当前位置: X-MOL首页全球导师 国内导师 › 陈伟

个人简介

曾获荣誉: 中国科学院优秀博士学位论文 陈伟,男,汉族,1988年生,湖南邵阳人。中南大学冶金与环境学院特聘副教授。2010年本科毕业于中国科学技术大学,2010-2016年于中国科学技术大学化学系攻读环境工程专业博士学位(硕博连读),2015-2016年于美国普渡大学访学交流。长期致力于环境中化学活性有机物质及其相关环境行为的分子光谱研究工作,在光谱电化学、环境光谱计量学、膜污染及环境相互作用等领域开展了一系列创新性工作。以第一/通讯作者在Chem、Environmental Science & Technology、Water Research等化学与环境领域著名刊物上发表SCI论文30余篇,总计50余篇,他引1000余次,申请国家发明专利10项,授权5项。获2018年中国科学院优秀博士学位论文。讲授《环境监测》、《环境影响评价》、《环境仪器分析方法》等课程。 教育经历 [1] 2015.9-2016.9 普渡大学 | 生物医学工程 联合培养博士研究生 [2] 2010.9-2016.12 中国科学技术大学 | 环境工程 | 工学博士 | 研究生 [3] 2006.9-2010.7 中国科学技术大学 | 化学 | 理学学士 | 本科 工作经历 [1] 2017.7-至今 中南大学 | 冶金与环境学院 | 特聘副教授 [2] 2017.3-2017.7 中南大学 | 冶金与环境学院 | 助理研究员 科研项目 [1]高氨氮复杂废水协同强化处理技术(2018SK2020),湖南省重点研发计划子课题,10万,2018-2021,在研,在研,湖南省科技厅,陈伟 [2]垃圾渗滤液处理组合新工艺的研究(H201811280350001),校企合作项目,50万,2018-2019,在研,在研, 湖南中金岭南康盟环保科技有限公司,陈伟 [3]矿区有机质调控铅镉重金属形态转化机制的光谱计量学研究(21707167),国家自然科学基金青年项目,23万,2018-2020,在研,在研,国家自然科学基金委,陈伟 [4]难降解废水有机质变化指纹光谱分析及处理新工艺的构建,中南大学科研启动经费,80万,2017-2021,在研,在研,特聘副教授科研启动金,陈伟 获奖信息 [1]中国科学院优秀博士学位论文-2018|2018,陈伟 [2]上海同济高廷耀环保科技发展基金会“青年博士生杰出人才奖学金”-2015|2015 [3]奥加诺“水质与水环境”奖学金一等奖-2015|2015 [4]教育部国家奖学金(博士)-2014|2014 专利成果 [1]一种磷酸铁生产过程中母液的循环利用方法,2017 [2]一种处理白钨矿的方法,2018 [3]一种氯化铜锰液制备电池级硫酸锰的方法,2018

研究领域

[1] 难降解废水高级氧化处理及其过程机理的分子光谱研究 [2] 分子光谱表征膜污染 [3] 溶解性有机质环境相互作用 [4] 环境电子媒介氧化还原特性的光谱电化学研究

[1] 分子光谱表征膜污染:利用光谱分析手段,实现膜污染物的分子识别及时空分布;得到污染物化学组分、浓度分布及渗透深度等信息;提出膜污染的可能机制。 [2] 溶解性有机质-重金属环境相互作用:通过光谱计量分析,对溶解性有机质与重金属作用过程中结构变化进行解析。 [3] 环境电子媒介氧化还原特性的光谱电化学研究:通过构建原位光谱电化学反应及监测装置,对氧化还原反应过程中电子媒介的特性进行解析。 [4] 废水处理光谱监测:利用光谱监测技术结合化学计量分析,对废水处理过程中有机物的结构变化进行示踪,解析其降解机理,为工程化应用提供指导。

近期论文

查看导师新发文章 (温馨提示:请注意重名现象,建议点开原文通过作者单位确认)

