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吴磊

发布日期:2020-11-27   阅读次数:

基本信息

吴磊,男,河南开封人,中共党员,博士,教授,博士生导师。长期从事流域水土环境过程与生态调控的教学与科研工作。入选陕西省青年科技新星,仲英青年学者。

教育经历

2010.9.15-2011.9.15美国加州大学欧文分校(UC Irvine)市政与环境工程系(水文水环境方向) 国家公派中美联合培养博士研究生

2012.6.27获重庆大学城市环境与生态工程博士学位(水文水环境方向)

2008.12.25获重庆大学市政工程硕士学位(水文水环境方向)

2006.7.1获给水排水工程学士学位(小城镇污水处理方向)

工作与访学经历

2020.1-今 西北农林科技大学水利与建筑工程学院 教授

2019.5-10 美国德州农工大学Blackland Research & Extension Center “海外提升计划”访问学者

2017.8.30-2018.8.30 美国加州大学伯克利分校(UC Berkeley)市政与环境工程系 国家公派访问学者

2015.1-2019.12 西北农林科技大学水利与建筑工程学院 副教授

2012.7-2014.12 西北农林科技大学水利与建筑工程学院 讲师

其他职务

四川省生态文明促进会第一届专家委员会青年专家,教育部科技发展中心评审专家,江苏省科技副总,东清合创(深圳)环境科技有限公司专家顾问,国家自然科学基金青年、面上、地区、海外通讯评审专家,陕西、江西、黑龙江、安徽、科研院所等科研立项与科技奖励评审专家,中国水资源战略研究会会员,中国水土保持学会会员,担任Science of the Total Environment, Land Degradation & Development, Environmental Science & Technology, Water Research, Journal of Environmental Informatics, Scientific Reports, Environmental Modelling & Software,Journal of Environmental Quality, Separation & Purification Reviews, Environmental Science and Pollution Research, Environmental Earth Sciences, Journal of Mountain Science, Environmental Management, SCIENCE CHINA Earth Sciences, International Soil and Water Conservation Research等30余个国内外期刊审稿人。

主要荣誉与获奖

2022年 Best Researcher Award (2022) for the contribution and honourable achievement in innovative research. International Research Award on New Science Inventions; NESIN 2022; Ministry of Corporate Affairs (MCA), Govt. of India.

2020年 水土流失型面源污染控制关键技术与应用,获中国水土保持学会科学技术奖二等奖(中国水土保持学会,排名第3)。

2018年 西北地区“村落—城镇—小流域”农村生活污水时空源区识别与“生物—生态”净化技术模式,获2018第三届中国创新挑战赛优秀奖(延安市科学技术局,延安市高新区管委会,共青团延安市委,排名第1)。

2016年 5月入选陕西省创新人才推进计划—陕西省青年科技新星(陕西省科技厅)。

2016年12月入选西北农林科技大学第一批“仲英青年学者”(唐仲英基金会)。

2019年 指导本科生获“华维杯”第一届全国大学生农业水利工程及相关专业创新设计大赛三等奖(项目名称“一种新型屋顶雨水收集与绿地定时灌溉系统”)。

2019年 指导本科生发明项目“零耗能空气取水器”获水利与建筑工程学院第五届水利创新设计大赛二等奖。

2016年 校优秀党员(中共西北农林科技大学委员会)。

2016年 院优秀党员(中共西北农林科技大学水利与建筑工程学院委员会)。

2014年 获水利与建筑工程学院 “宣传先进个人”荣誉称号。

主讲课程

本科生:先后主讲《水环境保护》、《水环境保护课程设计》、《水力学》、《生态学》、《水处理工程》、《水利工程概论》、《水环境监测与评价》等6门课程。

研究生:先后主讲《水环境理论与方法》、《分布式水文模型》、《环境水力学》、《非点源污染模拟》、《农业工程专论》等5门课程。

研究方向

以“高侵蚀丘陵区农业非点源污染理论与控制技术”为中心,围绕“流域水、沙、污染物耦合输移全过程模拟与生态调控”开展“分布式水文模拟,侵蚀产沙、污染物迁移转化动力学、情景模拟、BMPs时空配置优化、反演模拟,不确定性分析、时空尺度转换,多尺度效应,土壤物理化学微生物,水沙传质数值模拟、低影响开发(LID)、水质目标管理”等前沿基础科学和应用基础科学研究。

