南水北调条件下北京市供水可持续评价,南水北调与水利科技,14.2,66-73.    
[18] 刘悦忆,赵建世*,黄跃飞,施勇,陈炼钢(2015),基于蒙特卡洛模拟的水质概率预报模型,水利学报,46(1),51-57.
[19] 王丽珍; 黄跃飞; 王光谦; 赵建世(2015), 巴彦淖尔市水市场水权交易模型研究    水力发电学报, 34(6),81-87.  
[20] 陈翔,赵建世*,赵铜铁钢,雷小辉,倪广恒(2014),发电调度对径流情势及生态系统的影响分析-以小湾、糯扎渡电站为例,水力发电学报,33(4),36-43.
[21] 赵建世(2011), 水资源市场管理和行政管理的对比分析,中国水利,06.23,1-3.
[22] 杨芬; 王忠静; 赵建世(2010),作为流域山坡单元离散控制参数的河网阈值,清华大学学报(自然科学版),2010(3): 380-382.
[23] 唐文哲; 强茂山; 王忠静; 赵建世; 王光谦(2010),流域管理与区域管理相结合的机制研究,水力发电学报,第2期. 9.
[24] 廖四辉; 程绪水; 施勇; 马真臻; 赵建世; 王忠静(2010),淮河生态用水多层次分析平台与多目标优化调度模型研究,水力发电学报,2010(4),14-19。
[25] 赵建世,王忠静,甘泓,李海红(2009),双要素水资源承载能力计算模型及其应用,水力发电学报,28(3), 176-180.
[26] 赵建世,王忠静,秦韬,李海红 (2008),海河流域水资源承载能力演变分析,水利学报, 39(6),647-658.
[27] 王忠静; 杨芬; 赵建世; 何杉(2008),基于分布式水文模型的水资源评价新方法,水利学报,39(12),1209.
[28] 王学凤,赵建世,王忠静(2007),水资源使用权分配模型研究,水科学进展,第18 卷第2 期,241-245.    
[29] 王学凤,赵建世,王忠静(2007),南水北调西线一期工程调水对黄河流域影响分析,水力发电学报,第26 卷第2 期,2007 年4 月.
[30] 曹建廷; 秦大河; 罗勇; 赵建世(2007),长江源区1956-2000年径流量变化分析,水科学进展,2007,18(1)
[31] 胡立堂; 王忠静; 赵建世(2007); 马义华,地表水和地下水相互作用及集成模型研究,水利学报,2007,38(1):54-59.
[32] 李海红;赵建世(2005),初始水权分配原则及其量化方法, 应用基础与工程科学学报 13, SUPPL., 8-14.  
[33] 王忠静 熊雁晖 赵建世(2004),基于区域经济层次交互分析的流域需水预测方法,水力发电学报,23(5),78-82.
[34] 赵建世,王忠静,杨华,李涌平,翁文斌 (2003),可持续发展的人口承载能力模型,清华大学学报(自然科学版),43(2), 258-261.
[35] 王大正,赵建世,蒋慕川等.“多目标多层次流域需水预测系统开发与应用”,水科学进展,2002,13(1):49-54.

三、专著
[1] 郑航,王忠静,赵建世,水权分配、管理及交易—理论、技术与实务,中国水利水电出版社,2019.
[2] 赵建世,杨元月,黄淮海流域水资源配置模型研究,中国科学出版社,2015.
[3] 王建华,赵建世,李海红,赵勇,彭少明,南水北调水资源综合配置研究,中国科学出版社, 2013.
[4] 刘宁,王建华,赵建世,现代水资源系统解析与决策方法研究,科学出版社,2010.
[5] 赵建世,王忠静,翁文斌,水资源系统的复杂性理论方法与应用,清华大学出版社,2008.
[6] 翁文斌,王忠静,赵建世,现代水资源规划——理论、方法、技术,清华大学出版社,2004.







Baidu
sogou