基本介绍　　王先伟，教授,中山大学 “****”引进人才(2011.2)。2008年博士毕业于University of Texas, San Antonio，Environmental Science and Engineering专业，师从Hongjie Xie教授，获理学博士学位。 2008年6月-2011年1月，在University of California， Irvine, Department of Earth System Science做博士后，师从Charles Zender 教授。美国地球物理协会、地理学会和中国地理、水利学会等国际和国内专业协会会员；国际期刊Water的主题编辑，多个国际和国内期刊审稿人。主要从事GIS 空间分析与应用开发、水文遥感与水工测绘、洪涝模拟与洪灾风险管理等领域的研究，分别在Remote Sensing of Environment，Journal of Geophysical Research, ?Water Resource Research, Journal of Hydrology, and Hydrological Processes?等国际一流期刊上发表多篇文章。
?学历背景2004.08-2008.05，博士，环境科学与工程，University of Texas at San Antonio, TX, USA，美国；
1999.09-2002.07，硕士，环境科学，中国科学院南海海洋研究所, 广州；
1995.09-1999.07，学士，四川师范大学，成都；
?工作经历2016.12-2017.12，访问****，University of Bristol, Bristol, UK.
2015.08-2015.09，访问****，Montana Tech of the University of Montana, Butte, MT, USA.
2015.01- 目前， 教授，中山大学地理科学与规划学院，广州
2011.02-2014.12，副教授，中山大学地理科学与规划学院，广州
2008.06-2011.01，博士后,University of California, Irvine, CA, USA
?科研项目（主持）10) 国家基金面上项目：#**，基于RTK观测与洪潮耦合模拟的珠江三角洲网河水道壅水机制研究，60万，2019.01-2022.12；
9)? 2016广东省水利科技创新重点项目：#2016-19，机载激光三维数据河道围堤险情判别及洪潮变化对江河防洪影响分析，86万，2016.4-2018.12；
8）国家基金面上项目：#** ，基于IceBridge 和ICESat激光雷达高程的南极海冰和积雪厚度分析，75万，2014.01-2017.12；
7) 国家973基础研究计划项目子课题：广州市城市暴雨内涝灾害风险综合评估，42万，2012.1-2016.12；
6) 国家863计划主题项目子课题：城市洪涝应急响应示范系统，94万，2012.1-2014.12；
5）国家气候中心项目：台风灾害风险区划的风暴潮风险区划，30万，2015.1-2016.12；
4) 广东省气象局/北京超图软件股份有限公司：广东山洪地质灾害防治气象保障工程山洪地质灾害气象风险预报系统，50万，2015.1-2015.12；
3) 荒漠与绿洲生态国家重点实验室开放基金:天山地区积雪变化对水资源可持续利用的影响,32万，2014.1-2016.12;
2) 中山大学高校基本科研业务费-青年教师重点培育项目：中亚山地冰雪变化对全球变暖的响应,30万，2015.1-2016.12；
1) 中山大学****科研启动基金，水文遥感，30万，2011.3-2013.2。
?论著专利(IF: Impact Factor for SCI Journals,* for corresponding author)
英文期刊论文
(1) 洪涝灾害（Flood）：暴雨 Storm + 风暴潮 Storm surge +洪涝灾害 Flood hazard
13)? Huang, H., Y. Pan and X. Wang*. (2020). A Simplified Representation of Pressure Flow from Surface Slopes in Urban Sewer Systems. Water, 2020, 12, 2778; doi:10.3390/w**. (IF_2019=2.544) (Article.pdf)
12)? Chen, M., T.O. Chan*, X. Wang*, M. Luo, Y. Lin, H. Huang, Y. Sun, G. Cui and Y. Huang. (2020). A Risk Analysis Framework for Transmission Towers under Potential Pluvial Flood - LiDAR Survey and Geometric Modelling. International Journal of Disaster Risk Reduction, DOI: https://doi.org/10.1016/j.ijdrr.2020.101862. ?(IF_2019=2.896)?(Article.pdf)
11)? Wang*, X., L. Wang and T. Zhang. (2020). Geometry-based assessment of levee stability and overtopping using airborne LiDAR altimetry: a case study in the Pearl River Delta, Southern China. Water, 12, 403; doi:10.3390/w**. (IF_2018=2.524)?(Article.pdf)
10)? Huang, H., X. Chen*, X. Wang*, X.N. Wang and L. Liu. (2019). A depression-based index to represent topographic control in urban pluvial flooding. Water, 11, 2115; doi:10.3390/w**. (IF_2018=2.524)?(Article.pdf)
9) ?Huang, H., L. Zhang, L. Liu*, X. Wang*, X.N. Wang, C. Pan and D. Wang. (2019). Assessing the mitigation effect of deep tunnels on urban flooding: a case study in Guangzhou, China, Urban Water Journal, DOI: 10.1080/**X.2019.**. (IF_2018=2.083)?(Article.pdf)
