张永勇

中国科学院地理科学与资源研究所

浏览次数

30

收藏次数

0

接洽次数

0

  • 张永勇
  • 副研究员

个人简况

男,1981年生,湖北荆门人,工学博士,副研究员,硕士生导师。国际水文科学协会(IAHS)会员、国际水资源协会(IWRA)会员、国际水利工程研究学会(IAHR)会员和中国自然资源学会会员;中国科学院青年创新促进会会员(2014041),澳大利亚Endeavour Research Fellowship(2014)和中国科学院地理科学与资源研究所秉维优秀青年人才计划获得者(2015)。近五年主持项目10余项,主要有国家自然科学基金面上项目、青年-面上连续资助、青年基金;国家重点研发计划项目专题、国家水体污染控制与治理科技重大专项专题;中国科学院重点部署项目专题、中国科学院-澳大利亚科学与工业研究组织合作研究计划专题等。已发表学术论文80余篇,其中以第一作者发表的1篇SCI论文被评为 “中国百篇最具影响国际学术论文”;成果获中国科学院地理科学与资源研究所2016年度十大研究进展(G1)、淮河水利委员会科技进步特等和一等奖;入选《南水北调与水利科技》、《Advances in Water and Atmospheric Research》等中英文学术期刊编委。

主要工作和教育经历:

2011.12-至今 中国科学院地理科学与资源研究所 副研究员、硕士生导师

2013.04-2014.12 澳大利亚联邦科学与工业研究组织(CSIRO)访问学者

2010.07-2011.12 中国科学院地理科学与资源研究所 助理研究员

2009.07-2010.06 澳大利亚Griffith University, Australian River Institute 博士后

2008.07-2010.06 中国科学院地理科学与资源研究所 自然地理专业博士后

2005.09-2008.07 武汉大学 水文学与水资源专业 博士

2003.09-2005.07 武汉大学 环境工程专业 硕士

1999.09-2003.07 华东交通大学 给水排水工程专业 学士

研究方向与成绩:

长期从事流域水循环关键过程与系统模拟方面的研究,具体研究方向有流域水-生物地球化学循环均衡模拟、水利工程水文环境效应与调控等。

主要成绩有:(1)探索了多闸坝调控河流水量水质演变的区域特征,推导了闸坝调控、入河负荷对河流水量水质影响的非线性方程。(2)以水和营养源循环作为联系各个与水相关过程的主要纽带,构建了考虑生物地球化学过程的流域水循环系统模型(HEQM),并提出了模型多要素多过程均衡率定方法,提高了水量水质的模拟精度。(3)提出闸坝对水文环境影响指标体系,全面刻画完整径流过程及其年际变化,和闸坝、排污对水污染影响与贡献等;提出了基于数值模拟和聚类归因的闸坝群区域影响量化方法,并发展了以水功能区水质保护和保障下游水资源量为目标的闸坝优化调度模式。

主要论著:

已发表学术论文80余篇,其中SCI检索 37篇;第一或通讯作者SCI 20篇、EI\CSCD\中文核心21篇;出版专著3部,获软件著作权8项,实用新型专利1项。

[1] Zhang Yongyong*, Shao Quanxi*, Ye Aizhong, Xing Hongtao and Xia Jun. Integrated water system simulation by considering hydrological and biogeochemical processes: model development, with parameter sensitivity and autocalibration. Hydrology and Earth System Sciences, 2016, 20:529–553.

[2] Zhang Yongyong*, Shao Quanxi*, Taylor John A. A balanced calibration of water quantity and quality by multi-objective optimization for integrated water system model. Journal of Hydrology 2016, 538:802-816.

[3] Zhang Yongyong*, Shao Quanxi, Zhang Shifeng*, Zhai Xiaoyan, She Dunxian. Multi-metric calibration of hydrological model to capture overall flow regimes. Journal of Hydrology 2016, 539:525-538.

[4] Zhang Yongyong*, Zhou Yujian, Shao Quanxi*, Liu Hongbin, Lei Qiuliang, Zhai Xiaoyan, Wang Xuelei. Diffuse nutrient losses and the impact factors determining their regional differences in four catchments from North to South China. Journal of Hydrology 2016, 543:577-594.

[5] Zhai Xiaoyan, Xia Jun, Zhang Yongyong*. Integrated approach of hydrological and water quality dynamic simulation for anthropogenic disturbance assessment in the Huai River Basin, China. Science of The Total Environment 2017, 598 (15):749–764.

