个人简历

张冠，海外留学回国人员，广东省珠江人才计划青年项目，深圳海外高层次人才B类。
主持国家自然科学基金面上项目、青年项目、深圳市基础研究项目、技术创新等项目，发表50余篇SCI论文，一作通讯高影响因子论文包括： Chem Soc Rev. 2016(IF=40.1); Energy Environ. Sci. 2014 (IF=30.2), Appl. Catal B:Environ. (IF=16.2) 等，总引用1500余次，ESI高被引论文2篇。
每年招收硕士生~3 人，2021年开始每年招收全职博士生1-2人，欢迎大家咨询。
《资源有限，创意无限》
教育经历
2007.09 –2012.08 韩国浦项工科大学(2012年泰晤士报世界大学排名28位)，博士，环境科学与工程 (导师：Wonyong Choi)
2004.09-2007.07 辽宁大学，无机化学专业
2000.07-2004.07 辽宁大学，分析化学专业
研究与工作经历
2016.01 –现在 副教授，哈尔滨工业大学深圳研究生院
2014.01 –2015.12 项目研究员，英国圣安德鲁斯大学（15年泰晤士报世界大学排名87位）, 化学院 (导师：John TS. Irvine)
2012.09 –2013.12 博士后研究员，韩国浦项工科大学，环境能源研究所
2012.07-2012.08 访问学者，美国加州理工学院，环境学院
科研项目
2016.03-2019.03 哈工大新进教师科研启动项目（主持）
2016-2019 国家科技重大专项中小水厂饮用水安全项目（参与）
2017.08-2019.08 深圳科创委技术攻关项目-污染底泥处理技术（参与）
2017.10-2019.10 深圳市技术创新项目-光电化学废水处理（主持）
2017.03-2019.12 高层次人才科研启动项目-环境污染物治理（主持）
2018.01-2020.12 国家自然科学基金青年基金项目-新型光催化材料开发与去除污染物研究（主持）
2019.03-2021.03 深圳市基础研究项目-光催化氨氮处理技术（主持）
2020.01-2023.12 国家自然科学基金面上项目-光电热协同催化废水处理（主持）
2020.01-2023.12 国家自然科学基金面上项目-电化学还原全氟化合物（参与）
科研成果及奖励
2017.01 深圳市人才计划“B”类
2017.07 深圳市南山区领航人才“B”类
2011.12 2011年度国家优秀自费留学生奖学金 (国家留学基金委)
2011.11 CSS-13 国际会议杰出墙报奖 (日本九州)
2010.07 IPS-18 国际会议最佳墙报奖 (韩国首尔)
2009.11 CSS-11 国际会议最佳口头报告奖(韩国釜山)
2007.07 辽宁省优秀硕士学位毕业论文
2007.06 辽宁大学2007年优秀硕士学位论文一等奖
2007.04 辽宁大学2007年优秀科研成果二等奖
任教和任导师经历
讲授研究生课程与指导研究生： 春季：能源环境化学
春季：高级氧化技术
讲授本科生课程：秋季：环境化学
2016级：
凡祥-武汉科技大学-已毕业（哈工大优秀毕业生，现就职武汉中建三局公司）
周雨柔-哈尔滨商业大学-已毕业（哈工大优秀毕业生，现就职深圳市龙华区外国语学校）
2017级：
曲艺-合肥工业大学 （哈工大优秀毕业生，现就职华润地产有限公司）
宋霄-太原理工大学 （哈工大优秀毕业生，现就职中建科技深圳分公司）
陈曦-江西农业大学 （已毕业，江西省组织部选调生）
2018级：
谷豆豆-哈尔滨工业大学 研究方向： 沼气燃料电池开发技术（已毕业）
曲莎莎-东北大学 研究方向： 纤维素生物质转化技术（已毕业）
杜婷婷-成都大学 研究方向： 氨氮有机废水光电催化氧化技术
2019级：
阮居专-合肥工业大学 研究方向：电化学氧化去除氨氮技术
王俊祥-湘潭大学 研究方向：纤维素生物质能源转化技术
廖云开-安徽农业大学 研究方向：光电催化去除有机污染物技术
2020级：
陈楠-山东大学 研究方向：电化学氧化催化技术
毛超-山西大学 研究方向： 光催化污染物转化
李昭颐-中国石油大学（北京） 研究方向： 光电催化污染物转化