8) ?Pan^#, C., X. Wang*, L. Liu*, D.S. Wang, and H. Huang. (2019). Characteristics of heavy storms and the scaling relation with air temperature by event process-based analysis in South China. Water, 2019, 11, 185; doi:10.3390/w**. (IF_2018=2.524)?(Article.pdf)
7)?Wang*, X.,?and H. Xie*. (2018). A Review on Applications of Remote Sensing and Geographic Information Systems (GIS) in Water Resources and Flood Risk Management.?Water,?2018, 10, 608; doi:10.3390/w**.?(IF_2017=2.069)??(Article.pdf)
6) Huang, H., X. Chen, Z. Zhu, Y. Xie, L. Liu,?X. Wang, X.N. Wang, and K. Liu. (2018). The changing pattern of urban flooding in Guangzhou, China.?Science of the Total Environment, 622-623: 394-401. doi: 10.1016/j.scitotenv.2017.11.358. (IF_2017=4.610)?(Article.pdf)
5) Wang, X.N.,?X. Wang*, J. Zhai, X. Li, H. Huang and H. Sun. (2017). Improvement to flooding risk assessment of storm surges by residual interpolation in the coastal areas of Guangdong Province, China.?Quaternary International,?doi: 10.1016/j.quaint.2016.12.025. (IF_2017=2.163)?(Article.pdf)
4) Wang, R., J. Chen* and?X. Wang*.?(2017). Comparison of IMERG Level-3 and TMPA 3B42V7 in estimating typhoon-related heavy rain.?Water, 9(4), 276; doi:10.3390/w** ?(2017=2.069)?(Article.pdf)
3) Pan, C.,?X. Wang*, L. Liu*, H. Huang and D.S. Wang. (2017). Improvement to the Huff Curve for Design Storms and Urban Flooding Simulations in Guangzhou, China.?Water,?9(6), 411; doi:10.3390/w**. (2017=2.069)?(Article.pdf)
2) Wang, D.S.,?X. Wang*,?L. Liu*, H. Huang, C. Pan, and D.G. Wang. (2016). Evaluation of CMPA precipitation estimate in the evolution of typhoon-related storm rainfall events in Guangdong province, China.?Journal of Hydroinformatics, jh**, doi: 10.2166/hydro.2016.241.(IF_2016=1.634)?(Article.pdf)
1)? Liu*,L., Y. Liu,?X. Wang, D. Yu, K. Liu, H. Huang and G. Hu. (2015). Developing an effective 2-D urban flood inundation model for city emergency management based on cellular automata.?Natural Hazards and Earth System Sciences, 15. 381-391, doi:10.5194/nhessd-2-6173-2014. (IF_2014=1.735)?(Article.pdf)
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(2) 水文遥感 (Hydrology)：降雨 Rainfall + 土壤湿度 Soil moisture + 水库Reservoir + 干旱Drought
12) Wang^#, D.S., X. Wang*, L. Liu*, D.G. Wang, and Z. Zeng. 2021. Urban signatures in the spatial clustering of precipitation extremes over mainland China. Journal of Hydrometeorology, doi: 10.1175/jhm-d-20-0063.1. (IF_2019=4.158)?(Article.pdf)
11)? Lin, Z., T.O. Chan, E. Ge, X. Wang, Y. Zhao, Y. Yang, G. Ning, Z. Zeng, M. Luo*. 2020. Effects of urban land expansion on decreasing atmospheric moisture in Guangdong, South China. Urban Climate, 32, 100626, https://doi.org/10.1016/j.uclim.2020.100626. ?(IF_2019=3.834)
10)? Wang^#, D.S., X. Wang*, L. Liu*, D.G. Wang, X. Liang, C. Pan and H. Huang. (2018). Comprehensive evaluation of TMPA 3B42V7, GPM IMERG and CMPA precipitation estimates in Guangdong Province, China. International Journal of Climatology, 2018, 1-18; DOI: 10.1002/joc.5839. (IF_2017=3.100)?(Article.pdf)
