所受教育 · 1998年9月-2002年7月 维多利亚3308老品牌化学系学习,获学士学位 · 2002年9月-2007年7月 中国科学技术大学化学系硕博连读,获理学博士学位
职称职位 · 2007年7月-至今 维多利亚3308老品牌讲师,副教授 (2009年),教授 (2012年) · 2010年11月-至今 维多利亚3308老品牌物理化学专业硕士生导师(2010年),博士生导师(2014年) · 2009年8月-2011年2月 新加坡南洋理工大学 材料科学与工程学院 博士后 · 2016年1月-2021年3月 维多利亚3308老品牌 维多利亚3308老品牌 副院长 · 2021年3月-至今 维多利亚3308老品牌 学报编辑部 副主任
主持项目 1. 兼具活性位点及空间效应CO2RR电催化剂的构效关系研究,国家自然科学基金面上项目(No. 22176001),2022/01-2025/12,主持(在研) 2. 基于连续多级异质结构的全解水性能及其相界面电子转移机理研究,安徽省自然科学基金面上项目(2008085MB59),2020/07-2023/06,主持(在研) 3. 高能量密度车用超级电容器材料研发,安徽省科技攻关项目(1604a0902180),2017/01-2018/12,主持(已结题) 4. 柔性超级电容器电极的可控合成及电化学性能,国家自然科学基金面上项目(No. 2131007),2014/01-2017/12,主持(已结题) 5. 材料电化学,安徽省杰出青年基金(1408085J03),2014/01-2015/12,主持 (已结题) 6. 亚微米级碳包磷酸钒锂正极材料的可控合成及其电化学性能,安徽省教育厅重点项目(KJ2012A139),2012/01-2014/12,主持 (已结题) 7. 金属基复合材料电极的构建及其在肼类化合物中的检测应用,国家自然科学基金面上项目(No. 21073001),2011/01-2013/12,主持(已结题) 8. 金属基异质结构纳米材料的合成及其在糖尿病检测中的应用,国家自然科学基金青年项目(No.20901003),2010/01-2012/12,主持 (已结题)
研究领域 · 无机材料化学 · 电催化 · 锂离子电池、钠离子电池
讲授课程 · 物理化学 · 基础化学实验 · 综合化学实验 · 应用电化学(研究生) · 电极过程动力学(研究生)
指导学生获奖: 顾正翔:2015年研究生国家奖学金,2014年芜湖市专利大赛三等奖,校专利大赛二等奖,2015年度安徽省品学兼优毕业生 季 蓉:2013年研究生国家奖学金,2013年芜湖市专利大赛二等奖,校专利大赛一等奖,2013年研究生论文大赛一等奖,2012年研究生二等奖学金,2013年度安徽省品学兼优毕业生 汪玲玲:2012年研究生国家奖学金,2013年芜湖市专利大赛三等奖,校专利大赛二等奖 于刘涛:2012年芜湖市专利大赛特等奖,校专利大赛一等奖,2012年研究生一等奖学金
本人获奖: 7、化学国家级实验教学示范中心建设模式探索与成效,安徽省教学成果特等奖(排名第三)(2019年) 6、以学生为主体,以创新思维培养为目标,构建化学创新型人才培养新机制,安徽省教学成果一等奖(排名第一)(2019年) 5、维多利亚3308老品牌第五届青年教师讲课大赛一等奖 (2013年) 4、安徽省自然科学二等奖(排名第二) (2012年) 3、维多利亚3308老品牌第二届青年教师教学基本功大赛二等奖 (2012年) 2、维多利亚3308老品牌优秀教学三等奖 (2012年) 1、芜湖市首届大学生专利创新大赛 优秀指导教师 (2012年)
代表性论文: [30] Jiang L, Gu MZ, Wang H, Huang XM, Gao A, Sun P, Liu XD, Zhang XJ*, Synergistically Regulating the Electronic Structure by Cation and Anion for Efficient Overall Water Splitting, ChemSusChem, DOI:10.1002/cssc.202300592, 2023 [29] Lin M, Gu MZ, Deng XY, Xie Q*, Zhang XJ*, Interface engineered Ni3Se2/Ni3S2/NF heterostructure as a highly efficient electrocatalyst for robust oxygen evolution reaction, Chemical Engineering Journal, 468, 143705, 2023 [28] Wang H, Gu MZ, Huang XM, Gao A, Liu XD, Sun P, Zhang XJ*, Ligand-based modulation of the electronic structure at metal nodes in MOF to promote oxygen evolution reaction, Journal of Materials Chemistry A, 11, 7239–7245, 2023 [27] Pan ZH, Zhang XH, Xu ST, Gu MZ, Rui XH*, Zhang XJ*, Chloride-doping, defect and interlayer engineering of copper sulfide for superior sodium-ionbatteries, Journal of Materials Chemistry A, 11, 4102-4110, 2023 (Journal of Materials Chemistry A HOT Papers) [26] Jiang L, Gu MZ, Zhao SR, Wang H, Huang XM, Gao A,Zhu HL, Sun P, Liu XD, Lin HL, Zhang XJ*, Regulating the Active Sites of Metal–Phthalocyanine at the Molecular Level for Efficient Water Electrolysis: Double Deciphering of Electron-Withdrawing Groups and Bimetallic, Small, 