代伟

基本信息Personal Information

教授 博士生导师 硕士生导师

主要任职 : 1.材料与化工硕士点负责人;2.浙师大金开技术创新研究院院长

性别 : 男

毕业院校 : 天津大学

学历 : 博士研究生毕业

学位 : 博士学位

在职信息 : 在岗

所在单位 : 化学与材料科学学院

入职时间 : 2007年07月01日

学科 : 化学

办公地点 : 15-L303

联系方式 : qq:116083695

Email :

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个人简介Personal Profile

代伟:教授,博士生(博士后)导师

个人简介:

2007年获天津大学化学工程工学博士,2011-2012年在美国Purdue大学化工系访问学者,2013-2015南京工业大学博士后(合作导师:黄和 院士)。全球前2%顶尖科学家,浙江省钱江人才,浙江省团队科技特派员首席专家,金华市321人才,浙江师范大学教学名师。近年来主持国家自然科学基金面上项目、浙江省“领雁”科技计划项目在内的10余项国家/省部级项目。《Nature Communications》、《Nature Materials》、《Science Advances》等期刊审稿人,国家自然基金函评专家、江苏、上海、广东、湖南、河北、山西等省级科技计划项目、省级人才、科技奖、国家高新技术企业等评审专家。发表SCI论文百余篇,授权发明专利十余件。荣获浙江省科学技术发明二等奖和绿色矿山科学技术二等奖,制定两项国家标准。主讲化工设计、制药工程设备与车间设计、精细化学品化学、环境化学与清洁生产等课程,多次指导学生在国创、新苗等科研训练及挑战杯、化工设计竞赛、化学竞赛等学科竞赛中获奖(例如:2024年第一指导教师带领学生获全国大学生化工设计竞赛总决赛特等奖),主编出版中英版教材1部、发表教改论文5篇。近年来主持50多项企业资助的技术研发项目,为众多企业解决了许多技术上的痛点与难点,获得了良好的社会和经济效益。

研究方向:以人工智能、化工、食品和医药等为导向的新型精细化学品研发

发表论文(*corresponding author):

[1] Tingwei Wang, Tingting Zhan, Xiaojing Zhou, Na Ma, Wei Dai*. Proton etching-driven synthesis of MIL-101(Fe)-templated Cu-Fe LDH nanocatalysts: Synergistic Z-scheme heterojunction with Cu/Fe dual-metal redox cycling for high-efficiency photocatalytic degradation of tetracycline. Journal of Environmental Chemical Engineering, 2025, 13, 117876.

[2] Yuning Jin, Tingwei Wang, Tingting Zhan, Na Ma, Wei Dai*. Interface-electronically engineered MOF-on-MOF heterojunctions exhibiting dual light-driven functions: Synergistic fluorescence diagnosis and photocatalytic remediation of antibiotic contamination. Journal of Molecular Structure, 2025, 1346, 143183.

[3] Yan Li, Zhouheng Xia, Tingting Zhan, Mingzhi Mao, Na Ma, Wei Dai*. Levofloxacin synergistic capture using a “memory-effect” layered double oxides loaded with ZIF-67 nanoparticles. Langmuir, 2025, 41, 12140−12149.

[4] Yuning Jin, Tingting Zhan, Xiaojing Zhou, Na Ma, Wei Dai*. Modular design of hollow pancake-shaped TiO2/Fe2O3 nanoreactor derived from dual MOFs and its excellent photo-Fenton catalytic activity towards tetracycline. Journal of Alloys and Compounds, 2025, 1026, 180470.

[5] Yilan Liu, Qingyu Lei, Jun Chen, Kaiyi Chen, Xin Wang, Jiamin Wei*, Lianshe Fu, Rute A.S. Ferreira, Wei Dai*, Tinghai Yang*. Construction of nanoporous MOF with channel transfer effect and coupling AgCl for enhancing photodegradation efficiency. Applied Surface Science, 2025, 699, 163128.

[6] Qiaolan Yu, Tingting Zhan, Zhouheng Xia, Gaojie Lu, Na Ma, Wei Dai*. Well-construction of hollow-pocket shaped Zn-based metal-organic framework for boosting the capture ability towards thiophene sulfur. Particuology, 2025, 9, 116-127.

