1998-2022 ChinaKaoyan.com Network Studio. All Rights Reserved. 沪ICP备12018245号
分类:导师信息 来源:同济大学土木工程学院 2020-04-24 相关院校:同济大学
同济大学土木工程学院水利工程系研究生导师代朝猛介绍如下:
代朝猛,博士、副教授、博士生导师
基本情况
姓名:代朝猛
出生年月:1980年05月
籍贯:河南开封
学历:工学博士
职称: 副教授、博导
单位:同济大学水利工程系
职务:副系主任(主持工作)
电子信箱:daichaomeng@tongji.edu.cn
电话:86-21-65982531
研究方向
主要从事海陆交互带及浅海带地下水污染物迁移扩散规律及模拟、地下水污染修复技术及新型环境功能材料在地下水污染修复中的应用、海绵城市雨水蓄渗过程中地下水的响应耦合机制研究。
教育经历
2007/09 – 2011/01,同济大学,环境科学与工程学院,博士
2008/09 – 2010/10,德国柏林工业大学(Technical University of Berlin),环境过程工程系,联合培养博士
2004/09 – 2007/06,郑州大学,水利与环境学院,硕士
2000/09 – 2004/06,河南工业大学,化学化工学院,学士
工作经历
2016年7月-8月在澳大利亚墨尔本大学做访问学者。
2014年6月-7月在新西兰奥克兰大学做访问学者。
2011年1月-至今在同济大学土木工程学院水利工程系做师资博士后、讲师、副教授。
学术兼职
Jacobs Journal of Hydrology编委(USA)
中国水利学会第六届青年科技工作委员会委员
中国大坝工程学会数值模拟专业委员会委员
上海市水利学会专业委员会委员
国际期刊Journalof Chemistry(SCI收录)特刊编辑
国家自然科学基金委自然科学基金项目通讯评审专家
新西兰奥克兰大学博士学位毕业论文海外评审专家库成员
科技部十二五科技规划纲要城镇化与城市发展领域专题评估组成员
主持科研项目
[1]国家自然科学基金面上项目,项目批准号:41471392。
[2]国家自然科学基金青年项目,项目批准号:41101480。
[3]上海市“科技创新行动计划”“一带一路”项目,项目批准号:19230742400。
[4]上海市“科技创新行动计划”自然科学基金项目,项目批准号:19ZR1459300。
[5]上海市高峰学科交叉项目,项目批准号:0200121005/053。
[6]高峰学科建设国际一流科研合作项目,项目批准号:2019010202。
[7]科技部中新科学家交流计划项目,项目批准号:201406201407。
[8]科技部中澳青年科学家交流计划项目,项目批准号:201607201608。
[9]同济大学青年英才计划项目-优青计划,项目批准号:20161208。
[10]中央高校学科交叉类项目(滚动类),项目批准号:0200219234。
[11] 中央高校学科交叉类项目,项目批准号:20153772。
[12] 上海市教育委员会产学研项目,项目批准号:14cxy07。
[13] 中国博士后科学基金面上项目,项目批准号:20110490698。
主要论文
[1]X. You, S. Liu, C. Dai*, G. Zhong, Y. Duan, Y. Tu. Accelerationand centralization of a back-diffusion process: Effects of EDTA-2Na on cadmiummigration in high- and low-permeability systems. The Science of the total environment,DOI:10.1016/j.scitotenv.2019.135708.
[2]C. Dai, H. Shen, Y. Duan, S. Liu, F.Zhou, D. Wu, G. Zhong, A. Javadi, Y. Tu. TiO2 and SiO2 Nanoparticles Combinedwith Surfactants Mitigate the Toxicity of Cd2+ to Wheat Seedlings. Water Airand Soil Pollution, doi.org/10.1007/s11270-019-4297-4.
[3]Y. Wu, Y. Bo, F. Zhoua, Q. Tang, M. Guimberteau, P. Ciais, T.Yang, S. Peng, S. Piao, J. Zheng, Y. Dong, C. Dai. Quantifying theunauthorized lake water withdrawals and their impacts on the water budget ofeutrophic lake Dianchi, China. Journal of Hydrology 565 (2018) 39–48,2018
[4]B. Tan, S.Liu, C. Dai*, H. Zhou, Z. Hui, G. Zhong, H.Zhang. Modelling of colloidal particle and heavy metal transfer behavioursduring seawater intrusion and refreshing processes,HydrologicalProcesses,2017,31(22): 3920-3931.