19, 202207243, 2023 [25] Gu MZ, Jiang L, Zhao SR, Wang H, Lin M, Deng XY, Huang XM, Gao A, Liu XD, Sun P, Zhang XJ*, Deciphering the Space Charge Effect of the p-n Junction between Copper Sulfides and Molybdenum Selenides for Efficient Water Electrolysis in a Wide pH Range, ACS Nano, 16, 15425−15439, 2022 [24] Gu MZ, Deng XY, Lin M, Wang H, Gao A, Huang XM, Zhang XJ*, Ultrathin NiCo Bimetallic Molybdate Nanosheets Coated CuOx Nanotubes: Heterostructure and Bimetallic Synergistic Optimization of the Active Site for Highly Efficient Overall Water Splitting, Advanced Energy Materials, 11, 2102361, 2021(Front Cover Paper) [23] Chen J, Gu MZ, Liu SJ, Sheng T, Zhang XJ*, Iron Doped in the Subsurface of CuS Nanosheets by Interionic Redox: Highly Effiffifficient Electrocatalysts toward the Oxygen Evolution Reaction, ACS Applied Materials & Interfaces, 13, 16210−16217, 2021 [22] Zhou, YP, Zhang, XH, Liu, YJ, Xie, XX, Rui, XH*, Zhang, X, Feng, YZ, Zhang, XJ*, Yu, Y*, Huang, KM, A High-Temperature Na-Ion Battery: Boosting the Rate Capability and Cycle Life by Structure Engineering, Small, 16, 1906669, 2020 [21] Cai GH, Peng L, Ye SY, Huang YC, Wang GF*, Zhang XJ*, Defect-rich MoS2(1-x)Se2x few-layer nanocomposites: a superior anode material for high-performance lithium-ion batteries, Journal of Materials Chemistry A, 7, 9837-9843, 2019 [20] Ding MM, Chen J, Jiang MW, Wang GF*, Zhang XJ*, Ultrathin trimetallic metal–organic framework nanosheets for highly efficient oxygen evolution reaction, Journal of Materials Chemistry A, 7, 14163-14168, 2019 [19] Zheng XT, Ye YL,Yang Q, Geng BY, Zhang XJ*, Ultrafine nickel-copper carbonate hydroxide hierarchical nanowire networks for high-performance supercapacitor electrodes, Chemical Engineering Journal, 290, 353-360, 2016 [18] Hu, QQ, Gu ZX, Zheng XT, Zhang XJ*, Three-dimensional Co3O4@NiO hierarchical nanowire arrays for solid-state symmetric supercapacitor with enhanced electrochemical performances, Chemical Engineering Journal, 304, 223-231, 2016 [17] Gu ZX, Zhang XJ*, NiCo2O4@MnMoO4 core-shell flowers for high performance supercapacitors, Journal of Materials Chemistry A, 4, 8249-8254, 2016 [16] Gu ZX, Nan HH, Geng BY, Zhang XJ*, Construction of unique Co3O4@CoMoO4 Core/Shell Nanowire Arrays on Ni Foam by action exchange method for Electrochemical Energy Storage, Journal of Materials Chemistry A, 3, 14578-14584, 2015 (Front Cover Paper) [15] Gu ZX, Nan HH, Geng BY, Zhang XJ*, Three-Dimensional NiCo2O4@NiMoO4 Core/Shell Nanowire for Electrochemical Energy Storage, Journal of Materials Chemistry A, 3, 12069–12075, 2015 [14] Ma WQ, Nan HH, Gu ZX, Geng BY, Zhang XJ*, Superior Performance Asymmetric Supercapacitors Based on ZnCo2O4@MnO2 Core-shell Electrode, Journal of Materials