9)? Wang, D.S., D. Wang*,?L. Liu?and?X. Wang. (2018). Use of high-resolution precipitation observations in quantifying the effect of urban extent on precipitation characteristics for different climate conditions over the Pearl River Delta, China.?Atmospheric Science letters,?DOI: 10.1002/asl.820.?(IF_2017=1.198)?(Article.pdf)
8)? Wang*, X., M. Liu and L. Liu. (2014). Responses of MODIS spectral indices to typical drought events from 2000 to 2012 in Southwest China.?Journal of Remote Sensing,18(2), 433-442.?(Article.pdf)
7)? Wang*, X., C. de Linage and H. Xie. (2013). How much water is seeping off the Three Gorges Reservoir??SPIE Newsroom, 10.1117/2.**.004952.?(Article.pdf)
6) ?Wang* X., Y. Chen, L. Song, X. Chen, H. Xie and L. Liu. (2013). Analysis of lengths, water areas and volumes of the Three Gorges Reservoir at different water levels using Landsat images and SRTM DEM data.?Quaternary International,304，115-125.(IF_2014=2.062)??(Article.pdf)
5) ?Wang*, X.,H. Xie, N. Mazari, H. Sharif and J. Zeitler. (2013). Evaluation of the near-real time NEXRAD DSP Product in the evolution of heavy rain events on the Upper Guadalupe River Basin, Texas.?Journal of Hydroinformatics, 15.2,doi: 10.2166/hydro.2012.016. (IF_2014=1.388)?(Article.pdf)
4) ?Wang*, X., C.R., Linage, J. Famiglietti and C. S. Zender. (2011). Gravity Recovery and Climate Experiment detection of water storage changes in the Three Gorges Reservoir of China and comparison with in situ measurements.?Water Resources Research, 47, 1-13, doi:10.1029/2011WR010534.（IF_2016=4.397)?(Article.pdf)
3)? Schnur*, M. T. S., ?H. Xie and?X. Wang. (2010). Estimating Root Zone Soil Moisture at Distant Sites Using MODIS NDVI and EVI in a Semi-Arid Region of Southwestern USA.?Ecological Informatics,?5, 400-409, doi:10.1016/j.ecoinf.2010.05.001. (IF_2014= 1.727)?(Article.pdf)
2)? Wang, X.,?H. Xie*, H. Sharif, & J. Zeitler. (2008). Validating NEXRAD MPE and Stage III precipitation products for uniform rainfall on the Upper Guadalupe River Basin of the Texas Hill Country.?Journal of Hydrology, 348,73-86.(IF_2014=3.053)?(Article.pdf)
1) ?Wang, X., H. Xie*,H. Guan, & X. Zhou. (2007). Different responses of MODIS-derived NDVI to root-zone soil moisture in semi-arid and humid regions.?Journal of Hydrology, 340, 12-24. (IF_2014=3.053)?(Article.pdf)
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(3) 冰雪遥感 (Cryosphere)：积雪 Snow + 冰川 Glacier + 海冰 Sea ice
15)?Wang*, X., W. Jiang#, H. Xie, S. Ackley and H. Li. (2020). Decadal Variations of Sea Ice Thickness in the Amundsen‐Bellingshausen and Weddell Seas Retrieved From ICESat and IceBridge Laser Altimetry, 2003–2017. Journal of Geophysical Research-Oceans, jgrc24042, doi: 10.1029/2020JC016077. (IF_2019=3.559)?(Article.pdf)