研究领域

√ 光（电）驱动分解水制氢与环境污染物消除
√ 光/电/热催化水环境和大气环境污染治理
√ 固体氧化物燃料电池
√ 生物质能源转换与开发
√ 催化技术产业化应用"环境污染物治理协同新能源开发、光电热协同催化技术、氢能开发与利用技术、生物质转化与利用等。"

近期论文

2021
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51) Y. Liao, J. Wang, X. Song, G. Zhang*, B. Chen, Low？cost and large mass producible phenolic resin for water disinfection and antibacterial coating under weak visible light LED or sunlight irradiation, Appl. Catal. B: Environ. 2021
50) H. R. S. Abdellatif, G. Zhang, D. Xie, J. NI, C. Ni*, Ionic Salt-Mediated Tuning of the Morphology and Band Structure of Graphitic Carbon Nitride for NO Removal under Visible Light, ACS Appl. Nano Mater. 2021
49) G. Zhang*, J. Ruan, T. Du, Recent Advances on Photocatalytic and Electrochemical Oxidation for Ammonia Treatment from Water/Wastewater, ACS EST Engg. 2021, 1, 3, 310-325.
48) D. Gu, G. Zhang, J. Zou, High temperature thermo-photocatalysis driven carbon removal in direct biogas fueled solid oxide fuel cells, Chinese Chemical Letters, 2021
47) J. Feng, X. Zhang, G. Zhang*, J. Li, W. Song, Z. Xu, Improved photocatalytic conversion of high concentration ammonia in water by low cost Cu/TiO2 and its mechanism study, Chemosphere, 2021, 274, 129689.
2020
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46) H. R. S. Abdellatif, G. Zhang, Y. Tang, W. Ruan….. C. Ni*, A highly efficient dual-phase GaN(O)/Nb2O5(N) photocatalyst prepared through nitridation and reoxidation process for NO removal, Chem. Eng. J. 2020，402, 126199.

45) X. Zhao, Y. You, S. Huang, Y. Wu, Y. Ma, G. Zhang, Z. Zhang*, Z-scheme photocatalytic production of hydrogen peroxide over Bi4O5Br2/C3N4 heterostructure under visible light, Appl. Catal. B: Environ. 2020, 119251.

44) Z. Zhou, Z. Shen, Z. Cheng, G. Zhang, M. Li, Y. Li, S. Zhan*, J. C. Crittenden, Mechanistic insights for efficient inactivation of antibiotic resistance genes: a synergistic interfacial adsorption and photocatalytic oxidation process, Science Bulletin, 2020, 65， 2107-2119.
43) D. Xie, Z. Tang, Y. Wang, R. Yin….. G. Zhang, Piezo-catalytic persulfate activation system for water advanced disinfection: process efficiency and inactivation mechanisms, Chem. Eng. J. 2020,400, 125894.

42) X. Zhao, G. Zhang, Z. Zhang, TiO2-based catalysts for photocatalytic reduction of aqueous oxyanions: State-of-the-art and future prospects, Environment International, 2020, 136,105453. (JCR 1区，中科院1区，IF=7.9)

41）G. Zhang*, Z. Zhang, D. Xia, Y. Qu, W. Wang, Solar driven self-sustainable photoelectrochemical bacteria inactivation in scale-up reactor utilizing large-scale fabricable Ti/MoS2/MoOx photoanode. J. Hazard. Mater., 2020, 392, 122292。(JCR 1区，中科院1区，IF=7.6)

40) Y. Qu, X. Song, X. Chen, X. Fan, G. Zhang*, Tuning charge transfer process of MoS2 photoanode for enhanced photoelectrochemical conversion of ammonia in water into gaseous nitrogen, Chem. Eng. J., 2020，382，123048。(JCR 1区，中科院1区，IF=8.3)

