西安交通大学人居环境与建筑工程学院导师教师师资介绍简介-吴一平

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Welcome - 吴一平基本信息

吴一平
博士
教授，博士生导师
西安交通大学，人居环境与建筑工程学院，地球环境科学系
全球环境变化研究院

联系方式
陕西省西安市雁翔路99号
交大曲江校区西一楼
邮编：710051
Email: yipingwu@xjtu.edu.cn
rocky.ypwu@gmail.com

站点计数器

研究领域
环境变化与生态水文
流域水文水资源、面源污染、区域生态系统水碳氮循环、生态过程与生态系统服务、农业水土资源、气候与土地利用变化、数据同化、模型开发与集成

教育背景
博士 2009香港大学，土木系，水与环境工程
硕士 2004西安建筑科技大学，环境与市政工程学院，环境工程
学士 2001西安建筑科技大学，环境与市政工程学院，环境工程

工作经历
2015/09~至今：教授，西安交通大学，人居环境与建筑工程学院，地球环境科学系
2014/12~ 2015/08：高级科学家，北极区域联盟，美国地质调查局地球资源观测与科学中心 (USGS EROS Center）
2009/11 ~ 2014/11：科学家，北极区域联盟，美国地质调查局地球资源观测与科学中心（USGS EROS Center）

学术任职与荣誉
· 国家青年人才计划
·陕西省****
·教育部自然保护与环境生态类教指委委员
·教育部首批百名全国高校“双带头人”教师党支部书记工作室负责人
· 全球生物能源组织生物能源与水“主题专家”
· 亚洲大洋洲地球科学学会（AOGS）水文分会秘书
· 中国生态学会生态水文专业委员会委员
· 国内外知名期刊副主编和编委（SERRA, CBM, Engineering,Geosci Lett, Sci Rep,农环学报）
·国家重点研发计划、国家人才项目评审专家
· 亚洲大洋洲地球科学学会“青年科学家杰出报告”AOGS Early Career Researcher Distinguished Lecture
· 中国工程院工程科技国际高端论坛邀请报告CAE International Summit Forum on Engineering and Technology

主持或参与科研项目
·美国宇航局生物能源项目：美国北部大平原农业变化的生态环境效应
·美国内务部陆地碳项目：美国生物固碳及温室气体减排潜力评估
·美国地质调查局项目：生态系统碳循环模拟预测不确定性
·国家重点研发计划：祁连山生态环境变化评估、预警与监控
·国家自然科学基金：黄土高原农田土壤有机碳研究
·陕西省重点研发计划：陕北煤炭基地环境遥感动态监测系统