14) Tian, L., Xie*, H., Ackley, S., Tang, J., Mestas-Nu?ez, A., & Wang, X. 2020. Sea-ice freeboard and thickness in the Ross Sea from airborne (IceBridge 2013) and satellite (ICESat 2003–2008) observations. Annals of Glaciology, 1-16. doi:10.1017/aog.2019.49.(IF_2019=3.131)??(Article.pdf)
13)???Wang*, X.,?H. Chen and Y. Chen. (2018). Topography-Related Glacier Area Changes in Central Tianshan from 1989 to 2015 Derived from Landsat Images and ASTER GDEM Data.?Water, 10, 555; doi:10.3390/w**.?(IF_2017=2.069)?(Article.pdf)
12)? Wang*, X., H. Chen and Y. Chen. (2017). Large differences between glaciers 3D surface extents and 2D planar areas in Central Tianshan.?Water, 9(4), 282; doi:10.3390/w**. (2017=2.069)?(Article.pdf)
11)??Wang*, X., Y. Zhu, Y. Chen, H. Liu, H. Huang, K. Liu, and Lin Liu. (2017). Influences of forest on MODIS snow cover mapping and snow variations in the Amur River basin in Northeast Asia during 2000–2014.?Hydrological Processes,?DOI: 10.1002/hyp.11249. (IF_2017=3.182)?(Article.pdf)
10)? Wang*, X., F. Guan, J. Liu, H. Xie, and S. Ackley. (2016). An improved approach of total freeboard retrieval with IceBridge Airborne Topographic Mapper (ATM) elevation and Digital Mapping System (DMS) images.?Remote Sensing of Environment,184, 582-594.doi:10.1016/j.rse.2016.08.002.(IF_2016=6.265)?(Article.pdf)
9)? Wang*, X., H. Zheng, Y. Chen, H. Liu, L. Liu, H. Huang and K. Liu. (2014). Mapping snow cover variations using a MODIS daily cloud-free snow cover product in Northeast China.?Journal of Applied Remote Sensing, 8(1), 084681. doi:10.1117/1.JRS.8.084681.(IF_2016=1.107)?(Article.pdf)
8)? Wang*, X., H. Xie, Y. Ke, S. Ackley and L. Liu. (2013). A method to automatically determine sea level for referencing snow freeboard and computing sea ice thickness from NASA IceBridge airborne LIDAR.?Remote Sensing of Environment, 131, 160-172.(IF_2014=6.393)?(Article.pdf)
7)? Yu, H., X. Zhang, T. Liang*, H. Xie,?X. Wang,?Q. Feng and Q. Chen. (2012). A new approach of dynamic monitoring of 5-day snow cover extent and snow depth based on MODIS and AMSR-E data from Northern Xinjiang region.?Hydrological Processes, 26，3052-3061.(IF_2016=3.014)?(Article.pdf)
6)? Wang*, X. and C.S. Zender. (2011). Arctic and Antarctic diurnal and seasonal variations of snow albedo from multiyear Baseline Surface Radiation Network measurements.?Journal of Geophysical Research,116，F03008，doi:10.1029/2010JF001864. (IF_2014=3. 426)?(Article.pdf)
5)? Wang*, X. and C. Zender. (2010). Constraining MODIS snow albedo bias at large solar zenith angles: implications for surface energy budget in Greenland.?Journal of Geophysical Research,?115, F04015, doi:10.1029/2009JF001436.(IF_2014=3. 426)?(Article.pdf)
4)? Wang*, X.?and C. Zender. (2010). MODIS snow albedo bias at high solar zenith angles relative to theory and to in situ observations in Greenland.?Remote Sensing of Environment,?114, 563-575.(IF_2014=6.393)?(Article.pdf)
