高冠道教授

发布时间:2019-01-05浏览次数:22045


高冠道

博士,教授

Email: gaoguandao@nju.edu.cn

南京大学环境学院C412

Tel:025-89681675

教育及工作背景

2016 至今  南京大学,环境学院,教授/博导

2005 2016  南开大学,环境科学与工程学院,历任讲师(2005),副教授(2008),教授/博导(2013

2010  2012  哈佛大学,工程与应用科学学院博士后

2002 2005  南京大学,环境工程,博士

1995  2002  兰州铁道学院,给水排水工程,学士(1999);市政工程,硕士(2002

代表性学术论文

  1. Wang, Y.; Xu, Y.; Dong, S.; Wang, P.; Chen, W.; Lu, Z.; Ye, D.; Pan, B.;Wu, D.; Vecitis, C. D. & Gao, G., Ultrasonic activation of inert poly(tetrafluoroethylene) enables piezocatalytic generation of reactive oxygen species. Nature Communications 2021, 12, 3508.

  2. Pu, L.; Xu, Y.; Xia, Q.; Ding, J.; Wang, Y.; Shan, C.; Wu, D.; Zhang, Q.; Gao, G.; Pan, B., Ferroelectric membrane for water

    purification with arsenic as model pollutant. Chemical Engineering Journal 2021, 403.

  3. Bu, Y.; Li, H.; Yu, W.; Pan, Y.; Li, L.; Wang, Y.; Pu, L.; Ding, J.; Gao, G.; Pan, B., Peroxydisulfate Activation and Singlet Oxygen Generation by Oxygen Vacancy for Degradation of Contaminants. Environmental Science & Technology 2021, 55, (3), 2110-2120.

  4. Wang, C.; Dong, S.; Wang, Y.; Guo, T.; Gao, G.; Lu, Z.; Pan, B., Selective removal of nitrate via the synergistic effect of oxygen vacancies and plasmon-induced hot carriers.Chemical Engineering Journal 2020, 397.

  5. Pan, M.; Wang, J.; Gao, G.; Chew, J. W., Incorporation of single cobalt active sites onto N-doped graphene for superior conductive membranes in electrochemical filtration.Journal of Membrane Science 2020, 602.

  6. Liu, Z.; Dong, S.; Zou, D.; Ding, J.; Yu, A.; Zhang, J.; Shan, C.; Gao, G.; Pan, B., Electrochemically mediated nitrate reduction on nanoconfined zerovalent iron: Properties and mechanism. Water Research 2020, 173.

  7. Liu, Y.; Gao, G.; Vecitis, C. D., Prospects of an Electroactive Carbon Nanotube Membrane toward Environmental Applications. Accounts of Chemical Research2020, 53, (12), 2892-2902.

  8. Hu, Y.; Wang, Y.; Wen, X.; Pan, Y.; Cheng, X.; An, R.; Gao, G.; Chen, H.-Y.; Ye, D., Responsive Trimodal Probes for In Vivo Imaging of Liver Inflammation by Coassembly and GSH-Driven Disassembly. Research 2020.

  9. Garcia-Segura, S.; Qu, X.; Alvarez, P. J. J.; Chaplin, B. P.; Chen, W.; Crittenden, J. C.; Feng, Y.; Gao, G.; He, Z.; Hou, C.-H.; Hu, X.; Jiang, G.; Kim, J.-H.; Li, J.; Li, Q.; Ma, J.; Ma, J.; Nienhauser, A. B.; Niu, J.; Pan, B.; Quan, X.; Ronzani, F.; Villagran, D.; Waite, T. D.; Walker, W. S.; Wang, C.; Wong, M. S.; Westerhoff, P., Opportunities for nanotechnology to enhance electrochemical treatment of pollutants in potable water and industrial wastewater - a perspective. Environmental Science-Nano 2020, 7, (8), 2178-2194.

  10. Ding, J.; Pu, L.; Zou, D.; Cao, M.; Shan, C.; Zhang, Q.; Gao, G.; Pan, B., Removal of model dyes on charged UF membranes: Experiment and simulation. Chemosphere 2020, 240.

  11. Ding, J.; Pan, Y.; Li, L.; Liu, H.; Zhang, Q.; Gao, G.; Pan, B., Synergetic adsorption and electrochemical classified recycling of Cr(VI) and dyes in synthetic dyeing wastewater. Chemical Engineering Journal 2020, 384.