科研项目

先后主持国家自然科学基金面上项目2项、青年项目1项,教育部博士学科点基金1项,陕西省科技新星支持项目1项,仲英青年学者项目1项,国家重点实验室开放基金1项,国家重点研发计划子课题任务1项,校级国际科技合作项目1项。参加国家自然科学基金面上项目1项,曾参研国家水专项、国家科技支撑计划、中科院西部行动计划等项目。

主要代表性项目:

[1] 国家自然科学基金面上项目,考虑上下游水力联系的最佳管理措施多目标协同配置—以泾河流域为例, 2021/01-2024/12,主持

[2] 国家自然科学基金面上项目,黄土丘陵沟壑区水-沙-吸附态与溶解态非点源污染物多时空尺度耦合运移机理研究, 2017/01-2020/12,主持

[3] 国家自然科学基金青年项目,黄土高原小流域吸附态非点源污染过程模拟与调控研究,2014/01-2016/12,主持

[4] 教育部博士学科点专项基金,黄土高原小流域非点源氮磷流失形态模拟研究, 2014/01-2016/12,主持

[5] 陕西省创新人才推进计划—青年科技新星项目,延河流域非点源污染控制措施空间配置优化研究,2017/08-2019/12,主持

[6] 黄土高原土壤侵蚀与旱地农业国家重点实验室开放基金,黄土高原小流域吸附态氮磷非点源污染分布式模型研究, 2014/01-2016/07,主持

[7] 国家重点研发计划子课题任务,水资源协同配置方案效益可行性分析,2016/07-2019/12,主持

主要论著

先后在《Journal of Hydrology》、《Agricultural, Ecosystems & Environment》、《Journal of Cleaner Production》、《Catena》、《Agricultural Water Management》、《Science of the Total Environment》、《Ecological Indicators》、《Ecological Engineering》、《Scientific Reports》、《Environmental Science and Pollution Research》、《Solid Earth》、《Environmental Earth Sciences》、《Environmental Monitoring and Assessment》、《Water Policy》、《Water Environmental Research》、《Environmental Engineering Science》、《Water Science and Technology》、《Ecological Modelling》、《农业工程学报》、《中国环境科学》、《环境科学研究》、《农业环境科学学报》、《应用力学学报》、《中国科技论文》等本领域国内外重要期刊发表论文83篇,其中SCI论文50余篇(第一作者47篇)。据Google Scholar查询,以第一作者发表的SCI论文共被引用1100余次,h-index 18, i10-index 28;以第一作者发表在Journal of Hydrology论文被引110余次,为ESI(Essential Science Indicators)前3%高被引论文。另外,以第一作者授权发明专利1件,实用新型5件。

主持校、院级本科教育教改项目3项,校级研究生教育教改项目1项,院级研究生“课程思政”示范课程1项。在黑龙江教育(高教研究与评估)、高教学刊等以第一作者发表了《以高素质工程人才培养为目标的“水力学”教学新模式研究》、《本科生培养质量提升策略——基于毕业生跟踪反馈与社会评价机制》、《研究生人才培养质量提升策略——基于新型导学关系构建机制》、《“互联网+”大数据背景下新工科环境生态类课程教学与复合型创新人才培养模式》等主题的教育教改论文8篇。

主要代表性论文:

[1] Wu, L., Liu, X., Yang, Z., Yu, Y., Ma, X.Y. (2022). Effects of single- and multi-site calibration strategies on hydrological model performance and parameter sensitivity of large-scale semi-arid and semi-humid watersheds. Hydrological Processes, 36(6), e14616.

[2] Wu, L., Liu, X., Chen, J.L., Li, J.F., Yu, Y., Ma, X.Y. 2022. Efficiency assessment of best management practices in sediment reduction by investigating cost-effective tradeoffs. Agricultural Water Management 265: 107546.