2019
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39) H. Abdellatif, G. Zhang, X. T. Wang, C Ni* et al. Boosting photocatalytic oxidation on graphitic carbon nitride for efficient photocatalysis by heterojunction with graphitic carbon units, Chem. Eng. J., 2019，370， 875-884.
38) X. Fan, Y. Zhou, G. Zhang*, T. Liu, W. Dong, In situ Photoelectrochemical Activation of Sulfite by MoS2 Photoanode for Enhanced Removal of Ammonium Nitrogen from Wastewater, Appl. Catal. B: Environ., 2019, 244,396-406.
37) J. Li, X. Dong, G. Zhang, W. Cui, W. Cen, Z. Wu, S. Lee, F. Dong*, Probing ring-opening pathways for efficient photocatalytic toluene decomposition, J. Mater. Chem. A, 2019,7, 3366-3374.
36) Y. Zhou, X. Fan, G. Zhang*, W. Dong, Fabricating MoS2 nanoflakes photoanode with unprecedented high photoelectrochemical performance and multi-pollutants degradation test for water treatment, Chem. Eng. J., 2019, 356, 1003-1013.

2018
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35) G. Zhang, R. D. Tyagi, J. Chen, J. Li, X. Zhang*, P. Drogui, X. Dong, Lipid Extraction from oleaginous microorganism with electrochemical method, Eur. J. Lipid Sci. Technol. 2018, 1800215.（IF=2.0）
34) S. Wei, G. Zhang*, X. Xu*, Activating BaTaO2N by Ca modifications and cobalt oxide for visible light photocatalytic water oxidation reactions, Appl. Catal. B: Environ., 2018, 237, 373-381.（JCR1区，IF= 11.5）
33) J. Zou, G. Zhang*, X. Xu, One pot photoreforming of cellulosic biomass waste to hydrogen by merging photocatalysis with acid hydrolysis, Appl. Catal. A, 2018, 563, 73-79.（JCR1区，IF= 4.3）