[7] Xichen Mi, Xiaojing Zhou, Tingting Zhan, Yitong Chen, Na Ma, Wei Dai*. Interfacial engineering-mediated electronic structure regulation of homologous S-scheme LaFeO3@MIL-100(Fe) heterojunction: Enhancement of photocatalytic activity towards levofloxacin. Separation and Purification Technology, 2025, 363, 132126.

[8] Tingwei Wang, Yuning Jin, Xiaojing Zhou, Gaojie Lu, Weiwei Huan, Na Ma, Wei Dai*. Well-constructed of hollow Z-heterojunction nanocatalysts MIL101(Fe)@CdIn2S4 using MIL-101 as a template for efficient photocatalytic degradation of tetracycline. Surfaces and Interfaces, 2025, 59, 106002.

[9] Heng Lin, Zhouheng Xia, Kunpeng Xue, Xiaojing Zhou, Yifan Yao, Na Ma, Wei Dai*. Synergistically enhanced capture of perfluorooctanoic acid using a novel dual metal-organic framework adsorbent. Particuology, 2025, 97, 130-142.

[10] Xichen Mi, Tingwei Wang, Yitong Chen, Dan Cao, Na Ma, Wei Dai*. Ingenious construction of a magnetic-recyclable photo-Fenton catalyst ZnFe2O4@MIL-88A(Fe) and its adsorption-degradation activity toward levofloxacin. Journal of Environmental Sciences, 2025, 151, 677-691.

[11] Heng Lin, Jiehong Chen, Yifan Yao, Gaojie Lu, Weiwei Huan, Na Ma, Wei Dai*. Enhancement capture capability of cadmium ions using a MOF-in-MOF composite. Journal of Solid State Chemistry, 2025, 343, 125149.

[12] Danping Wu, Heng Lin, Tingting Zhan, Xingfa Ren, Yifan Yao, Na Ma, Wei Dai*. Boosting the sustained release performance of metronidazole and ornidazole with MIL-53(Fe) derived spherical porous carbon, Langmuir, 2024, 40, 26696−26705.

[13] Jiaying Zou, Qiaolan Yu, Dan Cao, Qianer Wang, Na Ma, Wei Dai*. NiFe2O4 magnetic nanoparticles supported on MIL-101(Fe) as bimetallic adsorbent for boosted capture ability toward levofloxacin. Materials Today Chemistry, 2024, 41, 102310.

[14] Yan Li, Heng Lin, Qiaolan Yu, Na Ma, Wei Dai*. UiO-66-NH2 nanoparticles supported on layered double hydroxides as an excellent adsorbent for levofloxacin capture. Particuology, 2024, 92, 155e165.

[15] Danping Wu, Heng Lin, Xingfa Ren, Jianglu Qian, Na Ma, Wei Dai*. ZIF-8 derived spherical porous carbon as an efficient sustained-release carrier for nitroimidazole drugs. Materials Today Chemistry, 2024, 38, 102057.

[16] Jiehong Chen, Heng Lin, Qiaolan Yu, Na Ma, Wei Dai*. Enhanced cadmium ions capture performance with a dual-zinc metal-organic framework composite. Journal of Solid State Chemistry, 2024, 335, 124703.

[17] Yuning Jin, Xichen Mi, Jianglu Qian, Na Ma, Wei Dai*. CdS Nanoparticles Supported on a Dual Metal−Organic Framework as a Catalyst for the Photodegradation of Tetracycline. ACS Applied Nano Materials, 2024, 7, 3154−3167.

[18] Xiuxuan Fang, Jiaying Zou, Xichen Mi, Na Ma, Wei Dai*. Synergistic boosting capture ability of thiophene sulfur with a novel dual-amino-functionalized MOF-on-MOF adsorbent. Langmuir, 2024, 40, 2405−2415.

[19] Danping Wu, Jiaying Zou, Junyi Chen, Yan Li, Na Ma, Wei Dai*. Boosted sustained-release with iron-based MOF-derived mesoporouscarbon-spheres as a nitroimidazole drugs carrier. Particuology, 2024, 86, 269e280.