[3] Wu, L., Liu, X., Chen, J.L., Yu, Y., Ma, X.Y. (2022). Overcoming equifinality: timevarying analysis of sensitivity and identifiability of SWAT runoff and sediment parameters in an arid and semiarid watershed. Environmental Science and Pollution Research 29(21): 31631-31645. DOI:10.1007/s11356-022-18573-9

[4] Wu, L., Liu, X., Yu, Y., Ma, X.Y. (2022). Biochar, grass, and cross-ridge reshaped the surface runoff nitrogen under consecutive rainstorms in loessial sloping lands. Agricultural Water Management 261: 107354.

[5] Wu, L., Liu, X., Yang, H., Ma, X.Y. (2021). How agricultural management practices affect nitrogen transportation and redistribution under the drying-rewetting process of loessial sloping lands? Agriculture, Ecosystems and Environment, 315: 107440. (SCI)

[6] Wu, L., Liu, X., Ma, X.Y. (2021). How biochar, horizontal ridge, and grass affect runoff phosphorus fractions and possible tradeoffs under consecutive rainstorms in loessial sloping land? Agricultural Water Management 256(3): 107121. (SCI)

[7] Wu, L., Liu, X., Yang, Z., Chen, J.L., Ma, X.Y. (2021). Landscape scaling of different land-use types, geomorphological styles, vegetation regionalizations and geographical zonings differs spatial erosion patterns in a large-scale ecological restoration watershed. Environmental Science and Pollution Research, 28(28): 38374-38392. doi: 10.1007/s11356-021-13274-1. (SCI)

[8] Wu, L., Yen, H., Ma, X.Y. (2021). Effects of particulate fractions on critical slope and critical rainfall intensity for runoff phosphorus from bare loessial soil. Catena 196, 104935. (SCI)

[9] Wu, L., Yen, H., Arnold, J.G., Ma, X.Y. (2020). Is the correlation between hydro-environmental variables consistent with their own time variability degrees in a large-scale loessial watershed? Science of the Total Environment 722, 137737. (SCI)

[10] Wu, L., He, Y., Ma, X.Y. (2020). Using five long time series hydrometeorological data to calibrate a dynamic sediment delivery ratio algorithm for multi-scale sediment yield predictions. Environmental Science and Pollution Research, 27:16377–16392. (SCI)

[11] Wu, L., He, Y., Ma, X.Y. (2020). Can soil conservation practices reshape the relationship between sediment yield and slope gradient? Ecological Engineering, 142, 105630. (SCI)

[12] Wu, L., Li, X.P., Ma, X.Y. (2019) Particulate nutrient loss from drylands to grasslands/forestlands in a large-scale highly erodible watershed. Ecological Indicators 107, 105673. (SCI)

[13] Wu, L., Li G.X., Jiang, J., Ma, X.Y. (2019).Using vegetation correction coefficient to modify a dynamic particulate nutrient loss model for monthly nitrogen and phosphorus load predictions: a case study in a small loess hilly watershed. Environmental Science and Pollution Research, 26: 32610-32623. (SCI)

[14] Wu, L., Yao, W.W., Ma, X.Y. (2018). Using the comprehensive governance degree to calibrate a piecewise sediment delivery ratio algorithm for dynamic sediment predictions: A case study in an ecological restoration watershed of northwest China. Journal of Hydrology, 564, 888-899. (SCI)

[15] Wu, L., Su, X.L., Ma, X.Y., Kang, Y., Jiang, Y.N. (2018). Integrated modeling framework for evaluating and predicting the water resources carrying capacity in a continental river basin of Northwest China. Journal of Cleaner Production, 204, 366-379. (SCI)

[16] Wu, L., Qiao, S.S., Peng, M.L., Ma, X.Y. (2018). Assessing impacts of rainfall intensity and slope on dissolved and adsorbed nitrogen loss under bare loessial soil by simulated rainfalls. Catena, 170, 51-63. (SCI)

[17] Wu, L., Jiang, J., Li G.X., Ma, X.Y. (2018). Characteristics of pulsed runoff-erosion events under typical rainstorms in a small watershed on the Loess Plateau of China. Scientific Reports, 8:3672. (SCI)