32) X. Huang, J. Feng, H. R. Abdellatif, J. Zou, G. Zhang, C. Ni, Electrochemical evaluation of double perovskite PrBaCo2-xMnxO5+δ (x = 0, 0.5, 1) as promising cathodes for IT-SOFCs. Int. J. Hydrogen energy, 2018, 43(18), 8962-8971. （JCR1区，IF= 3.5）
31) X. Zhang, G. Zhang*, J. Zou, Nitrogen reduction utilizing solvated electrons produced by thermal exciation of trapped electrons in reduced titanium oxide, New. J. Chem., 2018, 42, 6084-6090. （JCR2区，IF= 3.2）
30) G. Zhang, J. Zou*, Preparation and evaluation of novel Bi1.91Sr2Co1.96O7.08 cathode for intermediate temperature-solid oxide fuel cells, Mater. Lett., 2018, 217, 247-250. （JCR2区，IF= 2.5）
29) E. Huang, G. Liu, G. Zhang*, X. Xu*, In situ fabrication of two-dimensional g-C3N4/Ba5Ta4O15 nanosheet heterostructures with efficient charge separations and photocatalytic hydrogen evolution under visible light illumination, Dalton Trans., 2018, 47,4360-4367. (JCR 1区，IF=4.2)
28) G. Zhang, J. Zou*, X. Xu*, Reduced 3d transition metal oxides work as solid-state sources of solvated electrons and directly inject electrons into water for H2 production under mild thermal or IR excitation, Advanced Sustainable Systems, 2018, 2, 1700139.
2017
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27) C. Ni, Y. Zhang, X. huang, J. Zou, G. Zhang, J. Ni, effect of anode calcination on the performance and redox stability of low-temperature solid oxide fuel cells prepared via impregnation, Int. J. Hydrogen Energy, 2017, 42, 30760-30768. (JCR 1区, IF=3.5)
26) J. Hui, G. Zhang*, C.Ni, J. Irvine, Promoting photocatalytic H2 evolution by tuning cation deficiency in La and Cr co-doped SrTiO3, Chem. Commun., 2017 53(72), 10038-10042 . (JCR 1区，IF=6.3)
25）L. Wang, R. Niu, B. Chen*, L. Wang, G. Zhang. A comparison of photodegradation kinetics, mechanisms, and products between chlorinated and brominated/iodinated haloacetic acids in water., Chem. Eng. J., 2017, 230, 1326-1333 （JCR 1区，IF=6.3）
24) G. Zhang*,Y. Zhou, X. Fan, J. Zou, W. Dong, X. Xu, “Efficient and robust visible light photocatalytic H2 production based on CdSe quantum dots sensitized titania”，Int. Hydrogen Energy, 2017, 42(31) 19877-19884 （JCR1区，IF=4.3）
23）H. F. Greer, W. Zhou*, G. Zhang, H. Menard, Nanocone Decorated ZnO Microspheres Exposing the (0001) Plane and Enhanced Photocatalytic Properties，Adv. Mater. Interface., 2017, 4(13), 1601238. （JCR 1区，IF=4.2）
22) G. Zhang, C. Kim, W. Choi*, “Poly(4-vinylphenol) as a new stable and metal-free sensitizer of titania for visible light photocatalysis through ligand-to-metal charge transfer process”, Catal. Today, 2017, 281，109-116. (JCR1区，IF = 4.3)
21) S. Nagarajan, N. Skillen, F. Fina, G. Zhang, C. Randhorn, L. A. Lawton, J. TS. Irvine, P. K.J.Robertson, Comparative assessment of visible light and UV active photocatalysts by hydroxyl radical quantification, J.Photochem. Photobio：A: Chem., 2017, 334:13.（JCR2区，IF=2.6）
20) G. Zhang*, W. Dong, X. Huang, J. Zou, “Oxygen vacancy induced enhancement of photochemical water oxidation on calcium manganese oxide catalyst” Catal. Commun., 2017, 89，117-120 ( JCR 2 区， IF=3.3)
2016
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19) G. Zhang, G. Liu, L. Wang, J T. S. Irvine*, “Inorganic perovskite photocatalysts for solar energy utilization” Chem. Soc. Rev., 2016, 45, 5951-5984 (JCR 1区，IF=38.5)
18）G. Zhang*, J. Zou, Tuning Band Structure of CdS and Its Related Photocatalytic Performance by Co-Doping Ag and Trivalent Metals (M = Al, Cr, Ga and In) Nanosci. Nanotechnol. Lett. 2016, 8, 993-997.( JCR 3 区，IF=1.0)
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Before HITSZ
17) G. Zhang*, C. Ni, X. Huang, A. Welgamage, L. A. Lawton, P. K. J. Robertson, J. T. S. Irvine, “Simultaneous cellulose conversion and hydrogen production assisted by cellulose decomposition under UV-light photocatalysis” Chem. Commun., 2016，52，1673. (JCR 1区，IF=6.8)
16) L. Liu, G. Zhang, J., T. S. Irvine*, Y. Wu*. Organic semiconductor g-C3N4 modified TiO2 nanotube arrays for enhanced photoelectrochemical performance: dual roles of surface sensitization and passivation” Energy Technol., 2015,3, 982-988.（IF=2.8，JCR 2区）