[1]Chen, W.; Yu, H.-Q.*.Advances in the characterization and monitoring of natural organic matter using spectroscopic approaches.[J]:Water Res.,2020,190:116759 [2]Lei, Q.-Y.; He, D.-W.*; Zhou, K.-G.; Zhang, X.-K.; Peng, C.-H.; Chen, W.*.Separation and recovery of scandium and titanium from red mud leaching liquor through a neutralization precipitation-acid leaching approach.[J]:J. Rare Earth.,2020:Accepted. [3]Zhang, Z.; Teng, C.-Y.; Zhou, K.-G.; Peng, C.-H.; Chen, W.*.Degradation characteristics of dissolved organic matter in nanofiltration concentrated landfill leachate during electrocatalytic oxidation.[J]:Chemosphere,2020,255:127055 [4]Chen, W.*; Peng, L.; Hu, K.-R.; Zhang, Z.; Peng, C.-H.; Teng C.-Y.; Zhou K.-G.*.Spectroscopic response of soil organic matter in mining area to Pb/Cd heavy metal interaction: A mirror of coherent structural variation.[J]:J. Hazard. Mater.,2020,393:122425 [5]Zhang, X.-K.; Zhou, K.-G.; Lei, Q.-Y.; Xing, Y.; Peng, C.-H.; Chen, W.*.Stripping of Fe(III) from Aliquat 336 by NaH2PO4: Implication for rare-earth elements recovery from red mud.[J]:Sep. Sci. Technol.:Accepted. [6]Zhang, X.-K.; Zhou, K.-G.; Wu, Y.-H.-Z.; Lei, Q.-Y.; Peng, C.-H.; Chen, W.*.Separation and recovery of iron and scandium from acid leaching solution of red mud using D201 resin.[J]:J. Rare Earth.,2020,38(12):1322-1329 [7]Zhang, X.-K.; Zhou, K.-G.; Lei, Q.-Y.; Xing, Y.; Peng, C.-H.; Chen, W.*.Integration of resource recycling with de-alkalization for bauxite residue treatment.[J]:Hydrometallurgy,2020,192:105263 [8]Teng, C.-Y.; Zhou, K.-G.; Zhang, Z.; Peng, C.-H.; Chen, W.*.Elucidating the structural variation of membrane concentrated landfill leachate during Fenton oxidation process using spectroscopic analyses.[J]:Environ. Pollut.,2020,256:113467 [9]Wang, A.; Zhou, K.-G.*; Zhang, X.-K.; Zhou, D-C.; Peng, C.-H.; Chen, W.*.Arsenic removal from highly-acidic wastewater with high arsenic content by copper-chloride synergistic reduction.[J]:Chemosphere,2020,238:124675 [10]Zhang, X.-K.; Zhou, K.-G.*; Lei, Q.-Y.; Huang, Y.; Peng, C.-H.; Chen, W.*.Selective removal of iron from acid leachate of red mud by Aliquat 336.[J]:JOM,2019,71(12):4608-4615 [11]Zhou, K.-G.; Wu, Y.-H.-Z.; Zhang, X.-K.; Peng, C.-H.; Cheng, Y.-Y.; Chen, W.*.Removal of Zn(II) from manganese-zinc chloride waste liquor using ion-exchange with D201 resin.[J]:Hydrometallurgy,2019,190:105171 [12]Wang, A.; Zhou, K.-G.*; Zhang, X.-K.; Zhou, D.-C.; Peng, C.-H.; Chen, W.*.Reductive removal of arsenic from waste acid containing high-acidity and arsenic levels through iodide and copper powder synergy.[J]:Chem. Eng. J.,2019,373:23-30 [13]Chen, W.; Teng, C.-Y.; Qian, C.; Yu, H.-Q.*.Characterizing properties and environmental behaviors of dissolved organic matter using two-dimensional correlation spectroscopic analysis.[J]:Environ. Sci. Technol.,2019,53(9):4683–4694 [14]Gong, D.-D.; Zhou, K.-G.*; Li, J.-J.; Peng, C.-H.; Chen, W.