[18] Wu, L., Qiao, S.S., Peng, L.L., Ma, X.Y. (2018). Coupling loss characteristics of runoff-sediment-adsorbed and dissolved nitrogen and phosphorus on bare loess slope. Environmental Science and Pollution Research, 25(14), 14018-14031. (SCI)

[19] Wu, L., Liu, X., Ma, X.Y. (2018). Prediction of land use change and its driving forces in an ecological restoration watershed of the loess hilly region. Environmental Earth Sciences, 77:238. (SCI)

[20] Wu, L., Tang, X.D., Ma, X.Y. (2018). Optimal allocation of nonpoint source pollution control measures using two modern comprehensive evaluation methods. Water Policy, 20: 811-825. (SCI)

[21] Wu, L., Peng M.L., Qiao S.S., Ma X.Y. (2018). Effects of rainfall intensity and slope gradient on runoff and sediment yield characteristics of bare loess soil. Environmental Science and Pollution Research, 25(4): 3480-3487. (SCI)

[22] Wu L., Liu, X., Ma, X.Y. (2018). Spatio-temporal temperature variations in the Chinese Yellow River basin from 1981 to 2013. Weather, 73(1): 27-33. (SCI)

[23] Wu, L., Chang, H.Y., Ma, X.Y. (2017). A modified method for pesticide transport and fate in subsurface environment of a winter wheat field of Yangling, China. Science of the Total Environment, 609: 385–395. (SCI)

[24] Wu, L., Qi, T., Zhang, J. (2017). Spatiotemporal variations of adsorbed nonpoint source nitrogen pollution in a highly erodible Loess plateau watershed. Polish Journal of Environmental Studies, 26(3): 1343-1352. (SCI)

[25] Wu, L., Liu, X., Ma, X.Y. (2016). Application of a modified distributed-dynamic erosion and sediment yield model in a typical watershed of a hilly and gully region, Chinese Loess Plateau. Solid Earth, 7(6): 1577-1590. (SCI)

[26] Wu, L., Liu, X., Ma, X.Y. (2016). Spatio-temporal variation of erosion-type non-point source pollution in a small watershed of hilly and gully region, Chinese Loess Plateau. Environmental Science and Pollution Research, 23: 10957-10967. (SCI)

[27] Wu, L., Liu, X., Ma, X.Y. (2016). Spatio-temporal evolutions of precipitation in the Yellow River basin of China from 1981 to 2013. Water Science & Technology: Water Supply, 16(5): 1441-1450. (SCI)

[28] Wu, L., Liu, X., Ma, X.Y. (2016). Spatiotemporal distribution of rainfall erosivity in the Yanhe River watershed of hilly and gully region, Chinese Loess Plateau. Environmental Earth Sciences, 75: 315. (SCI)

[29] Wu, L., Liu, X., Ma, X.Y. (2016). Pesticide exposure levels in an apple-orchard catchment of Changwu Tableland, Chinese Loess Plateau. Fresenius Environmental Bulletin, 25(12a): 5904-5917. (SCI)

[30] Wu, L., Liu, X., Ma, X.Y. (2016). Tracking Soil Erosion Changes in an Easily-Eroded Watershed of the Chinese Loess Plateau. Polish Journal of Environmental Studies, 25(1): 332-344. (SCI)

[31] Wu, L., Li, P.C., Ma, X.Y. (2016). Estimating nonpoint source pollution load using four modified export coefficient models in a large easily eroded watershed of the loess hilly-gully region, China. Environmental Earth Sciences, 75: 1056. (SCI)

[32] Wu, L., Gao, J.E., Ma, X.Y., Li, D. (2015) Application of modified export coefficient method on the load estimation of non-point source nitrogen and phosphorus pollution of soil and water loss in semiarid regions. Environmental Science and Pollution Research, 22: 10647-10660. (SCI)

[33] Wu, L., Chang, H.Y., Ma, X.Y. (2015). Insecticide transport and fate in a small apple-orchard watershed of the hilly and gully region, Loess Plateau. Fresenius Environmental Bulletin, 24(8a): 2603-2614. (SCI)