  12. Shan, C.; Dong, H.; Huang, P.; Hua, M.; Liu, Y.; Gao, G.; Zhang, W.; Lv, L.; Pan, B., Dual-functional millisphere of anion-exchanger-supported nanoceria for synergistic As(III) removal with stoichiometric H2O2: Catalytic oxidation and sorption. Chemical Engineering Journal 2019, 360, 982-989.

  13. Pan, M.; Zhang, C.; Wang, J.; Chew, J. W.; Gao, G.; Pan, B., Multifunctional Piezoelectric Heterostructure of BaTiO3@Graphene: Decomplexation of Cu-EDTA and Recovery of Cu. Environmental Science & Technology 2019, 53, (14), 8342-8351.

  14. Pan, M.; Wang, J.; Hua, M.; Gao, G.; Wang, X.; Chew, J. W., Augmentation of hydroxyl groups as electrocatalytic active sites in porous graphene.Carbon 2019, 154, 384-390.

  15. Pan, M.; Chen, Z.; Shan, C.; Wang, Y.; Pan, B.; Gao, G., Photochemical activation of seemingly inert SO42- in specific water environments. Chemosphere 2019, 214, 399-407.

  16. Yang, Z.; Yu, A.; Shan, C.; Gao, G.; Pan, B., Enhanced Fe(III)-mediated Fenton oxidation of atrazine in the presence of functionalized multi-walled carbon nanotubes. Water Research 2018, 137, 37-46.

  17. Shan, C.; Xu, Z.; Zhang, X.; Xu, Y.; Gao, G.; Pan, B., Efficient removal of EDTA-complexed Cu(II) by a combined Fe(III)/UV/alkaline precipitation process: Performance and role of Fe(II). Chemosphere 2018, 193, 1235-1242.

  18. Pan, M.; Shan, C.; Zhang, X.; Zhang, Y.; Zhu, C.; Gao, G.; Pan, B., Environmentally Friendly in Situ Regeneration of Graphene Aerogel as a Model Conductive Adsorbent. Environmental Science & Technology 2018, 52, (2), 739-746.

  19. Pan, M.; Shan, C.; Hua, M.; Guo, S.; Pan, B.; Gao, G., Enhanced Photochemical/Electrochemical Performance of Graphene Benefited from Morphological Change as Substrate of Typical Composites. Advanced Materials Interfaces 2018, 5, (13).

  20. Li, T.; Zhang, W.; Zhai, S.; Gao, G.; Ding, J.; Zhang, W.; Liu, Y.; Zhao, X.; Pan, B.; Lv, L., Efficient removal of nickel(II) from high salinity wastewater by a novel PAA/ZIF-8/PVDF hybrid ultrafiltration membrane. Water Research2018, 143, 87-98.

  21. Ding, J.; Pu, L.; Wang, Y.; Wu, B.; Yu, A.; Zhang, X.; Pan, B.; Zhang, Q.; Gao, G., Adsorption and Reduction of Cr(VI) Together with Cr(III) Sequestration by Polyaniline Confined in Pores of Polystyrene Beads. Environmental Science & Technology2018, 52, (21), 12602-12611.

  22. Pan, M.; Zhang, Y.; Shan, C.; Zhang, X.; Gao, G.; Pan, B., Flat Graphene-Enhanced Electron Transfer Involved in Redox Reactions. Environmental Science & Technology 2017, 51, (15), 8597-8605.

  23. Pan, M.; Ding, J.; Duan, L.; Gao, G., Sunlight-driven photo-transformation of bisphenol A by Fe(III) in aqueous solution: Photochemical activity and mechanistic aspects. Chemosphere 2017, 167, 353-359.

  24. Zhou, W.; Jia, X.; Chen, L.; Yin, Z.; Zhang, Z.; Gao, G., Low cost NiS as an efficient counter electrode for dye-sensitized solar cells.Materials Letters 2016, 163, 1-3.

  25. Liu, L.; Sun, M.; Zhang, H.; Yu, Q.; Li, M.; Qi, Y.; Zhang, C.; Gao, G.; Yuan, Y.; Zhai, H.; Chen, W.; Alvarez, P. J. J., Facet Energy and Reactivity versus Cytotoxicity: The Surprising Behavior of CdS Nanorods.Nano Letters 2016, 16, (1), 688-694.