[5]S. Liu, A. Tao, C. Dai* ; B. Tan, H. Shen, G. Zhong, S.Lou, S. Chalov, R. Chalov. Experimental Study of Tidal Effects on CoastalGroundwater and Pollutant Migration. Water Air and SoilPollution.2017,288(4):163.
[6]Y. He, C. Dai*, X. Zhou.Magnetic cobalt ferrite compositeas an efficient catalyst for photocatalytic oxidation of carbamazepine,EnvironmentalScience and Pollution Research, 2017, 24(2):2065–2074.
[7]W. Chen, Y. Su, Z. Wen, Y. Zhang, X. Zhou, C. Dai*.Recovery of indium ions by nanoscale zero-valent iron. JOURNAL OF NANOPARTICLERESEARCH.2017,19(3):97.
[8]X. Zhan, C. Chen, Q. Wang, F. Zhou, K. Hayashi, X. Ju, S. Lam, Y.Wang, Y. Wu, J. Fu, L. Zhang; S. Gao, X. Hou, Y. Bo; D. Zhang, K. Liu, Q. Wu, R.Su, J. Zhu, C. Yang, C. Dai, H. Liu. Improved Jayaweera-Mikkelsen modelto quantify ammonia volatilization from rice paddy fields in China,Environmental Science and Pollution Research, 2019, 26(8): 8136-8147.
[9]B. Shao, Y. Chen, D. Wu, C. Dai, Y. Zhang. Mineraltransformation of structural Fe(II) hydroxides with O-2, Cu(II), Cr (VI) andNO2- for enhanced arsenite sequestration. Chemical Engineering Jounal,2017,311:247-254.
[10]S.Lou, S. Liu, C. Dai, A. Tao, B. Tan, Gangfeng Ma,RomanSergeeyvichChalov, Sergey RomanovichChalov. Heavy Metal Distribution andGroundwaterQuality Assessment for a Coastal Areaon a Chinese Island,PolishJournal of Environmental Studies, 2017, 26(2): 733-745.
[11] Y.Zhang, Z. Yin, C. Dai*, X. Zhou, W. Chen. Interfacial thermodynamics andkinetics of sorption of diclofenac on prepared high performance flower-likeMoS2,JOURNALOF COLLOID AND INTERFACE SCIENCE, 2016, 481: 210-219.
[12] B.Shao, Y. Chen, D. Wu, H. He, C. Dai, Y. Zhang. Aqueous nickelsequestration and release during structural Fe(II) hydroxide remediation: theroles of coprecipitation, reduction and substitution.RSCADVANCES,2016,6(88):85347-85354.
[13] H.He, D. Wu, L. Zhao, C.Luo, C. Dai, Y.Zhang. Sequestration of chelated copperby structural Fe(II): Reductivedecomplexation and transformation ofCuII-EDTA.Journal of Hazardous Materials, 2016,309: 116–125
[14] Y.Zhang, W. Chen, C. Dai*, C Zhou, X Zhou. Structural Evolution ofNanoscale Zero-Valent Iron (nZVI) in Anoxic Co2+ Solution: InteractionalPerformance and Mechanism, Scientific reports, 5, 2015.
[15] Y.Zhang, J. Yan, C. Dai*, Y.Li,Y. Zhu, X. Zhou.Sequestration of Ag(I) fromaqueous solution as Ag(0) nanostructures by nanoscale zero valent iron (nZVI).Journal of nanoparticle research,2015,17(11),455.
[16] S.LIU, B. TAN, C. Dai*, S. LOU, A. TAO. Geochemical characterization andheavy metal migration in a coastal polluted aquifer incorporating tidaleffects: field investigation in Chongming Island, China. Environmental Scienceand Pollution Research, 2015, 22(24), 20101-20113.
[17] Y.Su, X. Sun, X. Zhou, C. Dai*, Y. Zhang. Zero-valent Iron Doped CarbonsReadily Developed from Sewage Sludge for Lead Removal from Aqueous Solution,Journal of Environmental Sciences,2015, 36:1-8.
[18] Z.Zhou,C. Dai*, X. Zhou,J. Zhao, Y. Zhang. The Removal ofAntimony by Novel NZVI-Zeolite: the Role of Iron Transformation. Water Air andSoil Pollution. 226(3):76-92, 2015.