*.Kinetics of roasting reaction between synthetic scheelite and magnesium chloride.[J]:JOM,2019,71(8):2827–2833 [15]Gong, D.-D.; Zhou, K.-G.*; Peng, C.-H.; Li, J.-J.; Chen, W.*.Sequential extraction of tungsten from scheelite through roasting and alkaline leaching.[J]:Minerals Engineering,2019,132(1):238-244 [16]Gong, D.-D.; Zhou, K.-G.*; Peng, C.-H.; He, D.-W.; Chen, W.*.Resin-enhanced acid leaching of tungsten from scheelite.[J]:Hydrometallurgy,2018,182:75-81 [17]Zhou, K.-G.; Teng, C.-Y.; Zhang, X.-K.; Peng, C.-H.; Chen, W.*.Enhanced selective leaching of scandium from red mud.[J]:Hydrometallurgy,2018,182:57-63 [18]Gong, D.-D.; Zhou, K.-G.*; Li, J.-J.; Peng, C.-H.; Chen, W.*.Rapid leaching of synthetic scheelite by a resin-in-pulp process.[J]:JOM,2018,70(12):2846-2855 [19]Guan, Y.-F.#; Qian, C.#; Chen, W.*; Huang, B.-C.; Wang, Y.-J.; Yu, H.-Q.*.Interaction between humic acid and protein in membrane fouling process: A spectroscopic insight.[J]:Water Res.,2018,145:146-152 [20]Habibul, N.; Chen, W.*.Structural response of humic acid upon binding with lead: A spectroscopic insight.[J]:Sci. Total Environ.,2018,643:479-485 [21]Liu, F.; Zhou, K.-G.; Chen, Q.-Z.; Wang, A.-H.; Chen, W.*.Comparative study on the synthesis of magnetic ferrite adsorbent for the removal of Cd(II) from wastewater.[J]:Adsorpt. Sci. Technol.,2018,36(7-8):1456-1469 [22]Chen, W.; Qian, C.; Zhou, K.-G.; Yu, H.-Q.*.Molecular spectroscopic characterization of membrane fouling: A critical review.[J]:Chem,2018,4:1-18 [23]Zhou, K.-G.; Pan, L.-X.; Peng, C.-H.; He, D.-W.; Chen, W.*.Selective precipitation of Cu in manganese-copper chloride leaching liquor.[J]:Hydrometallurgy,2018,175:319–325 [24]Chen, W.; Ouyang, Z.-Y.; Qian, C.*; Yu, H.-Q..Induced structural changes of humic acid by exposure of polystyrene microplastics: A spectroscopic insight.[J]:Environ. Pollut.,2018,233:1-7 [25]Chen, W.; Qian, C.; Hong, W.-L.; Cheng, J.-X.*; Yu, H.-Q.*.Evolution of membrane fouling revealed by label-free vibrational spectroscopic imaging.[J]:Environ. Sci. Technol.,2017,51(17):9580–9587 [26]Chen, W.; Liu, X.-Y.; Yu, H.-Q.*.Temperature-dependent conformational variation of chromophoric dissolved organic matter and its consequent interaction with phenanthrene.[J]:Environ. Pollut.,2017,222:23-31 [27]Chen, W.; Liu, X.-Y.; Huang, B.-C.; Wang, L.-F.; Yu, H.-Q.*; Mizaikoff, B.*.Probing membrane fouling via infrared attenuated total reflection mapping coupled with multivariate curve resolution.[J]:ChemPhysChem,2016,17(3):358-363 [28]Chen, W.; Habibul, N.; Liu, X.-Y.; Yu, H.-Q.*.FTIR and synchronous fluorescence heterospectral two-dimensional correlation analyses of the binding characteristics of copper to dissolved organic matter.[J]:Environ. Sci. Technol.,2015,49:2052-2058 [29]Chen, W.; Liu, X.-Y.; Qian, C.; Song, X.-N.; Li, W.-W.; Yu, H.-Q.*.An UV –vis spectroelectrochemical approach for rapid detection of phenazines and exploration of their redox characteristics.