3)? Wang*, X.& H. Xie. (2009). New methods for studying the spatiotemporal variation of snow cover based on combination products of MODIS Terra and Aqua.?Journal of Hydrology,?371, 192-200. (IF_2014=3.053)?(Article.pdf)
5) Wang, X., H. Xie*, T. Liang & X. Huang. (2009). Comparison and validation of MODIS standard and new combination of Terra and Aqua snow cover products in Northern Xinjiang, China.?Hydrological Processes, 23, 419-429. (IF_2014=2.677)?(Article.pdf)
2) ?Xie*, H.,?X. Wang?& T. Liang. (2009). Development and assessment of combined Terra and Aqua MODIS snow cover products in Colorado Plateau, USA and northern Xinjiang, China.?Journal of Applied Remote Sensing,?Vol.3, 033559, 1-14.(IF_2014=1.183)?(Article.pdf)
1)? Wang, X., H. Xie*, & T. Liang. (2008). Evaluation of MODIS snow cover and its application in the Northern Xinjiang, China.?Remote Sensing of Environment,?112, 1497–1513. (IF_2014=6.393)?(Article.pdf)
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(4) 其它方向 Others
4)? Liang, J., X. Liu, K. Huang, X. Li, D. Wang and?X. Wang. (2013). Automatic Registration of Multi-Sensor Images Using an Integrated Spatial and Mutual Information (SMI) Metric.?IEEE Transactions on Geoscience and Remote Sensing, doi: 10.1109/TGRS.2013.**.(IF_2014=3.514)
3)? Du, Y., X.?Wang, X.?Yang, W. Ma, H. Ai and ?X. Wu. (2013). Impacts of climate change on human health and adaptation strategies in South China.?Advances in Climate Change Research,4(4), 208-214.
2)? Du, Y., X. Cheng,?X. Wang,?H. Ai, H. Duan and X. Wu. (2013). A review of assessment and adaptation strategy to climate change impacts on the coastal areas in South China.?Advances in Climate Change Research,4(4), 201-207.
1)? Du, Y., H. Ai, H. Duan, Y. Hu,?X. Wang, J. He, H. Wu and X. WU. (2013). Changes in climate factors and extreme climate events in South China during 1961-2010.?Advances in Climate Change Research,4(1), 1-11.
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中文期刊论文
6) 张麟, 黄华兵, 王先伟, 柳林, 黄容, 郭明月. (2018). 城市内涝模型参数灵敏度分析方法比较[J]. 中国给水排水, 34(3), 129-134.
5) 刘勇, 柳林,?王先伟, 刘凯, 黄华兵, 张韶月. (2015). 建筑物在减轻城市洪涝灾害中的作用分析[J].?自然灾害学报, 24(5): 68-74.
4) 刘勇, 张韶月, 柳林,?王先伟, 黄华兵. (2015). 智慧城市视角下城市洪涝模拟研究综述[J].?地理科学进展, 34(4): 494-504.
3)?王先伟*,?刘梅, 柳林. (2014). MODIS光谱指数在中国西南干旱监测中的应用[J]，遥感学报，2014, 18(2), 443-453.
2)?王先伟, ?温伟英*, 刘翠梅. (2003). 珠江口及附近海域夏季氮的化学形式分布研究[J].?海洋科学. 27(4): 49-53.
1) 何雪琴*, 何清溪,?王先伟. (2001). 燃煤电厂烟气脱硫工艺研究进展[J].?广州环境科学, 16(1): 5-8.
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专著
5) ?Wang*, X. (2019). Flooding Hazards and Risk Analysis in the Pearl River Delta, China. Book Chapter in Challenges towards Ecological Sustainability in China: An Interdisciplinary Perspective. Edited by Xiaojun Yang and Shijun Jiang. Publisher: Springer Nature Switzerland, ISBN 978-3-030-03483-2/9. DOI https://doi.org/10.1007/978-3-030-03484-9.
4) Xie, H. and X. Wang (Editors). (2018). Applications of Remote Sensing/GIS in Water Resources and Flooding Risk?Managements. Multidisciplinary Digital Publishing Institute (MDPI), 2018.