[19] Z.Wen, C. Dai, Y. Zhu ,Y. Zhang. Arsenate removal from aqueous solutionsusing magnetic mesoporous iron manganese bimetal oxides. RSC Advances, 5(6):4058-4068, 2015.
[20]Z.Wen, Y. Zhang, C. Dai, Z. Sun. Nanocasted synthesis of magneticmesoporous iron cerium bimetal oxides (MMIC) as an efficient heterogeneousFenton-like catalyst for oxidation of arsenite. Journal of Hazardous Materials.287:225-233,2015.
[21] Y.Su, X. Zhou, C. Dai, M. Jiang, Y. Zhang. Phosphate removal mechanism inan airlift-loop reactor under limited filamentous bulking conditions,Desalination and Water Treatment, 1299-1308, 2015.
[22]Q.Zhang, J. Chen, C. Dai, Y. Zhang, X. Zhou. Degradation of carbamazepineand toxicity evaluation using the UV/persulfate process in aqueous solution.Journal of Chemical Technology and Biotechnology. 90: 701-708,2015.
[23]Y.Zhang, A. Mazumder, T. Zhang, C. Dai. The Application of AdvancedMaterials on the Water or Wastewater Treatment. Journal of Chemistry, 2015:1-2. 2015.
[24]Y.Su , A. Adeleye, A. A. Keller ,Y. Huang, C. Dai, X. Zhou , Y. Zhang.Magnetic sulfide-modified nanoscalezerovalent iron (S-nZVI) for dissolved metalion removal. Water research, 74: 47-57,2015.
[25]C.Dai, Z. Zhou, X. Zhou, Y. Zhang. Removal of Sb(III) and Sb(V) fromaqueous solutions using nZVI. Water Air and Soil Pollution. 225:1799, 2014.
[26]W.Liang, C. Dai*, X. Zhou, Y. Zhang. Application of zero-valent ironnanoparticles for the removal of aqueous zinc ions under various experimentalconditions. PLoS One, 9(1): e85686, 2014.
[27]Y.Zhang, Y. Liu, C. Dai*, X. Zhou. Adsorption of Clofibric Acid fromAqueous Solution by Graphene Oxide and the Effect of Environmental Factors.Water Air Soil Pollut, 225: 2064, 2014.
[28]Z.Wen, Y. Zhang, C. Dai*. Removal of Phosphate from Aqueous Solution UsingNanoscaleZerovalent Iron (nZVI). Colloids and Surfaces A: Physicochemical andEngineering Aspects, 457: 433–440, 2014.
[29]Y.Zhang, Z. Shen, C. Dai*, X. Zhou. Removal of selected pharmaceuticalsfrom aqueous solution using magnetic chitosan: sorption behavior and mechanism.Environmental Science and Pollution Research, 21(22):12780-9, 2014.
[30]Y.Zhang, S. Lin, C. Dai*, L. Shi, X. Zhou*. Sorption-desorption andtransport of trimethoprim and sulfonamide antibiotics in agricultural soil:effect of soil type, dissolved organic matter and pH. Environmental Science andPollution Research. 21(9): 5827-5835, 2014.
[31] Y.Zhang, Y. Li, C. Dai*, X. Zhou, W. Zhang. Sequestration of Cd(II) withnanoscale zero-valent iron (nZVI): Characterization and test in a two-stagesystem. Chemical Engineering Journal, 244: 218-226, 2014.
[32]Y.Zhang, K. Zhang, C. Dai*, X. Zhou. Performance and mechanism of pyritefor nitrobenzene removal in aqueous solution. Chemical Engineering Science,111:135-141, 2014.
[33]Y.Zhang, K. Zhang, C. Dai*, X. Zhou, H. Si. An enhanced Fenton reactioncatalyzed by natural heterogeneous pyrite for nitrobenzene degradation in anaqueous solution. Chemical Engineering Journal, 244: 438-445, 2014.
[34]Z.Wen, Y. Zhang, C. Dai, B. Chen, S. Guo, H. Yu, D. Wu. Synthesis ofOrdered Mesoporous Iron Manganese Bimetal Oxides for Arsenic Removal fromAqueous Solutions. Microporous and Mesoporous Materials, 200: 235–244, 2014.