Chemistry A, 3, 5442–5448, 2015 [13] Zhu YH, Wang GF*, Jiang H, Chen L, Zhang XJ*, One-step ultrasonic synthesis of graphene quantum dots with high quantum yield and its application in sensing of alkaline phosphatase, Chemical Communications, 51, 948-951, 2015 [12] Wang GF, Xu G, Zhu YH, Zhang XJ*, A “Turn-on” Carbon nanotube-Ag Nanoclusters Fluorescent Sensor for Sensitive and Selective Detection of Hg2+ with Cyclic Amplification of Exonuclease III Activity, Chemical Communications 50, 747-750, 2014 [11] Ji R, Wang LL, Yu LT, Geng BY, Wang GF*, Zhang XJ*, Effective Electrocatalysis Based on Ag2O Nanowire Arrays Supported on Cu Substrate, ACS Applied Materials & Interfaces 5, 10465-10472, 2013 [10] Wang GF, Gu AX, Huang Y, Fang B, Geng BY, Zhang XJ*, Non-enzymatic Electrochemical Sensing of Glucose, Microchimica Acta 180, 161-186, 2013 (Invited Review) [9] Zhang XJ, Shi WH, Zhu JX, Kharistal DJ, Zhao WY, Lalia BS, Hng HH*, Yan QY*, High-Power and High-Energy-Density Flexible Pseudocapacitor Electrodes Made from Porous CuO Nanobelts and SWCNTs, ACS Nano 3, 2013-2019, 2011 [8] Zhang XJ, Lu ZY, Sim DH, Li SZ, Feng YH, Ma J, Chen HY, Boey F, Hng HH*, Yan QY*, Controllable Ag/Ag/Carbon Hybrid Nanostructures for Surface-Enhanced Raman Scattering, Chemistry-A European Journal 17, 13386-13390, 2011 [7] Zhang XJ, Shi WH, Zhu JX, Zhao WY, Ma J, Mhaisalkar S, Maria TL, Yang YH, Hng HH*, Yan QY*, Synthesis of Porous NiO Nanocrystals with Controllable Surface Area and Their Application as Supercapacitor Electrodes, Nano Research 3, 643-652, 2010 [6] Fang B*, Gu AX, Wang GF, Wang W, Feng YH, Zhang CH, Zhang XJ*, Silver Oxide Nanowalls grown on Cu Substrate as an Enzymeless Glucose Sensor, ACS Applied Materials & Interfaces 1, 2829-2834, 2009 [5] Zhang XJ*, Wang GF, Zhang W, Wei Y, Fang B, Fixure-reduce Method for the Synthesis of Cu2O/MWCNTs Nanocomposites and Its Application as Enzyme-free Glucose Sensor, Biosensors & Bioelectronics 24, 3395-3398, 2009 [4] Zhang XJ*, Wang GF, Gu AX, Wei Y, Fang B, CuS Nanotube for Ultrasensitive Nonenzymatic Glucose Sensors, Chemical Communications 45, 5945-5947, 2008 [3] Zhang XJ*, Wang GF, Liu XW, Wu HQ, Fang B, Copper Dendrites: Synthesis, Mechanism Discussion, and Application in Determination of L-Tyrosine, Crystal Growth & Design 8, 1430, 2008 [2] Zhang XJ*, Wang GF, Zhang W, Hu NJ, Wu HQ, Fang B, Seed-Mediated Growth Method for Epitaxial Array of CuO Nanowires on Surface of Cu Nanostructures and Its Application as a Glucose Sensor, The Journal of Physical Chemistry C 112, 8856, 2008 [1] Zhang XJ*, Wang GF, Liu XW, Wu JJ, Li M, Gu J, Fang B, Different CuO Nanostructures: Synthesis, Characterization, and Applications for Glucose Sensors, The Journal of Physical Chemistry C 112, 16845, 2008 |