[20] Jiaying Zou, Yan Li, Haotian Dong, Na Ma, Wei Dai*. Well-constructed a water stable Cu-BTC@TpPa-1 binary composite with excellent capture ability toward malachite green. Environmental Science and Pollution Research, 2023, 30, 124306–124315.

[21] Yingzhi Zhu, Yan Li, Na Ma, Wei Dai*. Adsorptive removal of tetracycline and methylene blue from aqueous solution with a water resistance copper-based metal-organic framework. New Journal of Chemistry, 2023, 47, 20499–20509.

[22] Jianglu Qian, Xichen Mi, Haotian Dong, Jiaqian Lv, Na Ma, Wei Dai*. Boosted capture ability of Rhodamine B by a core-shell composite equipped with spherical porous carbon and copper-based metal-organic framework. Journal of Solid State Chemistry, 2023, 327, 124267.

[23] Jiehong Chen, Yan Li, Gangfeng Liang, Na Ma, Wei Dai*. Boosted capture of trace Cd(II) with a magnetic dual metal-organic-framework adsorbent. Journal of Solid State Chemistry, 2023, 322, 123956.

[24] Yingzhi Zhu, Danping Wu, Jiehong Chen, Na Ma, Wei Dai*. Boosting highly capture of trace tetracycline with a novel water-resistant and magnetic (ZIF-8)-on-(Cu-BTC@Fe3O4) composite. Journal of Solid State Chemistry, 2023, 319, 123797.

[25] Xiuxuan Fang, Jiaying Zou, Na Ma, Wei Dai*. Boosting the Adsorption Performance of Thiophenic Sulfur Compounds with a Multimetallic Dual Metal–Organic Framework Composite. Langmuir, 2022, 38, 14451–14464.

[26] Yuning Jin, Xichen Mi, Jianglu Qian, Na Ma, Wei Dai*. Modular Construction of an MIL-101(Fe)@MIL-100(Fe) Dual-Compartment Nanoreactor and Its Boosted Photocatalytic Activity toward Tetracycline. ACS Appl. Mater. Interfaces, 2022, 14, 48285–48295.

[27] Haotian Dong, Jiehong Chen, Danping Wu, Kunpeng Xue, Na Ma, Wei Dai*. Well-constructed approach of exceptionally water-stable (mesoporous SiO2)-on-(microporous Cu-BTC) composite for efficient methylene blue capture. New Journal of Chemistry, 2022, 46, 13582–13592.

[28] Jiafei Wu, Yuning Jin, Danping Wu, Xiaoying Yan, Na Ma, Wei Dai*. Well-construction of Zn2SnO4/SnO2@ZIF-8 core-shell hetero-structure with efficient photocatalytic activity towards tetracycline under restricted space. Chinese Journal of Chemical Engineering, 2022, 52, 45–55.

[29] Shiya Zhang, Yingzhi Zhu, Na Ma, Wei Dai*. Enhanced capture of benzothiophene with a magnetism-bimetallic Fe3O4@Zn/Cu-BTC composite. Environmental Progress & Sustainable Energy, 2022, 41(6): e13873.

[30] Yuning Jin, Danping Wu, Na Ma, Wei Dai*. Well-design and synthesis of a water- and heat-resistant UiO-67@CNTs composite for Congo red efficient capture. Water Science & Technology, 2022, 85(5):1636–1647.

[31] Xiuxuan Fang, Yingzhi Zhu, Haotian Dong, Na Ma, Wei Dai*. Ability evaluation of thiophenic sulfurs capture with a novel (MOF-818)-on-(Cu-BTC) composite in the presence of moisture. Microporous and Mesoporous Materials, 2022, 333, 111756.

[32] Yingzhi Zhu, Danping Wu, Jiehong Chen, Na Ma, Wei Dai*. Enhanced water-resistant performance of Cu-BTC through polyvinylpyrrolidone protection and its capture ability evaluation of methylene blue. New Journal of Chemistry, 2022, 46, 3358–3369.