[6] Zhang Yongyong, Xia Jun*, Liang Tao, Shao Quanxi. Impact of water projects on river flow regimes and water quality in Huai River Basin. Water Resources Management 2010, 24(5):889-908.(2010年中国百篇最具影响国际学术论文)

[7] Zhang Yongyong*, Zhai Xiaoyan, Shao Quanxi, Yan Ziqi. Assessing temporal and spatial flow regime alterations in the regulated Huai River Basin, China. Journal of Hydrology 2015, 529:384-397.

[8] Zhang Yongyong*, Fu Guobin, Sun Boyang, Zhang Shifeng*, Men Baohui. Simulation and classification of the impacts of projected climate change on flow regimes in the arid Hexi Corridor of Northwest China, Journal of Geophysical Research-Atmosphere, 2015, 120, 7429-7453.

[9] Zhang Yongyong*, Arthington Angela H., Bunn Stuart E., Mackay Stephen, Xia Jun, Kennard Mark. Classification of flow regimes for environmental flow assessment in regulated rivers: the Huai River Basin, China. River Research and Applications 2012, 28: 989–1005.

[10] Zhang Yongyong*, Xia Jun, Shao Quanxi, Zhai Xiaoyan. Water quantity and quality simulation by improved SWAT in highly regulated Huai River Basin of China. Stochastic Environmental Research & Risk Assessment 2013 27:11-27.

[11] Zhang Yongyong*, Xia Jun, Shao Quanxi, Zhang Xiang. Experimental and simulation studies on the impact of sluice regulation on water quantity and quality processes. ASCE: Journal of Hydrologic Engineering 2012, 16(4):467-477.

[12] Zhang Yongyong, Xia Jun*, Chen Junfeng, Zhang Minghua. Water quantity and quality optimization modeling of dams operation based on SWAT in Wenyu River Catchment, China. Environmental Monitoring and Assessment 2011, 173:409–430.

[13] Zhang Yongyong, Shao Quanxi, Xia Jun*, Bunn Stuart E., Zuo Qiting. Changes of flow regimes and precipitation in Huai River Basin in the last half century. Hydrological Processes 2011, 25:246–257.

[14] Wang Zhonggen, Ficklin Darren L., Zhang Yongyong*, Zhang Minghua. Impact of climate change on streamflow in the arid Shiyang River Basin of northwest China. Hydrological Processes 2012, 26: 2733–2744.

[15] Zhang Yongyong, Zhang Shifeng*, Zhai Xiaoyan, Xia Jun. Runoff variation and its response to climate change in the Three Rivers Source Region. Journal of Geographical Sciences 2012, 22(5): 781-794.

[16] Zhang Yongyong, Zhang Shifeng*, Xia Jun, Hua Dong. Temporal and spatial variation of the main water balance components in the Three Rivers Source Region, China from 1960 to 2000. Environmental Earth Science 2013 68:973-983.

[17] Zhai Xiaoyan, Zhang Yongyong*, Wang Xuelei, Xia Jun. Non-point source pollution modeling using Soil and Water Assessment Tool and its parameter sensitivity analysis in Xin’anjiang Catchment, China. Hydrological Processes 2014, 28, 1627-1640.

[18] Zhang Yongyong*, She Dunxian, Xia Jun, Zhai Xiaoyan, Zuo Qiting. Causal analysis on the specified paroxysmal water pollution incidents in Huai River Basin. Environmental Engineering and Management Journal 2015, 14(1):139-151.

[19] Xia Jun, Zhang Yongyong*, Zhao Changsen, Stuart E. Bunn. Bioindicator assessment framework of river ecosystem health and the detection of factors influencing the health of the Huai River Basin, China Journal of Hydrologic Engineering 2014,19(8), 04014008. doi:10.1061/(ASCE)HE.1943-5584.0000989,2014.

[20] Xia Jun*, Zhang Yongyong*, Xiong Lihua, He Shan, Wang Longfeng, Yu Zhongbo. Opportunities and challenges of the Sponge City construction related to urban water issues in China. Science China: Earth Sciences 2017, 60(4): 652–658.

[21] 张永勇,夏军,翟晓燕. 闸坝的水文水环境效应及其量化方法探讨. 地理科学进展 2013, 32(1):105-113.