主要期刊论文
Li H, Wu Y*, Liu S, Xiao J, 2021. Regional contributions to interannual variability of net primary production and climatic attributions. Agricultural and Forest Meteorology, in press.
Li H, Wu Y*, Chen J, Zhao F, Wang F, Sun Y, et al., 2021. Responses of soil organic carbon to climate change in the Qilian Mountains and its future projection. Journal of Hydrology, in press.
Zhao F, Wu Y*, Yin X, Alexandrov G, Qiu L, 2021. Toward sustainable revegetation in the Loess Plateau using coupled water and carbon management. Engineering, 7, 1-12.
Hu J, Wu Y*, Wang L, Sun P, Zhao F, Jin Z, et al., 2021. Impacts of land-use conversions on the water cycle in a typical watershed in the southern Chinese Loess Plateau. Journal of Hydrology, 593, 125741.
Hui J, Wu Y*, Zhao F, Lei X, Sun P, Singh SK, et al., 2020. Parameter Optimization for Uncertainty Reduction and Simulation Improvement of Hydrological Modeling. Remote Sensing, 12, 4069.
Zhao F, Wu Y*, Wang L, Liu S, Wei X, Xiao J, Qiu L, Sun P, 2020. Multi-environmental impacts of biofuel production in the U.S. Corn Belt: A coupled hydro-biogeochemical modeling approach. Journal of Cleaner Production, 251, 119561.
Zhao F, Wu Y*, Yao Y, Sun K, Zhang X, Winowiecki L, et al., 2020. Predicting the climate change impacts on water-carbon coupling cycles for a loess hilly-gully watershed. Journal of Hydrology, 581, 124388.
Sun P, Wu Y*, Wei X, Sivakumar B, Qiu L, Chen J, et al., 2020. Quantifying the contributions of climate variation, land use change, and engineering measures for dramatic reduction in streamflow and sediment in a typical Loess watershed, China. Ecological Engineering, 142, 105611.
Sun P, Wu Y*, Gao J, Yao Y, Zhao F, Lei X, et al., 2020. Shifts of sediment transport regime caused by ecological restoration in the Middle Yellow River Basin. Science of the Total Environment, 698, 134261.
Sun P, Wu Y*, Yang Z, Bellie S, Qiu L, Liu S, Cai Y, 2019. Can ‘Grain-for-Green’ program really ensure a low sediment load on the Chinese Loess Plateau? Engineering, 5, 855–864.
Sun P, Wu Y*, Xiao J, Hui J, Hu J, Zhao F, et al., 2019. Remote sensing and modeling fusion for investigating the ecosystem water-carbon coupling processes. Science of the Total Environment, 697, 134064.
Zhao F, Wu Y*, Bellie S, Long A*, Qiu L, Chen J, et al., 2019. Climatic and hydrologic controls on net primary production in a semiarid loess watershed. Journal of Hydrology, 568, 803–815.
Feng S, Liu S, Huang Z, Jing L, Zhao M, Peng Xi, Yan W, Wu Y, et al., 2019. Inland Water Bodies in China: New Features Discovered in the Long-term Satellite Data. Proceedings of the National Academy of Sciences of the United States of America (PNAS).
Qiu L, Wu Y*, Hao M, Shen J, Lei X, Liao W, Li Y, 2018. Simulation of the irrigation requirements for improving carbon sequestration in a rainfed cropping system under long-term fertilization on the. Agriculture, Ecosystems and Environment, 265: 198–208.
Zhao F, Wu Y*, Qiu L, Sun Y, Sun L, Li Q, et al., 2018. Parameter Uncertainty Analysis of the SWAT Model in a Mountain-Loess Transitional Watershed on Chinese Loess Plateau. Water, 10, 690.
Zhao F, Wu Y*, Qiu L, Sivakumar B, Zhang F, Sun Y, Sun L and Li Q, 2018. Spatiotemporal features of the hydro-biogeochemical cycles in a typical loess gully watershed. Ecological Indicators, 91: 542–554.
Qiu L, Wu Y*, Wang L, Hui Y, Lei X, Liao W, Meng X, 2017. Spatiotemporal response of the water cycle to land use conversions in a typical hilly-gully basin on the Loess Plateau, China. Hydrology and Earth System Sciences, 21(12): 6485–6499.
Li Z, Liu S, Tan Z, Sohl TL, Wu Y, 2017. Simulating the effects of management practices on cropland soil organic carbon changes in the Temperate Prairies Ecoregion of the United States from 1980 to 2012. Ecological Modelling, 364: 68–79.
Zhang F*, Wang Z, Glidden S, Wu Y*, Tang L, Liu Q, et al., 2017. Changes in the soil organic carbon balance on China's cropland during the last two decades of the 20th century. Scientific Reports, 7, 7144.
Li P, Mu X, Holden J, Wu Y, Irvine B, Wang F, et al., 2017. Comparison of soil erosion models used to study the Chinese Loess Plateau. Earth-Science Reviews, 170: 17–30.
Qiu L, Hao M, Wu Y*, 2017. Potential impacts of climate change on carbon dynamics in a rain-fed agro-ecosystem on the Loess Platau of China. Science of the Total Environment, 577: 267–278.
Wu Y*, Liu S, Qiu L, and Sun Y, 2016. SWAT-DayCent coupler: An integration tool for simultaneous hydro-biogeochemical modeling using SWAT and DayCent. Environmental Modelling & Software, 86: 81–90.
Tan Z*, Liu S*, Sohl T, Wu Y, and Young C, 2015. Ecosystem carbon stocks and sequestration potential of federal lands across the conterminous United States. Proceedings of the National Academy of Sciences of the United States of America, 112(41): 12723–12728.
Wu Y*, Liu S*, Young C, Dahal D, Sohl T, and Davis B, 2015. Projection of corn production and stover harvesting impacts on soil organic carbon dynamics in the U.S. Temperate Prairies. Scientific Reports, 5, 10830.