[J]:Biosens. Bioelectron.,2015,64:25-29 [30]Chen, W.; Qian, C.; Liu, X.-Y.; Yu, H.-Q.*.Two-dimensional correlation spectroscopic analysis on the interaction between humic acids and TiO2 nanoparticles.[J]:Environ. Sci. Technol.,2014,48(19):11119-11126 [31]Chen, W.#; Chen, J.-J.#; Lu, R.; Qian, C.; Li, W.-W.; Yu, H.-Q.*.Redox reaction characteristics of riboflavin : A fluorescence spectroelectrochemical analysis and density functional theory calculation.[J]:Bioelectrochemistry,2014,98:103-108 [32]Liu, X.-Y.#; Chen, W.#; Qian, C.; Yu, H.-Q.*.Interaction between dissolved organic matter and long-chain ionic liquids: A microstructural and spectroscopic correlation study.[J]:Envrion. Sci. Technol.,2017,51(9):4812–4820 [33]Zhang, D.-L.#; Chen, W.#; Chen, H.; Yu, H.-Q.; Kassab, G.*; Cheng, J.-X.*.Chemical imaging of fresh vascular smooth muscle cell response by epi-detected stimulated Raman scattering.[J]:Journal of Biophotonics,2018,11(2):1-7 [34]Lu, R.#; Chen, W.#; Li, W.-W.; Sheng, G.-P.; Wang, L.-J.; Yu, H.-Q.*.Probing the redox process of p-benzoquinone in dimethyl sulphoxide by fluorescence spectroelectrochemistry.[J]:Front. Environ. Sci. Eng.,2017,11:14 [35]Chen, J.-J.#; Chen, W.#; He, H.; Li, D.-B.; Li, W.-W.; Xiong, L.; Yu, H.-Q.*.Manipulation of microbial extracellular electron transfer by changing molecular structure of phenazine-type redox mediators.[J]:Environ. Sci. Technol.,2013,47:1033-1039 [36]Liu, X.-Y.; Chen, W.; Yu, H.-Q.*.Probing protein-induced membrane fouling with in-situ attenuated total reflectance fourier transform infrared spectroscopy and multivariate curve resolution-alternating least squares.[J]:Water Res.,2020,183:116052 [37]Qian, C.; Chen, W.; Gong, B.; Yu, H.-Q..Determination of saccharides in environments using a sulfuric acid-fluorescence approach.[J]:Environ. Sci. Technol.,2020,54(11):6632–6638 [38]Xue, S.-G.; Tang, L.; Tang, Y.-K.; Li, C.-X.; Li, M.-L.; Zhou, J.-J.; Chen, W.; Zhu, F.; Jiang, J.*.Selective electrocatalytic water oxidation to produce H2O2 using a C, N Co-doped TiO2 electrode in acidic electrolyte.[J]:ACS Appl. Mater. Interfaces,2020,12(4):4423-4431 [39]Wang, L.-F.; Chen, W.; Song, X.-C.; Li, Y.*; Zhang, W.-L.; Zhang, H.-J.; Niu, L.-H..Cultivation substrata differentiate the properties of river biofilm EPS and their binding of heavy metals: A spectroscopic insight.[J]:Environ. Res.,2020,182:109052 [40]Qian, C.; Chen, W.; Gong, B.; Wang, L.-F.; Yu, H.-Q.*.Diagnosis of the unexpected fluorescent contaminants in quantifying dissolved organic matter using excitation-emission matrix fluorescence spectroscopy.[J]:Water Res.,2019,163:114873 [41]He, D.-W.; Yang, Y.; Tang, J.-J.*; Zhou, K.-G.; Chen, W.; Chen, Y.-P.; Dong, Z.-J..Synergistic effect of TiO2-CuWO4 on the photocatalytic degradation of atrazine.[J]:Environ. Sci. Pollut. Res.,2019,26(12):12359-12367 [42]Zhang, X.-K.; Zhou, K.-G.*; Chen, W.; Lei, Q.-Y.; Huang, Y.; Peng, C.-H..Recovery of iron and rare earth elements from red mud through an acid leaching-stepwise extraction approach.