15) G. Zhang*, C. Ni, L. Liu, G. Zhao, F. Fina, J. TS Irvine, “ Marcro-mesoporous resin as amorphous metal free visible light photocatalysts” J. Mater. Chem. A, 2015, 3, 15413-15419. (JCR 1区， IF=8.4)
14) G. Zhao, X. Huang, F. Fina, G. Zhang, J. TS Irvine*, “Facile Structure Design Based on C3N4 for Mediator-free Z-Scheme Water Splitting under Visible Light” Catal. Sci. Technol. 2015, 5, 3416. （JCR 2区，IF= 5.4）
13) G. Zhang, G. Kim, W. Choi*, “Visible light driven photocatalysis mediated via ligand-to-metal charge transfer (LMCT): an alternative approach to solar activation of titania” Energy Environ. Sci., 2014, 7(3), 954–966.（JCR 1区，IF= 29.5, 引用 124 次， ESI 1%高引论文）
12) G. Zhang, D. Monllor-Satoca, S. Lee, W. Choi*, “Band energy levels and compositions of CdS based solid solution and their relation with photocatalytic activities”. Catal. Sci. Technol. 2013, 3(7), 1790-1797. （JCR 2区，IF= 5.4）
11) G. Zhang, W. Choi*, “Low-cost sensitizer based on phenolic resin for charge-transfer type photocatalyst working under visible light” Chem. Commun. 2012, 48(86), 10621-10623. (Featured by RSC Chemistry World ) （JCR 1区，IF= 6.3）
10) G. Zhang, I. Y. Song, T. Park, W. Choi*, “Recyclable and stable ruthenium catalyst for free radical polymerization at ambient temperature initiated by visible light photocatalysis”. Green Chem. 2012, 14(3), 618-621. （JCR 1区， IF= 9.4）
9) G. Zhang, I. Y. Song, K. H. Ahn, T. Park, W. Choi*, “Free radical polymerization initiated and controlled by visible light photocatalysis at ambient temperature”. Macromolecules, 2011, 44(19), 7594-7599. （JCR 1区，IF=5.9, 引用 92 次）
8) G. Zhang, J. Yi, J. Shim, J. Lee, W. Choi*, “Photocatalytic hydroxylation of benzene to phenol over titanium oxide entrapped into hydrophobically modified siliceous foam”. Appl. Catal. B: Environ. 2011, 102(1-2), 132-139 （JCR 1区，IF= 9.4）
7) G. Zhang, W. Choi*, S. H. Kim, S. B. Hong, “Selective photocatalytic degradation of aquatic pollutants by titania encapsulated into FAU-type zeolites”. J. Hazard. Mater. 2011, 188(1-3), 195-205. （JCR 1区，IF=4.7）
6) J. Wang, T. Ma, G. Zhang, Z.H. Zhang, X.D. Zhang et al., “Preparation of novel nanometer TiO2 catalyst doped with upconversion luminescence agent and investigation on degradation of acid red B dye using visible light”. Catal. Commun. 2007, 8(3), 607-611. （JCR 3区，IF= 3.3）
5) J. Wang, G. Zhao, Z. Zhang, X. Zhang, G. Zhang, T. Ma, Y. Jiang, P. Zhang, Y. Li. Investigation on degradation of azo fuchsine using visible light in the presence of heat-treated anatase TiO2 powder. Dyes and Pigments 2007, 75, 335-343. （JCR 2区，IF= 3.4
4) J. Wang, T. Ma, Z. Zhang, X. Zhang, Y. Jiang, G. Zhang, G. Zhao, H. Zhao, Peng Zhang. Investigation on transition crystal of ordinary rutile TiO2 powder and its sonocatalytic activity. Ultrason. Sonochem. 2007, 14, 246-252. (JCR 2区，IF=3.8,）
3) J. Wang, Y. Jiang, Z. Zhang, X. Zhang, T. Ma, G. Zhang, G. Zhao, P. Zhang, Y. Li. Investigation on the sonocatalytic degradation of acid red B in the presence of nanometer TiO2 catalysts and comparison of catalytic activities of rutile and anatase TiO2 powders. Ultrason. Sonochem. 2007, 14, 545-551. （JCR 2区，IF= 3.8）
2) J. Wang, Y. Jiang, Z. Zhang, G. Zhao, G. Zhang, T. Ma, W. Sun, “Investigation on the sonocatalytic degradation of congo red catalyzed by nanometer rutile TiO2 powder and various influencing factors”Desalination, 2007, 216, 196. （JCR 2区，IF= 3.9）
1) J. Wang, G. Zhang, Z. Zhang, X.D. Zhang, G. Zhao., “Investigation on photocatalytic degradation of ethyl violet dyestuff using visible light in the presence of ordinary rutile TiO2 catalyst doped with upconversion luminescence agent”. Water Research. 2006, 40(11), 2143-2150. （JCR 1区，IF= 6.3）
2015- “Heliyon” 杂志编委会成员 (Elsevier)
2007- 期刊受邀审稿人 1. Journal of American Chemical Society (JACS)
2. Energy Environmental Science （RSC）
3. Advanced Functional Materials (Wiley)
4. Environment Science & Technology (JACS)
5. Chemical Communications (RSC)
6. Journal of Physical Chemistry C (Letter) (JACS)
7. Macromolecules (JACS)
8. Applied Catalysis B：Environmental (Elsevier)
9. Catalysis Science & Technology (RSC)
10. Journal of Hazardous Materials (Elsevier)
11. Water Research (Elsevier)