[35]Y.Su, AS Adeleye, X. Zhou, C. Dai, W. Zhang, AA Keller, Y. Zhang Effectsof Nitrate on the Treatment of Lead Contaminated Groundwater byNanoscaleZerovalent Iron. J. Hazard. Matls., 280: 504-513, 2014.
[36]Y.Su, A. Adeleye, Y. Huang, Z. Sun, C. Dai, X. Zhou, Y. Zhang, A.A. Keller(2014). Simultaneous Removal of Cadmium and Nitrate in Aqueous Media byNanoscaleZerovalent Iron (nZVI) and Au Doped nZVI Particles, Water Research,63: 102-111, 2014.
[37]C.Dai, J. Zhang, Y. Zhang, X. Zhou, S. Liu. Application of MolecularlyImprinted Polymers to Selective Removal of Clofibric Acid from Water. PlosOne.8(10): 78167(1-8), 2013.
[38]C.Dai, J. Zhang, Y. Zhang, X Zhou, YanpingDuan, Shuguang Liu. Removalof carbamazepine and clofibric acid from water using doubletemplates–molecularly imprinted polymers. Environmental Science and PollutionResearch , 20:5492-5501, 2013.
[39]Y.Duan, C. Dai*, Y. Zhang, L. Chen. Selective trace enrichment of acidicpharmaceuticals in real water and sediment samples based on solid-phaseextraction using multi-templates molecularly imprinted polymers. AnalyticaChimicaActa,758: 93-100,2013.
[40]Y.Zhang, J. Zhang, C. Dai*, X. Zhou, S. Liu.Sorption of carbamazepine fromwater by magnetic molecularly imprinted polymers based on chitosan-Fe3O4.Carbohydrate Polymers, 97(2):809-816, 2013.
[41] Y.Zhang*, Y. Su, X. Zhou, C. Dai, A. K. Arturo. A new insight on the core–shellstructure of zerovalentironnanoparticles and its application for Pb(II)sequestration. Journal of Hazardous Materials. 263: 685-693, 2013.
[42]Liu,Z. G., Zhou, X. F., Chen, X. H., Dai, C. M., Zhang, J., Zhang, Y. L.Biosorption of clofibric acid and carbamazepine in aqueous solution byagricultural waste rice straw. Journal of Environmental Sciences-China, 25(12).2384-2395 ,2013.
[43]C.Dai, J. Zhang, Y. Zhang, X Zhou, S. Liu. Selective removal ofacidic pharmaceuticals from contaminated lake water using multi-templatesmolecularly imprinted polymer. Chemical Engineering Journal, 211-212: 302-309,2012.
[44]C.Dai, X. Zhou,Y. Zhang, Z. Qiang, T C. Zhang. Comparative Study ofthe Degradation of Carbamazepine in Water by Advanced Oxidation Processes.Environmental Technology, 33(10-12): 1101-1109,2012.
[45]C.Dai Y. Zhang, X. Zhou, S. Liu, J Zhang. Synthesis by precipitationpolymerization of molecularly imprinted polymer microspheres for the selectiveextraction of diclofenac from water samples. Journal of Hazardous Materials.198:175-181,2011.
[46]C.Dai, S. Geissen, Y. Zhang, Y. Zhang and X. Zhou. Selective removalof diclofenac from contaminated water using molecularly imprinted polymermicrospheres. Environmental Pollution, 159: 1660-1666,2011.
[47]XZhou, C. Dai, Y Zhang, R. Y. Surampalli and T. C. Zhang. A preliminarystudy on the occurrence and behavior of carbamazepine (CBZ) in aquaticenvironment of Yangtze River Delta, China. Environmental Monitoring andAssessment, 173(1-4): 45-53,2011.
[48]C.Dai, S. Geissen, Y. Zhang, Y. Zhang and X. Zhou. Performanceevaluation and application of molecularly imprinted polymer for separation ofcarbamazepine in aqueous solution. Journal of Hazardous Materials, 184(1-3):156-163,2010.
[49]X.Zhou, Y. Zhang, D. Q. Xu, W. H. Cao, C. Dai, Z. Qiang, Z. Yang and J. F.Zhao. Treatment of succinonitrile wastewater by immobilized high efficiencymicroorganism strains. Water Science & Technology, 58(4): 911-918,2008.