Wu Y, Liu S*, Yan W*, Xia J, Xiang W, Wang K, Luo Q, Fu W, and Yuan W, 2015. Climate change and consequences on the water cycle in the humid Xiangjiang River Basin, China. Stochastic Environmental Research and Risk Assessment, 30(1): 225–235.
Wu Y*, Liu S*, and Tan Z, 2015. Quantitative attribution of major driving forces on soil organic carbon dynamics. Journal of Advances in Modeling Earth Systems, 7(1): 21–34.
Wu Y*, Liu S*, and Yan W, 2014. A universal Model-R Coupler to facilitate the use of R functions for model calibration and analysis. Environmental Modelling & Software, 62: 65–69.
Wu Y* and Liu S*, 2014. A suggestion for computing objective function in model calibration, Ecological Informatics, 24: 107–111.
Wu Y*, Cheng D, Yan W*, Liu S, Xiang W, Chen J, Hu Y, Wu Q, 2014. Diagnosing climate change and hydrological responses in the past decades for a minimally-disturbed headwater basin in South China, Water Resources Management, 28(12): 4385–4400.
Wu Y*, Liu S*, Huang Z, Yan W, 2014. Parameter optimization, sensitivity and uncertainty analysis of an ecosystem model at a forest flux tower site in the United States. Journal of Advances in Modeling Earth Systems, 6(2): 405–419.
Wu Y*, Liu S*, Li Z, Dahal D, Young C, Schmidt GL, Liu J, Davis B, Sohl TL, Werner J, and Oeding J, 2014. Development of a generic auto-calibration package for regional ecological modeling and application in the Central Plains of the United States, Ecological Informatics, 19: 35–46.
Wu Y* and Liu S*, 2014. Improvement of the R-SWAT-FME framework to support multiple variables and multi-objective functions, Science of the Total Environment, 466–467: 455–466.
Wu Y*, Liu S*, Sohl T, and Young C, 2013. Projecting the land cover change and its environmental impacts in the Cedar River Basin in the Midwestern United States, Environmental Research Letters, 8(2), 024025.
Wu Y* and Chen J*, 2013. Investigating the effects of point source and nonpoint source pollution on the water quality of the East River (Dongjiang) in South China, Ecological Indicators, 32: 294–304.
Wu Y* and Chen J*, 2013. Analyzing the water budget and hydrological characteristics and responses to land use in a monsoonal climate river basin in South China, Environmental Management, 51(6): 1174-1186.
Wu Y*, Li T*, Sun L, and Chen J, 2013. Parallelization of a hydrological model using the message passing interface, Environmental Modelling & Software, 43: 124–132.
Wu Y and Chen J*, 2013. Estimating irrigation water demand using an improved method and optimizing reservoir operation for water supply and hydropower generation: a case study of the Xinfengjiang reservoir in southern China, Agricultural Water Management, 116: 110–121.
Wu Y and Chen J*, 2012. Modeling of soil erosion and sediment transport in the East River Basin in southern China, Science of the Total Environment, 441: 159–168.
Wu Y and Liu S*, 2012. Modeling of land use and reservoir effects on nonpoint source pollution in a highly agricultural basin, Journal of Environmental Monitoring, 14(9): 2350–2361.
Wu Y, Liu S*, and Gallant A, 2012. Predicting impacts of increased CO₂ and climate change on the water cycle and water quality in the semiarid James River Basin of the Midwestern USA, Science of the Total Environment, 430: 150–160.
Wu Y, Liu S*, and Chen J, 2012. Urbanization eases water crisis in China, Environmental Development, 2: 142–144.
Wu Y, Liu S* and Li Z, 2012. Identifying potential areas for biofuel production and evaluating the environmental effects: a case study of the James River Basin in the Midwestern United States, Global Change Biology Bioenergy, 4(6): 875–888.
Wu Y and Liu S*, 2012. Automating calibration, sensitivity and uncertainty analysis of complex models using the R package Flexible Modeling Environment (FME): SWAT as an example, Environmental Modelling & Software, 31: 99–109.
Wu Y and Liu S*, 2012. Impacts of biofuels production alternatives on water quantity and quality in the Iowa River Basin, Biomass & Bioenergy, 36:182–191.
Wu Y and Chen J*, 2012. An operation-based scheme for a multiyear and multipurpose reservoir to enhance macro-scale hydrologic models, Journal of Hydrometeorology, 13(1): 270–283.
Wu Y, Liu S*, and Abdul-Aziz OI, 2012. Hydrological effects of the increased CO₂ and climate change in the Upper Mississippi River Basin Using a modified SWAT, Climatic Change, 110(3–4): 977–1003.
Chen J* and Wu Y, 2012. Advancing representation of hydrologic processes in the Soil and Water Assessment Tool (SWAT) through integration of the TOPographic MODEL (TOPMODEL) features, Journal of Hydrology, 420–421: 319–328.
Zhou G*, Wei X, Wu Y, Liu S, Huang Y, Yan J, Zhang D, Zhang Q, Liu J, Meng Z, Wang C, Chu G, Liu SZ, Tang X, and Liu X, 2011. Quantifying the hydrological responses to climate change using an intact forested small watershed in Southern China, Global Change Biology, 17(12): 3736–3746.