  26. Duan, L.; Wang, Z.; Hou, Y.; Wang, Z.; Gao, G.; Chen, W.; Alvarez, P. J. J., The oxidation capacity of Mn3O4 nanoparticles is significantly enhanced by anchoring them onto reduced graphene oxide to facilitate regeneration of surface-associated Mn(III). Water Research 2016, 103, 101-108.

  27. Zhen, M.; Sun, M.; Gao, G.; Liu, L.; Zhou, Z., Synthesis of Mesoporous Wall-Structured TiO2 on Reduced Graphene Oxide Nanosheets with High Rate Performance for Lithium-Ion Batteries. Chem-Eur J2015, 21, (14), 5317-5322.

  28. Zhen, M.; Guo, S.; Gao, G.; Zhou, Z.; Liu, L., TiO2-B nanorods on reduced graphene oxide as anode materials for Li ion batteries. Chem Commun2015, 51, (3), 507-510.

  29. Zhang, X.; Guo, S.; Zhen, M.; Gao, G.; Liu, L., Morphology Property Effect in Electrocatalysis Based on Ni1-chi Se@Graphene Series with Specific Stoichiometric Ratio. J Electrochem Soc2015, 162, (10), H774-H779.

  30. Xu, Z.; Gao, G.; Pan, B.; Zhang, W.; Lv, L., A new combined process for efficient removal of Cu(II) organic complexes from wastewater: Fe(III) displacement/UV degradation/alkaline precipitation. Water Research 2015, 87, 378-384.

  31. Wang, F.; Wang, F.; Gao, G.; Chen, W., Transformation of graphene oxide by ferrous iron: Environmental implications. Environmental Toxicology and Chemistry 2015, 34, (9), 1975-1982.

  32. Pan, M.; Zhang, H.; Gao, G.; Liu, L.; Chen, W., Facet-Dependent Catalytic Activity of Nanosheet-Assembled Bismuth Oxyiodide Microspheres in Degradation of Bisphenol A. Environmental Science & Technology 2015, 49, (10), 6240-6248.

  33. Guo, S.-q.; Sun, M.-q.; Gao, G.-d.; Liu, L., Scalable low-cost CdS nanospheres@graphene nanocomposites counter electrode for high efficiency dye-sensitized solar cells. Electrochimica Actam 2015, 176, 1165-1170.

  34. Gao, G.; Zhang, Q.; Hao, Z.; Vecitis, C. D., Carbon Nanotube Membrane Stack for Flow-through Sequential Regenerative Electro-Fenton. Environmental Science & Technology 2015, 49, (4), 2375-2383.

  35. Gao, G.; Pan, M.; Vecitis, C. D., Effect of the oxidation approach on carbon nanotube surface functional groups and electrooxidative filtration performance.Journal of Materials Chemistry A2015, 3, (14), 7575-7582.

  36. Zhen, M.; Guo, X.; Gao, G.; Zhou, Z.; Liu, L., Rutile TiO2 nanobundles on reduced graphene oxides as anode materials for Li ion batteries.Chem Commun 2014, 50, (80), 11915-11918.

  37. Zhang, X.; Jing, T.-z.; Guo, S.-q.; Gao, G.-d.; Liu, L., Synthesis of NiSe2/reduced graphene oxide crystalline materials and their efficient electrocatalytic activity in dye-sensitized solar cells. Rsc Advances2014, 4, (92), 50312-50317.

  38. Li, G.; Chen, X.; Gao, G., Bi2S3 microspheres grown on graphene sheets as low-cost counter-electrode materials for dye-sensitized solar cells. Nanoscale2014, 6, (6), 3283-3288.

  39. Guo, S.-q.; Zhang, X.; Zhou, Z.; Gao, G.-d.; Liu, L., Facile preparation of hierarchical Nb2O5 microspheres with photocatalytic activities and electrochemical properties. Journal of Materials Chemistry A 2014, 2, (24), 9236-9243.

  40. Guo, S.-q.; Zhang, X.; Hao, Z.-w.; Gao, G.-d.; Li, G.; Liu, L., In2O3 cubes: synthesis, characterization and photocatalytic properties. Rsc Advances 2014, 4, (59), 31353-31361.

  41. Gao, G.; Zhang, Q.; Vecitis, C. D., CNT-PVDF composite flow-through electrode for single-pass sequential reduction-oxidation. Journal of Materials Chemistry A 2014, 2, (17), 6185-6190.