[50]代朝猛,沈晖,段艳平,刘曙光。土壤和地下水环境中纳米材料迁移的研究进展,水资源与水工程学报,2018,29(3):237-248
[51] 代朝猛*,周辉,刘曙光,谭博,万耀强。地下水多孔介质中胶体与污染物协同运移规律研究进展,水资源与水工程学报,2017,28(5):15-23
[52]谭博,刘曙光,代朝猛*,邓慧萍,周辉,丰莎。滨海地下水交互带中的胶体运移行为研究综述,水科学进展,2017, 28 (5):788-800.
[53]贺亚雪,代朝猛*,苏益明,张亚雷。地下水重金属污染修复技术研究进展。水处理技术,42(2):1-5, 2016.
[54]尹曾甫,文志潘,张亚雷,代朝猛*,周雪飞。二维纳米片层结构MoS2和其改性材料的合成及在环境领域的应用,材料导报,30(11):131-135,2016.
[55]宋世琨,苏益明,代朝猛,周雪飞,张亚雷。纳米硫化铁在环境保护中的应用研究进展,化工进展,35(1):248-254,2016.
[56]钱冬旭,张亚雷,周雪飞,代朝猛,钱雅洁,苏益明。钼污染水体处理技术研究进展,化工进展,35(2):617-623,2016.
[57]陶安,刘曙光,娄厦,代朝猛。含水层中重金属运移的动力学模型研究进展,水资源保护,31(4):8-14,2015.
[58]陈文,张亚雷,周雪飞,代朝猛。水中铟(Ⅲ)的分离富集及资源化回用研究进展,化工进展,34(7):2009-2015,2015
[59]闫婧, 代朝猛,周雪飞,张亚雷。碳纳米管复合材料用于削减水环境中污染物的研究进展,材料导报,29(1), 127-131, 2015.
[60]何永珍,周雪飞,代朝猛,张亚雷。铁氧体及其复合材料去除水体中有机污染物的研究进展,材料导报,29(3), 16-24, 2015.
[61] 朱岩,张亚雷,代朝猛,周雪飞,张伟贤。纳米零价铁颗粒用于地下水原位修复的研究进展,现代农业科技,4:204-208, 2015.
[62]刘彦静,曾小兵,代朝猛,周雪飞,张亚雷。石墨烯纳米复合材料在水处理中的应用研究进展,材料导报,27(7), 127-138, 2013.
[63]周传龙,代朝猛*,张亚雷,张伟贤。大气重金属引发交叉污染的研究,环境化学,31(9): 1344-1348. 2012.
[64]张娟,代朝猛,周雪飞*,张亚雷。水体中卡马西平的污染特征与赋存现状研究,给水排水,38(6):120-124, 2012.
[65]周传龙,代朝猛,张亚雷,张伟贤。新型环境功能材料对水体痕量污染物去除的研究进展,材料导报,26 (13):145-149, 2012.
[66]沈哲,代朝猛,张亚雷。纳米材料应用对环境的潜在风险的探讨,材料导报,26 (1): 19-22, 2012.
[67]李钰婷,代朝猛,张亚雷,张伟贤。环境介质中重金属的污染现状研究,安徽农业科学,40( 20): 10549-10553, 2012.
[68]李钰婷,张亚雷,代朝猛,张伟贤。纳米零价铁颗粒去除水中重金属的研究进展,环境化学,31 (9): 1349-1354,2012.
[69]沈哲,张亚雷,代朝猛。改性淀粉絮凝剂的应用现状和研究进展.水处理技术,38(10): 1-3,7,2012.
[70]段艳平,代朝猛,曾科,李亚萍。含脂类废水处理研究进展.工业水处理,28(2):16-19,2008.
[71] 代朝猛,曾科,段艳平,李亚萍。含脂肪酸废水处理方法,工业用水与废水,38(1): 47-50,2007.
[72]张娟,代朝猛,周雪飞,张亚雷。分子印迹聚合物在环境样品分析中的应用研究进展,环境污染与防治,33:77-80,2011.
[73]代朝猛,周雪飞,张亚雷。环境介质中药物和个人护理品的潜在风险研究进展,环境污染与防治,31(2):77-80,2009.
[74]周雪飞,张亚雷,代朝猛。城市污水处理系统去除药物和个人护理用品(PPCPs)的机理研究,环境保护科学,35(2):15-17,2009.
[75]周雪飞,代朝猛,张亚雷,石璐。水体环境中氟喹诺酮类药物的污染现状及分析方法,化工环保,28(6):505-508,2008.