USGS专业论文与开放报告

1. Liu S, Liu J, Wu Y, Young C, Werner JM, Dahal D, Oeding J, and Schmidt GL, 2014. Baseline and Projected Future Carbon Storage, Carbon Sequestration, and Greenhouse-Gas Fluxes in Terrestrial Ecosystems of the Eastern United States, Chapter 7 of Baseline and Projected Future Carbon Storage and Greenhouse-Gas Fluxes in Ecosystems of the Eastern United States (eds Zhu Z and Reed B), U.S. Geological Survey Professional Paper 1804. pp.115–156. Reston, Virginia.
2. Liu S, Wu Y, Young C, Dahal D, Werner JM, Liu J, Li Z, Tan Z, Schmidt GL, Oeding J, Sohl TL, Hawbaker TJ, and Sleeter BM, 2012. Projected Future Carbon Storage and Greenhouse-Gas Fluxes of Terrestrial Ecosystems in the Western United States, Chapter 9 of Baseline and Projected Future Carbon Storage and Greenhouse-Gas Fluxes in Ecosystems of the Western United States (eds Zhu Z and Reed B), U.S. Geological Survey Professional Paper 1797. pp. 109–124. Reston, Virginia.
3. Liu S, Liu J, Young C, Werner JM, Wu Y, Li Z, Dahal D, Oeding J, Schmidt GL, Sohl TL, Hawbaker TJ, and Sleeter BM, 2012. Baseline Carbon Storage, Carbon Sequestration, and Greenhouse-Gas Fluxes in Terrestrial Ecosystems of the Western United States, Chapter 5 of Baseline and Projected Future Carbon Storage and Greenhouse-Gas Fluxes in Ecosystems of the Western United States (eds Zhu Z and Reed B), U.S. Geological Survey Professional Paper 1797. pp. 45–63. Reston, Virginia.
4. Wu Y and Liu S, 2012. R-SWAT-FME User’s Guide, U.S. Geological Survey Open-File Report 2012-1071. pp. 5. Reston, Virginia.

招生、合作需求
课题组（环境变化与生态水文实验室）长期招收具有水文学、生态学、RS、GIS等专业背景的硕士生、博士生、博士后、交流访问****等。诚邀有志于从事生态水文与环境保护事业的学生****加盟或交流探讨。欢迎来信联系。

Model / Software
SWAT-DayCent Coupler
GEMS-EDCM-Auto
Model-R Coupler
R-SWAT-FME
SWAT-CO2
P-SWAT

English - 吴一平Basic Information

Yiping (Rocky) Wu

PhD, Professor
Institute of Global Environmental Change

Department of Earth & Environmental Science
School of Human Settlements & Civil Engineering
Xi’an Jiaotong University

Contact
School of Human Settlements & Civil Engineering
Xi'an Jiaotong University
99 Yanxiang Road, West One Building, JiaoDaQujiang Campus
Xi'an, Shaanxi Province, 710049, China
Email: yipingwu@mail.xjtu.edu.cn
rocky.ypwu@gmail.com

Research Interest
Environmental Change and Eco-hydrology
Watershed hydrology, Nonpoint source pollution, Climate change, Land-use change,Ecosystem Water-Carbon-Nitrogen cycle and coupling, Soil moisture, Soil organic carbon, Agricultural management, Greenhouse gas emissions,Data assimiliation, Model development and integration