[33] Hanyin Zheng, DanpingWu, Yan Chen, Xinyu Xue, Shouwen Jin, Wei Dai*. Efficient capture of ornidazole through cobalt/zinc-containing naonoporous carbons derived from cobalt/zinc-based MOF-74, Journal of Solid State Chemistry, 2022, 308, 122936.

[34] Yuan Gao, Xiuxuan Fang, Dabo Chen, Na Ma, Wei Dai*. Ternary photocatalyst of ZIF-8 nanofilms coupled with AgI nanoparticles seamlessly on ZnO microrods for enhanced visible-light photocatalysis degradation. Journal of the Taiwan Institute of Chemical Engineers, 2022, 131, 104146.

[35] Leshui Lian, Shiya Zhang, Na Ma, Wei Dai*. Well-designed a novel phosphomolybdic-acid@PCN-224 composite with efficient simultaneously capture towards rubidium and cesium ions. Polyhedron, 2021, 207, 115402.

[36] Jiafei Wu, Xiuxuan Fang, Haotian Dong, Leshui Lian, Na Ma, Wei Dai*. Bimetallic silver/bismuth-MOFs derived strategy for Ag/AgCl/BiOCl composite with extraordinary visible light-driven photocatalytic activity towards tetracycline. Journal of Alloys and Compounds, 2021, 877, 160262.

[37] Jiafei Wu, Yingzhi Zhu, Kunpeng Xue, Yan Lu, Jiahao Hu, Wei Dai*. Efficient elimination of organic contaminants with novel and stable zeolite@MOF layer adsorbents. Particuology, 2021, 58, 74–84.

[38] Yuan Gao, Jiafei Wu, Jiaqi Wang, Na Yan, Na Ma, Wei Dai*. Design and in situ synthesis of ZnInS@ZIF-8-nanofilms multifunctional nanocomposite: A case application for simultaneous fluorescent sensing and enhanced photocatalytic performance toward antibiotic. Microporous and Mesoporous Materials, 2021, 315, 110916–110926.

[39] Jiafei Wu, Xiuxuan Fang, Yingzhi Zhu, Na Ma, Wei Dai*. Well-designed TiO2@UiO-66-NH2 nanocomposite with superior photocatalytic activity for tetracycline under restricted space. Energy Fuels, 2020, 34, 10, 12911–12917.

[40] Yuan Gao, Jiafei Wu, Xiaoqin Xiong, Na Yan, Na Ma, Wei Dai*. Enhanced dibenzothiophene capture with multimetal−organic frameworks in the presence of benzene and octane. Industrial & Engineering Chemistry Research, 2020, 59(16): 7849–7856.

[41] Yuan Gao, Jiafei Wu, Shuting Wang, Na Yan, Na Ma, Wei Dai*. Design and fabrication of a novel water- and heat-resistant Cu-based coordination compound for dibenzothiophene capture. Energy & Fuels, 2020, 34, 4, 4508–4515.

[42] Yuan Gao, Jiafei Wu, Jiaqi Wang, Yuxin Fan, Shiya Zhang, Wei Dai*. A novel multifunctional p-type semiconductor@MOFs nanoporous platform for simultaneous sensing and photodegradation of tetracycline. ACS Applied Materials & Interfaces 2020, 12, 11036–11044.

[43] YuningJin, Jiafei Wu, Jiaqi Wang, Yuxin Fan, Shiya Zhang, Na Ma, Wei Dai*. Highly efficient capture of benzothiophene with a novel water-resistant-bimetallic Cu-ZIF-8 material. Inorganica Chimica Acta, 2020, 503, 119412–119419.

[44] Ning Tian, Jiafei Wu, Jiaqi Wang, Wei Dai*. Development of a Novel core−shell magnetic Fe3O4@CMC@ZIF-8-OH composite with outstanding rubidium-ion capacity. Journal of Chemical and Engineering Data, 2019, 64(12): 5716–5724.

[45] Yitian Zhou, Le Yu, Yuan Gao, Jiafei Wu, Wei Dai*. Effective capture of cefradines in water with a highly stable Zr(IV)-based bimetal−organic framework. Industrial & Engineering Chemistry Research, 2019, 58, 19202–19210.