[J]:Journal of Central South University,2019,26(2):458-466 [43]Chen, Y.; Chen, W.; Chen, Q.-Z.; Peng, C.-H.; He, D.-W.; Zhou, K.-G.*.Removal of ammonia-nitrogen in wastewater using a novel poly ligand exchanger-Zn(II)-loaded chelating resin.[J]:Water Science & Technology,2019,79(1):126-136 [44]Liu, F.; Zhou, K.-G.*; Chen, Q.-Z.; Wang, A.-H.; Chen, W..Application of magnetic ferrite nanoparticles for removal of Cu(II) from copper-ammonia wastewater.[J]:Journal of Alloys and Compounds,2018,773:140-149 [45]Liu, F.; Zhou, K.-G.*; Chen, Q.-Z.; Wang, A.-H.; Chen, W..Preparation of magnetic ferrite by optimizing the synthetic pH and its application for the removal of Cd(II) from Cd-NH3-H2O system.[J]:Journal of Molecular Liquids,2018,264:215-222 [46]Wang, A.-H.; Zhou, K.-G.*, Chen, W.; Zhang, C.; Liu, X. Chen, Q.-Z.; Liu, F..Adsorption of fluoride by the calcium alginate embedded with Mg-Al-Ce trimetal oxides.[J]:Korean Journal of Chemical Engineering,2018,35(8):1636-1641 [47]Wang, W.-L.#; Min, Y.#; Yu, S.-S.; Chen, W. Chen, J.-J.*; Liu, X.-Y.; Yu, H.-Q.*.Probing electron transfer between hemin and riboflavin using a combination of analytical approaches and theoretical calculations.[J]:Physical Chemistry Chemical Physics,2017,19:32580--32588 [48]Huang, B.-C.; Guan, Y.-F.; Chen, W.; Yu, H.-Q.*.Membrane fouling characteristics and mitigation in a coagulation-assisted microfiltration process for municipal wastewater pretreatment.[J]:Water Res.,2017,123:216-223 [49]Qian, C.; Wang, L.-F.; Chen, W.; Wang, Y.-S.; Liu, X.-Y.; Jiang, H.; Yu, H.-Q.*.Fluorescence approach for the determination of fluorescent dissolved organic matter.[J]:Anal. Chem.,2017,89(7):4264–4271 [50]Qian, C.; Chen, W.; Li, W.-H.; Yu, H.-Q.*.A chemometric analysis on the fluorescent dissolved organic matter in a full-scale sequencing batch reactor for municipal wastewater treatment.[J]:Front. Environ. Sci. Eng.,2017,11(4):12 [51]Habibul, N.; Hu, Y.; Wang, Y.-K.; Chen, W.; Yu, H.-Q.; Sheng, G.-P.*.Bioelectrochemical Chromium (VI) Removal in Plant-Microbial Fuel Cells.[J]:Environ. Sci. Technol.,2016,50:3882-3889 [52]Wang, L.-F.; He, D.-Q.; Chen, W.; Yu, H.-Q.*.Probing the roles of Ca2+ and Mg2+ in humic acids-induced ultrafiltration membrane fouling using an integrated approach.[J]:Water Res.,2015,81(0):325-332 [53]Lu, R.; Sheng, G.-P.; Liang, Y.; Li, W.-H.; Tong, Z.-H.; Chen, W.; Yu, H.-Q.*.Characterizing the interactions between polycyclic aromatic hydrocarbons and fulvic acids in water.[J]:Environ. Sci. Pollut. Res.,2013,20(4):2220-2225 [54]王小瑶; 周康根; 彭长宏; 陈伟*.联合法处理高 SCN- 含量有机制药废水.[J]:水处理技术,2019,45(1):75-80

学术兼职

[1] 2020.10-至今 国际水协(IWA)中国青年委员会(YWP)委员 [2] 2019.1-至今 Member of International Water Association (IWA). Membership No. 1616237 [3] 2016.1-至今 中国化学会 会员 [4] 2016.10-至今 Environmental Science & Technology, Water Research, Environmental Pollution, Journal of Hazardous Materials, Chemosphere等期刊审稿人。

推荐链接
down
wechat
bug