Education
Ph.D. 2009 in Water & Environmental Engineering, The University of Hong Kong, HKSAR
M.E.2004 in Environmental Engineering, Xi’an University of Arch. & Tech., Xi’an, China
B.E.2001 in Environmental Engineering, Xi’an University of Arch. & Tech., Xi’an, China

Academic Positions/Honors
National Youth Talent Program of China
'Hundred Talent Program' of Shaanxi Province
Member of Higher Education Teaching Committee of Ministry of Education
'Young Talent Support Plan' of Xi'an Jiaotong University
Oversea Endowed Professor, National Engineering Laboratory for Applied Technology of Forestry & Ecology in South China
Subject Matter Expert, Global Bioenergy Partnership (GBEP)’s Bioenergy and Water field
Secretary of Hydrological Section of AOGS
Member of Ecohydrology Team of China's Ecology Society
Associate Editor / Editorial Board Member for international journals (SERRA, CBM, Engineering, Geoscience Letters, Sci Rep)
AOGSEarly Career Researcher Distinguished Lecture

Projects participated
NSF of China International Cooperation Program
National Key Research and Development Program
NSF of China and Hong Kong Research Grants Council (RGC) Joint Research Scheme
Hong Kong Research Grants Council (RGC)
NASA Bioenergy
U.S. Department of Interior Land Carbon
USGS Carbon Trends