[46] Ning Tian, Yuan Gao, Jiafei Wu, Suqing Luo, Wei Dai*. Water-resistant HKUST-1 functionalized with polydimethylsiloxane for efficient rubidium ion capture. New Journal of Chemistry, 2019, 43, 15539–15547.

[47] Qing Liu, Yuan Gao, Yitian Zhou, Ning Tian, Gangfeng Liang, Na Ma, Wei Dai*. Highly improved water resistance and congo red uptake capacity with a Zn/Cu-BTC@MC composite adsorbent. J. Chem. Eng. Data, 2019, 64(8): 3323–3330.

[48] Ning Tian, Yifang Dai, Qing Liu, Wei Dai*. Highly efficient capture of rubidium ion by a novel HS-Fe3O4@MIL-53(Al) composite material. Polyhedron, 2019, 166, 109–114.

[49] Qing Liu, Guihua Zhao, Yifang Dai, Na Ma, Wei Dai*. Rubidium ion capture with a phosphotungstic acid-functionalized finger-citron-residue-based carbon. RSC Adv., 2019, 9, 9106–9112.

[50] Le Yu, Ning Tian, Congmin Liu, Qing Liu, Yuan Gao, Wei Dai*. Development of a novel double-templated mesoporous carbon with outstanding desulfurization capacity. Journal of the Taiwan Institute of Chemical Engineers, 2019, 96, 520–525.

[51] Guihua Zhao, Qing Liu, Ning Tian, Le Yu, Wei Dai*. Highly efficient benzothiophene capture with a metal-modified copper–1,3,5-benzenetricarboxylic acid adsorbent. Energy Fuels, 2018, 32(6): 6763-6769.

[52] Huijing Yu, Tingting Wang, Wei Dai*, Le Yu, Na Ma. Competitive adsorption of dye species onto biomass nanoporous carbons in single and bicomponent systems. Brazilian Journal of Chemical Engineering, 2018, 35(1): 1–12.

[53] Le Yu, Qing Liu, Wei Dai*, Ning Tian, Na Ma. Efficient thiophene capture with a hydrophobic Cu-BTC-(n)Br adsorbent in the presence of moisture. Microporous and Mesoporous Materials, 2018, 266, 7–13.

[54] Wei Dai*, Yaoyao Fang, Le Yu, Guihua Zhao, Xiaoying Yan. Rubidium ion capture with composite adsorbent PMA@HKUST-1. Journal of the Taiwan Institute of Chemical Engineers, 2018, 84, 222-228.

[55] Guihua Zhao, Yaoyao Fang, Wei Dai*, Na Ma. Highly enhanced adsorption of congo red by functionalized finger-citron-leaf-based porous carbon. Water Science and Technology, 2018, 77(1): 220-228.

[56] Luying Ma, Guihua Zhao, Yaoyao Fang, Wei Dai*, Na Ma. Facile synthesis of mesoporous calcium carbonate particles with finger citron residue as template and their adsorption performances for congo red. Adsorption Science & Technology, 2018, 36(3–4): 872–887.

[57] Wei Dai*, Ning Tian, Congmin Liu, Le Yu, Qing Liu, Na Ma, and Yuexing Zhao. (Zn, Ni, Cu)-BTC functionalized with phosphotungstic acid for adsorptive desulfurization in the presence of benzene and ketone, Energy Fuels, 2017, 31 (12): 13502–13508.

[58] Wanni Wang, Fu Zhang, Chuanling Zhang, Yanchuan Guo, Wei Dai*, Hai-Sheng Qian. Fabrication of zinc oxide composite microfibers for near-infrared-light-mediated photocatalysis. CHEMCATCHEM, 2017, 9(18): 3611–3617.

[59] Yaoyao Fang, Guihua Zhao, Wei Dai*, Luying Ma, Na Ma. Enhanced adsorption of rubidium ion by a phenol@MIL-101(Cr) composite material. Microporous and Mesoporous Materials, 2017, 251, 51–57.

[60] Guihua Zhao, Yaoyao Fang, Wei Dai*, Na Ma. Copper-containing porous carbon derived from MOF-199 for dibenzothiophene adsorption. RSC Adv., 2017, 7, 21649–21654.