  42. Vecitis, C. D.; Gao, G.; Liu, H., Electrochemical Carbon Nanotube Filter for Adsorption, Desorption, and Oxidation of Aqueous Dyes and Anions. Journal of Physical Chemistry C2011, 115, (9), 3621-3629.

  43. Gao, G.; Vecitis, C. D., Electrochemical Carbon Nanotube Filter Oxidative Performance as a Function of Surface Chemistry. Environmental Science & Technology 2011, 45, (22), 9726-9734.

  44. Sun, H.; Xu, X.; Gao, G.; Zhang, Z.; Yin, P., A novel integrated active capping technique for the remediation of nitrobenzene-contaminated sediment. Journal of Hazardous Materials 2010, 182, (1-3), 184-190.

  45. Guo, C.; Ge, M.; Liu, L.; Gao, G.; Feng, Y.; Wang, Y., Directed Synthesis of Mesoporous TiO2 Microspheres: Catalysts and Their Photocatalysis for Bisphenol A Degradation. Environmental Science & Technology2010, 44, (1), 419-425.

  46. Liu, L.; Liu, H.; Zhao, Y.-P.; Wang, Y.; Duan, Y.; Gao, G.; Ge, M.; Chen, W., Directed synthesis of hierarchical nanostructured TiO2 catalysts and their morphology-dependent photocatalysis for phenol degradation. Environmental Science & Technology 2008, 42, (7), 2342-2348.

  47. Gao, G.; Zhang, A.; Zhang, M.; Chen, J.; Zhang, Q., Reaction factors and kinetics of degradation of malachite green with novel biomimetic photocatalyst HMS-FePcS.Chinese Journal of Catalysis 2008, 29, (4), 397-402.

  48. Gao, G.; Zhang, A.; Zhang, M.; Chen, J.; Zhang, Q., Photocatalytic degradation mechanism of malachite green under visible light irradiation over novel biomimetic photocatalyst HMS-FePcs.Chinese Journal of Catalysis 2008, 29, (5), 426-430.

  49. Wu, L.; Li, A.; Gao, G.; Fei, Z.; Xu, S.; Zhang, Q., Efficient photodegradation of 2,4-dichlorophenol in aqueous solution catalyzed by polydivinylbenzene-supported zinc phthalocyanine. Journal of Molecular Catalysis a-Chemical 2007, 269, (1-2), 183-189.

  50. Gao, G. D.; Chen, J. L.; Fei, Z. H.; Li, A. M.; Lu, J. D.; Long, C.; Zhang, Q. X., Degradation of malachite green in aqueous solutions with a novel catalyst of hypercrosslinked resin. Acta Polymerica Sinica 2006, (1), 113-117.

  51. Gao, G. D.; Chen, J. L.; Zheng, S. R.; Fei, Z. H.; Liu, F. Q.; Li, A. M.; Lu, X. G.; Zhang, Q. X., Synthesis of novel biomimetic photocatalyst and its use for visible light-assisted catalytic degradation of malachite green. Chinese Journal of Catalysis2005, 26, (7), 545-549.

  52. Liu, F. Q.; Chen, J. L.; Long, C.; Li, A. M.; Gao, G. D.; Zhang, Q. X., Adsorption of 1,2,4-acid by weakly basic resin: Isotherms, thermodynamics and kinetics.Chinese Journal of Polymer Science2004, 22, (3), 219-224.

  53. Fei, Z. H.; Chen, J. L.; Gao, G. D.; Long, C.; Li, A. M.; Zhang, Q. X., Adsorption of chloroform and trichloroethylene in water with a new kind of hypercrosslinked resins.Chinese Journal of Polymer Science 2004, 22, (5), 425-430.

发明专利

1. 高冠道,丁杰,一种导电吸附树脂的制备方法,专利号:ZL201511001479.1

2. 高冠道,郝振威,张秀丽,一种阴阳两极协同降解硝基苯类污染物的"三明治"型膜电极系统及方法,专利号:ZL ZL201310213119.2

3. 高冠道,郝振威,张秀丽,一种基于碳纳米管制备膜电极及其电解去除有机污染物的方法,专利号:ZL 201310208195.4

4. 高冠道,潘梅兰,潘丙才, 一种石墨烯气凝胶的制备方法及其应用, 201810033499.4

5. 高冠道,潘梅兰,潘丙才, 一种Cu-EDTA重金属络合废水的处理方法, 201810342341.5

6. 高冠道, 任志远, 潘丙才, 蒲良桃, 丁杰, 刘振威, 董上上, 喻安晴, 王炎锋, 一种基于碳纳米管内孔性质的高通量复合滤膜及制备方法, 201810343211.