Selected journal publications
Li H, Wu Y*, Liu S, Xiao J, 2021. Regional contributions to interannual variability of net primary production and climatic attributions. Agricultural and Forest Meteorology, in press.
Li H, Wu Y*, Chen J, Zhao F, Wang F, Sun Y, et al., 2021. Responses of soil organic carbon to climate change in the Qilian Mountains and its future projection. Journal of Hydrology, in press.
Zhao F, Wu Y*, Yin X, Alexandrov G, Qiu L, 2021. Toward sustainable revegetation in the Loess Plateau using coupled water and carbon management. Engineering, 7, 1-12.
Hu J, Wu Y*, Wang L, Sun P, Zhao F, Jin Z, et al., 2021. Impacts of land-use conversions on the water cycle in a typical watershed in the southern Chinese Loess Plateau. Journal of Hydrology, 593, 125741.
Hui J, Wu Y*, Zhao F, Lei X, Sun P, Singh SK, et al., 2020. Parameter Optimization for Uncertainty Reduction and Simulation Improvement of Hydrological Modeling. Remote Sensing, 12, 4069.
Zhao F, Wu Y*, Wang L, Liu S, Wei X, Xiao J, Qiu L, Sun P, 2020. Multi-environmental impacts of biofuel production in the U.S. Corn Belt: A coupled hydro-biogeochemical modeling approach. Journal of Cleaner Production, 251, 119561.
Zhao F, Wu Y*, Yao Y, Sun K, Zhang X, Winowiecki L, et al., 2020. Predicting the climate change impacts on water-carbon coupling cycles for a loess hilly-gully watershed. Journal of Hydrology, 581, 124388.
Sun P, Wu Y*, Wei X, Sivakumar B, Qiu L, Chen J, et al., 2020. Quantifying the contributions of climate variation, land use change, and engineering measures for dramatic reduction in streamflow and sediment in a typical Loess watershed, China. Ecological Engineering, 142, 105611.
Sun P, Wu Y*, Gao J, Yao Y, Zhao F, Lei X, et al., 2020. Shifts of sediment transport regime caused by ecological restoration in the Middle Yellow River Basin. Science of the Total Environment, 698, 134261.
Sun P, Wu Y*, Yang Z, Bellie S, Qiu L, Liu S, Cai Y, 2019. Can ‘Grain-for-Green’ program really ensure a low sediment load on the Chinese Loess Plateau? Engineering, 5, 855–864.
Sun P, Wu Y*, Xiao J, Hui J, Hu J, Zhao F, et al., 2019. Remote sensing and modeling fusion for investigating the ecosystem water-carbon coupling processes. Science of the Total Environment, 697, 134064.
Zhao F, Wu Y*, Bellie S, Long A*, Qiu L, Chen J, et al., 2019. Climatic and hydrologic controls on net primary production in a semiarid loess watershed. Journal of Hydrology, 568, 803–815.
Feng S, Liu S, Huang Z, Jing L, Zhao M, Peng Xi, Yan W, Wu Y, et al., 2019. Inland Water Bodies in China: New Features Discovered in the Long-term Satellite Data. Proceedings of the National Academy of Sciences of the United States of America (PNAS).
Qiu L, Wu Y*, Hao M, Shen J, Lei X, Liao W, Li Y, 2018. Simulation of the irrigation requirements for improving carbon sequestration in a rainfed cropping system under long-term fertilization on the. Agriculture, Ecosystems and Environment, 265: 198–208.
Zhao F, Wu Y*, Qiu L, Sun Y, Sun L, Li Q, et al., 2018. Parameter Uncertainty Analysis of the SWAT Model in a Mountain-Loess Transitional Watershed on Chinese Loess Plateau. Water, 10, 690.
Zhao F, Wu Y*, Qiu L, Sivakumar B, Zhang F, Sun Y, Sun L and Li Q, 2018. Spatiotemporal features of the hydro-biogeochemical cycles in a typical loess gully watershed. Ecological Indicators, 91: 542–554.
Qiu L, Wu Y*, Wang L, Hui Y, Lei X, Liao W, Meng X, 2017. Spatiotemporal response of the water cycle to land use conversions in a typical hilly-gully basin on the Loess Plateau, China. Hydrology and Earth System Sciences, 21(12): 6485–6499.
Li Z, Liu S, Tan Z, Sohl TL, Wu Y, 2017. Simulating the effects of management practices on cropland soil organic carbon changes in the Temperate Prairies Ecoregion of the United States from 1980 to 2012. Ecological Modelling, 364: 68–79.
Zhang F*, Wang Z, Glidden S, Wu Y*, Tang L, Liu Q, et al., 2017. Changes in the soil organic carbon balance on China's cropland during the last two decades of the 20th century. Scientific Reports, 7, 7144.
Li P, Mu X, Holden J, Wu Y, Irvine B, Wang F, et al., 2017. Comparison of soil erosion models used to study the Chinese Loess Plateau. Earth-Science Reviews, 170: 17–30.
Qiu L, Hao M, Wu Y*, 2017. Potential impacts of climate change on carbon dynamics in a rain-fed agro-ecosystem on the Loess Platau of China. Science of the Total Environment, 577: 267–278.
Wu Y*, Liu S, Qiu L, and Sun Y, 2016. SWAT-DayCent coupler: An integration tool for simultaneous hydro-biogeochemical modeling using SWAT and DayCent. Environmental Modelling & Software, 86: 81–90.
Tan Z*, Liu S*, Sohl T, Wu Y, and Young C, 2015. Ecosystem carbon stocks and sequestration potential of federal lands across the conterminous United States. Proceedings of the National Academy of Sciences of the United States of America, 112(41): 12723–12728.
Wu Y*, Liu S*, Young C, Dahal D, Sohl T, and Davis B, 2015. Projection of corn production and stover harvesting impacts on soil organic carbon dynamics in the U.S. Temperate Prairies. Scientific Reports, 5, 10830.