[61] Tingting Wang, Yaoyao Fang, Wei Dai*, Lifeng Hu, Na Ma and Le Yu. The remarkable adsorption capacity of zinc/nickel/copper-based metal–organic frameworks for thiophenic sulfurs. RSC Adv., 2016, 6, 105827–105832.

[62] Huijing Yu, Tingting Wang, Le Yu, Wei Dai*, Na Ma, Xin Hu, Ye Wang. Remarkable adsorption capacity of Ni-doped magnolia-leaf-derived bioadsorbent for congo red. Journal of the Taiwan Institute of Chemical Engineers. 2016, 64, 279–284.

[63] Yaoyao Fang, Wei Dai*, Lin Chen, Na Ma. Facile synthesis of ordered mesoporous carbon with finger citron residue as carbon precursor. Materials Letters, 2016, 174, 246–248.

[64] Jue Hu, Wei Dai*, Xiaoyang Yan. Comparison study on the adsorption performance of methylene blue and congo red on Cu-BTC. Desalination and Water Treatment, 2016, 57(9): 4081–4089 

[65] Tingting Wang, Xianxing Li, Wei Dai*, Yaoyao Fang and He Huang. Enhanced adsorption of dibenzothiophene with zinc/copper-based metal-organic porous material. Journal of Materials Chemistry A, 2015, 3(42):21044–21050.

[66] Huijing Yu, Tingting Wang, Wei Dai*, Xianxing Li, Xin Hu and Na Ma. Single and bicomponent anionic dyes adsorption equilibrium studies on magnolia-leaf-based porous carbons. RSC Adv., 2015, 5, 63970–63977.

[67] Jingjing Ye, Fan Ye, Wei Dai*, Dong Ding. Formaldehyde capture with finger-citron-residue-based activated carbon. Sep. Sci. Technol., 2015, 50(2):253-259.

[68] Wei Dai*, Huijing Yu, Na Ma, Xiaoyang Yan. Adsorption equilibrium and kinetic studies of crystal violet and naphthol green on torreya-grandis-skin-based activated carbon. Korean J. Chem. Eng., 2015, 32 (2): 335–341.

[69] Wei Dai*, Rui Gong, Jue Hu, Li-Mei Zhou. Thiophene capture by an oxidation-modified activated carbon derived from bergamot. Sep. Sci. Technol., 2014, 49 (30): 367–375.

[70] Wei Dai*, Yuchen Liu, Tao Tong, Xingwei Li, Fang Luo. Rh(III)-catalyzed oxidative amidation of aldehydes: An efficient route to N-pyridinamides and imides. Chinese J. Catal., 2014, 35 (7): 1012–1016.

[71] Jue Hu, Huijing Yu, Wei Dai*, Xiaoyang Yan, Xin Hu, He Huang. Enhanced adsorptive removal of hazardous anionic dye “congo red” by a Ni/Cu mixed-component metal-organic porous material. RSC Adv., 2014, 4 (66): 35124–35130.

[72] Rui Gong, Jingjing Ye, Wei Dai*, Xiaoyang Yan, Jue Hu, Xin Hu, Shuang Li, He Huang. Adsorptive removal of methyl orange and methylene blue from aqueous solution with finger-citron-residue-based activated carbon. Ind. Eng. Chem. Res. 2013, 52 (39): 14297–14303.

[73] Wei Dai*, Jue Hu, Limei Zhou, Shuang Li, Xin Hu, He Huang. Removal of dibenzothiophene with composite adsorbent MOF-5/Cu(I). Energy & Fuels, 2013, 27 (2): 816–821.

[74] 代伟,董昊天,方秀玄,马娜. 一种抗水型MOFs材料的研制. 发明专利,授权号:ZL 202011530313.X

[75]代伟,朱宝军,马娜.一种室内用佛手炭雕以及用于该炭雕的佛手胶囊. 发明专利,授权号:ZL 2016 1 1170053.3

[76]代伟,马娜,陈建荣. 用佛手渣制备活性炭的方法。发明专利,授权号:ZL201010183831.9

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