[22] 张永勇,夏军,陈军峰,孟德娟.基于SWAT模型的闸坝水量水质优化调度模式研究.水力发电学报 2010,29(5):159-164.

[23] 张永勇,夏军,王纲胜,蒋艳,赵长森. 淮河流域闸坝联合调度对河流水质影响分析. 武汉大学学报 2007,40(4): 31-35.

[24] 张永勇,陈军峰,夏军,孟德娟. 温榆河流域闸坝群对河流水量水质影响研究.自然资源学报2009, 24(10):1697-1705.

[25] Xia Jun, Zhang yongyong*, Wang gangsheng. Assessment of dam impacts on river flow regimes and water quality: a case study of the Huai River Basin in P. R. China. Journal of Chongqing University(English Edition) 2008,7(4):260-274.

[26] 张永勇,王中根,夏军,柳文华,刘晓洁. 基于水循环过程的水量水质联合评价方法. 自然资源学报 2009, 24(7): 1308-1314.

[27] 张永勇,王中根,于磊,夏军,陈向东. SWAT水质模块的扩展及其在海河流域典型区的应用.资源科学 2009,31 (1):94-100.

[28] 张永勇,王中根,于静洁,翟晓燕. 流域COD减排核证研究-以淮河中上游为例.自然资源学报, 2014, 29(5):819-829.

[29] 孙波扬,张永勇*,门宝辉,张士锋. 分布式水循环模型的参数优化算法比较及应用.资源科学 2013,35(11):2217-2223.

[30] 张永勇,花瑞祥. 基于水动力-水质模型的湖库安全纳污量化. 华北水利水电大学学报(自然科学版),2016, 37(5): 33-39.

[31] 刘昌明, 张永勇*, 王中根, 王月玲, 白鹏. 维护良性水循环的城镇化LID模式:海绵城市规划方法与技术初步探讨. 自然资源学报, 2016, 31 (5): 719-731.

[32] 张永勇,张士锋,翟晓燕,夏军.三江源区径流演变及其对气候变化的响应. 地理学报 2012,67(1):71-82.

[33] 张永勇, 张士锋, 翟晓燕, 孟秀敬, 王中根.气候变化下石羊河流域径流模拟与影响量化.资源科学 2013,35(3):601-609.

[34] 张永勇,花瑞祥,夏瑞.气候变化对淮河流域水量水质影响分析.自然资源学报, 2017, 32(1): 114-126.

[35] 花瑞祥,张永勇*,刘威,杨逸航.不同评价方法对水库水质评价的适应性分析.南水北调与水利科技, 2016, 14(4) : 1-7.

[36] 周宇建,张永勇*,花瑞祥,左其亭,陈豪. 淮河中上游浮游植物时空分布特征及关键环境影响因子识别.地理研究, 2016, 35(9): 1626-1636.

[37] 张永勇,李宗礼,刘晓洁.近千年淮河流域河湖水系连通演变特征.南水北调与水利科技,2016,14(4) :77-83.

[38] 左其亭,陈豪,张永勇*,窦明,刘静. 淮河中上游轮虫群落结构分析及水质评价.环境工程学报, 2017, 11(1): 165-173.

[39] 张永勇,夏军,王中根. 区域水资源承载力理论与方法探讨. 地理科学进展 2007,26(2):126-132.

[40] Zhang Yongyong, Xia Jun, Wang Zhonggen. Integrated water resources carrying capacity in Tongzhou District, Beijing City .Journal of Resources and Ecology 2010, 1(3):253-258.

[41] 张永勇,张光义,夏军,王红萍. 湿地污水处理机理的研究.环境科学与技术2005, 28(S1):165-167.

专著

张永勇,夏军,程绪水,张翔. 多闸坝流域水文环境效应研究及应用. 中国水利水电出版社,2011.

软件著作权

[1] 张永勇. 复杂流域水系统模型系统.登记号:2016SR040307.

[2] 张永勇. 流域水系统模型参数分析软件.登记号:2016SR039945.

[3] 张永勇. 淮河流域多闸坝分布式时变增益模拟系统.登记号: 2016SR040518.

[4] 张永勇. 水库入流预报系统.登记号: 2016SR148971.

[5] 张永勇,夏军,等. 温榆河流域水质水量联合调控系统. 登记号: 2011SR095375.

[6] 张永勇,夏军,等. 分布式时变增益水量水质耦合模拟系统. 登记号: 2011SR095221.