[34] Wu, L., Qi, T., Li, D., Yang, H.J., Liu, G.Q., Ma, X.Y., Gao, J.E. (2015). Current status, problems and control strategies of water resources pollution in China. Water Policy, 17(3): 423-440. (SCI)

[35] Wu, L., Wang, J., Liu, X. (2015). Enhanced nitrogen removal under low-temperature and high-load conditions by optimization of the operating modes and control parameters in the CAST system for municipal wastewater. Desalination and Water Treatment, 53: 1683-1698. (SCI)

[36] Wu, L., Ma, X.Y., Liu, X. (2014) Assessment of herbicide transport and distribution in subsurface environments of an orange field. Water Environment Research, 86(8): 729-740. (SCI)

[37] Wu, L., Long, T.Y., Liu, X., Ma, X.Y. (2013). Modeling impacts of sediment delivery ratio and land management on adsorbed non-point source nitrogen and phosphorus load in a mountainous basin of the Three Gorges reservoir area, China. Environmental Earth Sciences, 70(3):1405-1422. (SCI)

[38] Wu, L., Long, T.Y., Liu, X., Guo, J.S. (2012). Impacts of climate and land-use changes on the migration of non-point source nitrogen and phosphorus during rainfall-runoff in the Jialing River Watershed, China. Journal of Hydrology, 475: 26-41. (SCI)

[39] Wu, L., Long, T.Y., Cooper, W.J. (2012). Simulation of temporal and spatial distribution on dissolved non-point source nitrogen and phosphorus load in Jialing River Watershed, China. Environmental Earth Sciences, 65(6): 1795-1806. (SCI)

[40] Wu, L., Long, T.Y., Liu, X., Mmereki, D. (2012). Simulation of soil loss processes based on rainfall runoff, and the time factor of governance in the Jialing River Watershed, China. Environmental Monitoring and Assessment, 184(6): 3731-3748. (SCI)

[41] Wu, L., Long, T.Y., Cooper, W.J. (2012). Temporal and spatial simulation of adsorbed nitrogen and phosphorus non-point source pollution load in Xiao Jiang Watershed of Three Gorges Reservoir Area, China. Environmental Engineering Science, 29(4): 238-247. (SCI)

[42] Wu, L., Long, T.Y., Lu, X.P. (2012).Improvement of separation efficiency and production capacity of a hydrocyclone. Water Science and Technology: Water Supply, 12(3): 281-299. (SCI)

[43] Wu, L., Long, T.Y., Li, C.M. (2010). The simulation research of dissolved nitrogen and phosphorus non-point source pollution in Xiao-Jiang Watershed of Three Gorges Reservoir Area. Water Science and Technology, 61(6): 1601-1616. (SCI)

[44] Wu, L., Liu, X., Ma, X.Y. (2018). Research progress on the watershed sediment delivery ratio. International Journal of Environmental Studies, 75: 4, 565-579. (EI)

[45] Wu, L., Ma, X.Y., Peng, H.L., Wang, J., Wen, J.X. (2013). Herbicide distribution and transport in subsurface environment of a tomato field in the Three Gorges Reservoir area, China. International Journal of Environmental Studies, 70(4): 637-654. (EI)

研究生招生

团队建有水质监测与水土环境模拟实验室。实验室拥有美析—紫外可见光分光光度计UV-1700PC、气浴恒温振荡器THZ-92C、高速万能粉碎机LD-Y500A、电热恒温培养箱HH•B11•420-BS-II、TDZ5-WS多管架自动平衡离心机、普通实验冰箱BCD-221WDPT、LDZX-50KBS立式压力蒸汽灭菌器、DRB200数字式消解器、SHZ-D(III)循环水式抽滤真空泵、电子分析天平FA1004B(0.00001g、0.001g、0.1g)、多级别725080mLINE可调移液器(1-5000μl)、TOMOS移液器EPP(10-200μl)、TOMOS枪架、pH计、洁净台、中高端工作站、计算机等仪器设备。

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联系方式

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