[76]周雪飞,张亚雷,代朝猛。饮用水处理中药物和个人护理用品去除特性的研究进展,环境与健康杂志,25(11):1024-1027,2008.
主要专利
[1]模拟地下水含氧量梯度分布的装置,(201910332088.X),第一发明人。
[2]一种地表-地下水交互带污染物穿透的智能控制实验系统,(201810673901.5)第一发明人。
[3]一种水静力条件下模拟土壤地下水含氧量梯度分布的装置,(201710065078.5),第一发明人。
[4]一种海绵城市关键模块作用下的地下水污染循环净化系统,(201611253989.2),第二发明人。
[5]一种花瓣状MoS2-Mn3O4纳米线磁性复合材料的制备方法及应用(201610225999.9),第一发明人。
[6]一种土壤地下水污染物穿透智能化取样及在线监测的实验系统,(201610295139.2),第二发明人。
[7]一种用于地下水污染物运移物理模型的潮汐型水头控制装置,(ZL201510124855.X),第二发明人。
[8]一种平板式二维地下水水动力及水质模型装置,(ZL201510056140.5)第二发明人。
[9]一种硫酸盐污染场地地下水污染治理和土壤修复方法,(ZL2015100167004),第二发明人。
[10]一种Fe(Ⅱ)活化过硫酸钠法修复地下水装置及方法,(ZL201510556985.0),第一发明人。
[11] 一种磁性氧化石墨烯分子印迹复合材料的制备方法及应用,(ZL201410309288.0),第一发明人。
[12] 一种纳米零价铁-β沸石新型复合纳米材料的制备方法及应用,(201410326691.4),第一发明人。
[13] 一种可测量水位、原位溶解氧及采集不同深度地下水的方法及装置,(ZL201410160857X),第二发明人。
[14] 组件式垂直饱和土柱污染物迁移试验装置,(ZL2014105423163),第二发明人。
[15] 一种除氟、砷和微生物的一体化装置,(ZL2014205775789),第二发明人。
[16] 羟基亚铁除铁锰水处理一体化装置,(ZL2014205659025),第二发明人。
[17] 一种同步去除废水中重金属的铁基材料制备方法及应用,(ZL201410028027.1),第四发明人。
[18] 一种强化除铁锰反应沉淀耦合池,(201410485723.5),第二发明人。
[19] 同步去除多种重金属离子的多级逆流反应一体化工艺及装置,(ZL201410550568.0),第四发明人。
[20]纳米零价铁-多级反滤式系统去除工业废水中重金属的方法及其装置,(ZL201210447872.3),第四发明人。
[21] 一种选择性分离氯贝酸的核壳式分子印迹聚合物的制备方法及其应用,(ZL201110310791.4),第一发明人。
[22]一种典型酸性药物多模板分子印迹聚合物的制备方法和应用(ZL201210181488.3),第二发明人。
[23]一种选择性分离卡马西平的磁性分子印迹聚合物制备方法及应用,(ZL201210325770.4),第二发明人。
[24]一种低污染生物强化膜生物反应器,(ZL201320439036.0),第三发明人。
[25]一种改进的生物强化膜生物反应器,(ZL201320439024.8),第三发明人。
[26]一种处理重金属废水的一体化工艺,(ZL201310053836.3),第二发明人。
[27]应用磁生物强化膜生物反应器的水处理方法,(201310172378.5),第二发明人。
[28]一种利用磁性分子印迹-电磁格栅联合去除土壤中药物的方法,(ZL2013100642691),第一发明人。
[29]一种利用电磁搅拌桨去除工业废水中重金属的方法及装置,(201210559393.0),第三发明人。
[30]纳米零价铁-电磁系统去除电镀废水中重金属的方法及其装置,(201210039770.8),第三发明人。
[31] 纳米零价铁净化废水中镉的方法及其装置,(ZL201210418941.8),第四发明人。
[32]纳米零价铁去除污泥中有害物质的方法,(201210395601.8),第三发明人。
主要著作
参编《药物及个人护理品的环境污染与控制》,科学出版社,2012。
编著《新兴污染物的分析、迁移转化与控制技术:以药物活性化合物为例》,第3作者,科学出版社,2017。
教学工作
本科生课程:《工程水文学》,《专业导论(土木与环境类)》
研究生课程:《生态水文学》(硕士生、博士生共选)
扫码关注
考研信息一网打尽