Wu Y, Liu S*, Yan W*, Xia J, Xiang W, Wang K, Luo Q, Fu W, and Yuan W, 2015. Climate change and consequences on the water cycle in the humid Xiangjiang River Basin, China. Stochastic Environmental Research and Risk Assessment, 30(1): 225–235.
Wu Y*, Liu S*, and Tan Z, 2015. Quantitative attribution of major driving forces on soil organic carbon dynamics. Journal of Advances in Modeling Earth Systems, 7(1): 21–34.
Wu Y*, Liu S*, and Yan W, 2014. A universal Model-R Coupler to facilitate the use of R functions for model calibration and analysis. Environmental Modelling & Software, 62: 65–69.
Wu Y* and Liu S*, 2014. A suggestion for computing objective function in model calibration, Ecological Informatics, 24: 107–111.
Wu Y*, Cheng D, Yan W*, Liu S, Xiang W, Chen J, Hu Y, Wu Q, 2014. Diagnosing climate change and hydrological responses in the past decades for a minimally-disturbed headwater basin in South China, Water Resources Management, 28(12): 4385–4400.
Wu Y*, Liu S*, Huang Z, Yan W, 2014. Parameter optimization, sensitivity and uncertainty analysis of an ecosystem model at a forest flux tower site in the United States. Journal of Advances in Modeling Earth Systems, 6(2): 405–419.
Wu Y*, Liu S*, Li Z, Dahal D, Young C, Schmidt GL, Liu J, Davis B, Sohl TL, Werner J, and Oeding J, 2014. Development of a generic auto-calibration package for regional ecological modeling and application in the Central Plains of the United States, Ecological Informatics, 19: 35–46.
Wu Y* and Liu S*, 2014. Improvement of the R-SWAT-FME framework to support multiple variables and multi-objective functions, Science of the Total Environment, 466–467: 455–466.
Wu Y*, Liu S*, Sohl T, and Young C, 2013. Projecting the land cover change and its environmental impacts in the Cedar River Basin in the Midwestern United States, Environmental Research Letters, 8(2), 024025.
Wu Y* and Chen J*, 2013. Investigating the effects of point source and nonpoint source pollution on the water quality of the East River (Dongjiang) in South China, Ecological Indicators, 32: 294–304.
Wu Y* and Chen J*, 2013. Analyzing the water budget and hydrological characteristics and responses to land use in a monsoonal climate river basin in South China, Environmental Management, 51(6): 1174-1186.
Wu Y*, Li T*, Sun L, and Chen J, 2013. Parallelization of a hydrological model using the message passing interface, Environmental Modelling & Software, 43: 124–132.
Wu Y and Chen J*, 2013. Estimating irrigation water demand using an improved method and optimizing reservoir operation for water supply and hydropower generation: a case study of the Xinfengjiang reservoir in southern China, Agricultural Water Management, 116: 110–121.
Wu Y and Chen J*, 2012. Modeling of soil erosion and sediment transport in the East River Basin in southern China, Science of the Total Environment, 441: 159–168.
Wu Y and Liu S*, 2012. Modeling of land use and reservoir effects on nonpoint source pollution in a highly agricultural basin, Journal of Environmental Monitoring, 14(9): 2350–2361.
Wu Y, Liu S*, and Gallant A, 2012. Predicting impacts of increased CO₂ and climate change on the water cycle and water quality in the semiarid James River Basin of the Midwestern USA, Science of the Total Environment, 430: 150–160.
Wu Y, Liu S*, and Chen J, 2012. Urbanization eases water crisis in China, Environmental Development, 2: 142–144.
Wu Y, Liu S* and Li Z, 2012. Identifying potential areas for biofuel production and evaluating the environmental effects: a case study of the James River Basin in the Midwestern United States, Global Change Biology Bioenergy, 4(6): 875–888.
Wu Y and Liu S*, 2012. Automating calibration, sensitivity and uncertainty analysis of complex models using the R package Flexible Modeling Environment (FME): SWAT as an example, Environmental Modelling & Software, 31: 99–109.
Wu Y and Liu S*, 2012. Impacts of biofuels production alternatives on water quantity and quality in the Iowa River Basin, Biomass & Bioenergy, 36:182–191.
Wu Y and Chen J*, 2012. An operation-based scheme for a multiyear and multipurpose reservoir to enhance macro-scale hydrologic models, Journal of Hydrometeorology, 13(1): 270–283.
Wu Y, Liu S*, and Abdul-Aziz OI, 2012. Hydrological effects of the increased CO₂ and climate change in the Upper Mississippi River Basin Using a modified SWAT, Climatic Change, 110(3–4): 977–1003.
Chen J* and Wu Y, 2012. Advancing representation of hydrologic processes in the Soil and Water Assessment Tool (SWAT) through integration of the TOPographic MODEL (TOPMODEL) features, Journal of Hydrology, 420–421: 319–328.
Zhou G*, Wei X, Wu Y, Liu S, Huang Y, Yan J, Zhang D, Zhang Q, Liu J, Meng Z, Wang C, Chu G, Liu SZ, Tang X, and Liu X, 2011. Quantifying the hydrological responses to climate change using an intact forested small watershed in Southern China, Global Change Biology, 17(12): 3736–3746.

Research experience
SWAT-DayCent Coupler
GEMS-EDCM-Auto
Model-R Coupler
R-SWAT-FME
SWAT-CO2
P-SWAT