3)? 王先伟, 王喜娜. (2018). 风暴潮灾害风险评估技术.《气象灾害风险评估技术指南》第13章.　姜彤，王艳君，翟建青主编。气象出版社，2018.8，北京，ISBN: 978-7-5029-6820-5。
2) Xie*, H., T. Liang,?X. Wang?and G. Zhang. (2015). Remote sensing mapping and modeling of snow cover parameters and applications. Chapter 6: Remote Sensing Handbook Volume III: Water Resources, Disasters and Urban-Monitoring, Modeling and Mapping, Editor-in-Chief: Dr. Prasad S. Thenkabail. Publisher:?CRC Press.?Nov 17, 2015. ISBN-10: ; ISBN-13: 15.
1) Wang*,X.,?H. Xie and T. Liang. (2014). Spatiotemporal variation of snow cover from space in Northern Xinjiang. Book Chapter 6: Water Resources Research in Northwest China, Editor: Yaning Chen. Publisher:?Springer, DOI:10.1007/978-94-017-8017-9_6.
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专利
3）王先伟,汪家意,方勇军,郭昱,余琪.2020. 一种水流示踪实时监测系统与测速方法. 专利申请号：CN3.0 ，申请日期：2020年5月20日；公开公告日：2020年9月22日（实质审查阶段）
2）陈定安,陈明薇,罗明,王先伟. 2020. 一种基于LiDAR点云的电塔受灾风险评估方法及系统. 专利申请号：CN 9.8 ，申请日期：2020年6月20日；公开公告日：2020年10月12日（实质审查阶段）
1）黄华兵,王先伟.2020. 一种城市内涝风险快速评估方法及系统. 专利申请号：CN9.8 ，申请日期：2020年3月9日；公开公告日：2020年8月7日（实质审查阶段）.
软件著作权
8）黄华兵,王先伟.2019. 城市内涝地形控制作用分析软件V1.0,登记号：2019SR**，登记日期：2019/11/12.
7) 王先伟，何玮杰,王凌志.2019. Floodzone洪灾制图软件V1.0. 登记号：2019SR**, 登记日期：2019/4/25.
6) 王先伟，王凌志，何玮杰. 2019. 堤围几何属性自动提取与防洪性能评估软件V1.0. 登记号：2019SR**, 登记日期：2019/4/4.
5) 王先伟，管芳，高金顶，蒋为旭. 2017. 基于机载激光高程和影像的海表面高程及海冰厚度计算与分析软件 V1.10, 登记号：2017SR186878,2017/5/18.
4）王先伟，王喜娜，钟焕珍，黄华兵. 2017. 缺潮位数据地区风暴潮设计潮位计算软件V1.0，登记号：2017SR255714,登记日期：2017/6/12.
3）王先伟，王喜娜，钟焕珍，黄华兵. 2017. 风暴潮灾害风险评估系统V1.0，登记号：2017SR255711, 登记日期：2017/6/12.
2) 黄华兵，王先伟，柳林，李秋萍. 2017. 城市内涝应急响应示范系统V1.0. 登记号：2017SR630298, 登记日期：2017/11/16.
1）黄华兵，刘勇，王先伟. ?2015. 城市内涝精细化模拟平台软件V1.0，登记号：2015SR055449,2015/3/27.
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社会任职Editorial Board of Hydrosphere for Frontiers in Earth Science and Frontiers in Built Environment
Topic editor for Water
Guest editor of Water for a special issue: Applications of Remote Sensing/GIS in Water Resources and Flooding Risk Managements.
期刊审稿人：?Remote Sensing of Environment, Journal of Geophysical Research, Cold Regions Science and Technology, Water Resource Research, Journal of Hydrology,? Hydrological Processes, Journal of Hydroinformatics, Quaternary International, Journal of Applied Remote Sensing, Advances in Polar Research, 《遥感学报》、《水利水电技术》、《冰川冻土》、《极地科学》等.
行业协会会员：?中国地理学会、遥感学会、水利学会会员； 全球华人地理信息科学协会(CPGIS)， 美国地球物理协会 (AGU)， 美国地理学会 (AAG)，国际冰川协会（IGS）， 国际水文协会（IAHS）等.