7. 高冠道, 刘振威, 潘丙才, 丁杰, 蒲良桃, 王炎锋, 任志远, 喻安晴, 董上上, 一种基于载零价铁纳米复合树脂为催化剂的阴阳两极协同降解硝酸盐的装置及方法, 201810348539.4

8. 高冠道, 徐芳, 一种电化学还原去除水体中高氯酸盐的方法, 201710411266.9,公开号CN107162117A

9. 高冠道, 丁杰, 潘丙才, 蒲良桃,  王炎锋, 刘振威, 任志远, 董上上, 喻安晴, 一种聚苯胺基复合功能材料、制备方法及应用, 201810315187.2

10. 高冠道,张萌,张爱勇,任玉辉,尹玉玲,朱莹佳,中孔材料HMS固载磺酸铁酞菁光催化剂的制备方法,公开号:CN 101590428

11. 高冠道,张萌,张爱勇,任玉辉,尹玉玲,朱莹佳,一种利用可见光催化降解有机污染物的树脂催化剂及其制备方法,公开号:CN101590429

12. 肖羽堂,高冠道,赵美姿,1-氨基-8-萘酚-3,6-二磺酸生产废水的治理及其回收利用方法,公开号:CN101066824, 2010-10-27授权

13. 孙红文,高冠道,徐晓阳,张子种,高效修复水体中有机物污染沉积物的反应格栅技术,公开号:CN101289255

14. 张全兴,鲁秀国,高冠道,陈金龙,李爱民,龙超,韩永忠,氯酸盐法制备二氧化氯的方法,专利号: ZL200410013828.7

15. 龙超,李爱民,高冠道,费正皓,张全兴,陈金龙,硝基氯苯生产废水中硝基氯苯的树脂吸附回收工艺,专利号: ZL200410014428.8

16. 李爱民,吴林,高冠道,钱洪明,朱兆连,吴春金,胡学伟,陈金龙,一种负载金属酞菁光催化剂及其制备方法,专利号:ZL 200610098315.X

17. 李爱民,费正皓,钱洪明,龙超,张根成,刘福强,高冠道,刘伟,蔡建国,石鸿雁,王穆君,陈金龙,张全兴,间苯二甲酸二甲酯-5-磺酸钠生产废水的治理及资源化方法,专利号:ZL 200310106127.3  

承担科研项目

1. 江苏省重点研发计划社会发展项目”超高通量-抗污染型膜材料的开发及在水处理领域中的示范应用” (BE2017710,主持,2017.7-2020.6)

2. 政府间国际科技创新合作重点专项”基于纳米复合材料的污水回用技术与安全性评估” (2017YFE0107200,主研,2018.01 - 2020.12)

3. 科技部重点研究计划-纳米专项“基于纳米复合材料的水处理集成技术开发与应用示范”(2016YFA0203104,主研,2016.6-2021.5)

4. 国家自然科学基金项目“基于碳纳米管内孔(壁)的电化学特性高效降解有机污染物的过程和机理”(21577069,主持,2016.01-2019.12)

5. 天津市应用基础研究重点项目“碳纳米管内孔(壁)的电化学特性及污染物在其内高效催化降解” (15JCZDJC40000, 主持,2015.5-2018.04)

6. 国家自然科学基金项目“仿生光催化剂的合成及其对有毒有机废水的降解研究”(20803036,主持,已完成)

7. 国家科技人员服务企业行动计划“功能树脂的开发及对有毒有机化工废水的治理及资源化应用”(2009GJA10014,主持,已完成)

8. 国家水体污染控制与治理科技重大专项“典型行业再生水规模化循环利用水质安全保障关键技术”(2008ZX07314-003-2,主研,已完成)

研究方向

 1. 涉电物理效应(热电、压电、铁电等)及环境功能纳米材料界面电荷调控

 2. 电调控水处理技术、原理及应用

 3. 碳纳米管阵列滤膜的规模化构建及潜在应用