张霞光，博士

邮箱：zhangxiaguang@htu.edu.cn

教育经历：

2015.09-2019.06厦门大学 物理化学专业 理学博士

2012.09-2015.07西南大学 物理化学专业 理学硕士

2008.09-2012.06安阳师范学院 化学专业 理学学士

2019.08至今 betway官方app 化学化工学院物理化学研究所

主讲课程：

结构化学（本科生），分子模拟方法（研究生）,物理化学实验（本科生）

研究方向：

理论计算化学、电化学、光谱学和化学反应机理

科研项目：

1. 国家自然科学基金-青年项目，主持

2. 河南省自然科学基金-青年项目，主持

3. 固体表面物理化学国家重点实验室开放课题，主持

科研论文：

2023年

[58] Chao Zhan*, Jun Yi, Shu Hu,Xia-Guang Zhang, De-Yin Wu, and Zhong-Qun Tian*, Plasmon-mediated chemical reactions,Nat. Rev. Methods Primers2023, 3, 12.

[57]Xia-Guang Zhang*, Yu Zhao, Si Chen, Shu-Ming Xing, Jin-Chao Dong*, and Jian-Feng Li*, Electrolyte effect for carbon dioxide reduction reaction on copper electrode interface: A DFT prediction,J. Chem. Phys.2023, 158, 094704.

[56] Qiong Liu†,Xia-Guang Zhang†, Zi-Yu Du†, Can-Jun Zou, Huan-Yu Chen, Yu Zhao, Jin-Chao Dong, Ping-Ping Fang*, and Jian-Feng Li*, Converting CO2 to ethanol on Ag nanowires with high selectivity investigated by operando Raman spectroscopy,Sci. China Chem.2023, 66, 259-265.(共同第一作者)

[55] Li Lin+, Xiaoyang He+,Xia-Guang Zhang+, Wenchao Ma, Biao Zhang, Diye Wei, Shunji Xie*, Qinghong Zhang, Xiaodong Yi, and Ye Wang*, A Nanocomposite of Bismuth Clusters and Bi2O2CO3 Sheets for Highly Efficient Electrocatalytic Reduction of CO2 to Formate,Angew. Chem. Int. Ed.2023, 62, e202214959.(共同第一作者)

[54] Jia-Li Chen,Xia-Guang Zhang, and De-Yin Wu*, Dissociation reactions of hydrogen molecules at active sites on gold clusters: A DFT study,J. Chin. Chem. Soc.https://doi.org/10.1002/jccs.202200392

[53] Huaizhou Jin, Jing-Yu Wang,Xia-Guang Zhang, Weiyi Lin, Weiwei Cai, Yue-Jiao Zhang*, Zhi-Lin Yang, Fan-Li Zhang*, and Jian-Feng Li,Nano Res.https://doi.org/10.1007/s12274-022-5209-2

2022年

[52] Hong Li, Xianxian Qin,Xia-Guang Zhang, Kun Jiang*, and Wen-Bin Cai*, Boron-Doped Platinum-Group Metals in Electrocatalysis: A Perspective,ACS Catal.2022, 12, 12750−12764.

[51]Xia-Guang Zhang* and Jin-Hui Zhong*, Correlating the orbital overlap area and vibrational frequency shift of an isocyanide moiety adsorbed on Pt and Pd covered Au(111) surfaces,Phys. Chem. Chem. Phys.2022, 24, 23301–23308.

[50] Zijie Mao, Yicai Wu, Xian-Yin Ma, Li Zheng,Xia-Guang Zhang,* and Wen-Bin Cai*, In Situ Wide-Frequency Surface-Enhanced Infrared Absorption Spectroscopy Enables One to Decipher the Interfacial Structure of a Cu Plating Additive,J. Phys. Chem. Lett.2022, 13, 9079−9084.

[49] Yu Zhao,‡Xia-Guang Zhang,‡ Nataraju Bodappa,‡ Wei-Min Yang, Qian Liang, Petar M. Radjenovica, Yao-Hui Wang, Yue-Jiao Zhang, Jin-Chao Dong,* Zhong-Qun Tian, and Jian-Feng Li*, Elucidating electrochemical CO2reduction reaction processes on Cu(hkl) single-crystal surfaces by in situ Raman spectroscopy,Energy Environ. Sci.2022, 15, 3968–3977.(共同第一作者)

[48] Zijie Mao,# Chen Ding,# Xuan Liu, Qing Zhang, Xianxian Qin, Hong Li, FanYang, Qing Li,*Xia-Guang Zhang,* Junliang Zhang, and Wen-Bin Cai*, Interstitial B-Doping in Pt Lattice to Upgrade Oxygen Electroreduction Performance,ACS Catal.2022, 12, 8848−8856.

[47] Xiu-Mei Lin, Xiao-Ting Wang, Yong-Liang Deng, Xing Chen, Hao-Ning Chen, Petar M. Radjenovic,Xia-Guang Zhang, Yao-Hui Wang,* Jin-Chao Dong,* Zhong-Qun Tian, and Jian-Feng Li*, In Situ Probe of the Hydrogen Oxidation Reaction Intermediates on PtRu a Bimetallic Catalyst Surface by Core–Shell Nanoparticle-Enhanced Raman Spectroscopy,Nano Lett.2022, 22, 5544−5552.

[46] Biao-Feng Zeng,‡ Jun-Ying Wei,‡Xia-Guang Zhang,‡ Qing-Man Liang, Shu Hu, Gan Wang, Zhi-Chao Lei, Shi-Qiang Zhao, He-Wei Zhang, Jia Shi, Wenjing Hong, Zhong-Qun Tian and Yang Yang*, In situ lattice tuning of quasi-single-crystal surfaces for continuous electrochemical modulation,Chem. Sci.2022, 13, 7765–7772.(共同第一作者)

[45] Yongkui Chen, Jikuan Qiu,Xia-Guang Zhang, Huiyong Wang, Wenhui Yao, Zhiyong Li, Qingchun Xia, Guangshan Zhu* and Jianji Wang *, A visible light/heat responsive covalent organic framework for highly efficient and switchable proton conductivity,Chem. Sci.2022, 13, 5964–5972.

[44] Shichao Lin+, Huajie Ze+,Xia-Guang Zhang, Yue-Jiao Zhang, Juan Song, Huimin Zhang, Han-Liang Zhong, Zhi-Lan Yang, Chaoyong Yang, Jian-Feng Li, and Zhi Zhu*, Direct and Simultaneous Identification of Multiple Mitochondrial Reactive Oxygen Species in Living Cells Using a SERS Borrowing Strategy,Angew. Chem. Int. Ed.2022, 61, e202203511.

[43] Jing-Liang Yang+, Hong-Jia Wang+, Zhenwei Zhu+, Mu-Fei Yue, Wei-Min Yang,Xia-Guang Zhang, Xiangyu Ruan, Zhiqiang Guan, Zhi-Lin Yang, Weiwei Cai, Yuan-Fei Wu, Feng-Ru Fan,* Jin-Chao Dong,* Hua Zhang, Hongxing Xu, Zhong-Qun Tian, and Jian-Feng Li*,Angew. Chem. Int. Ed.2022, 61, e20211274.

2021年

[42] Jing Zhang,Xia-Guang Zhang, Jin-Chao Dong, Petar M. Radjenovic, David James Young, Jian-Lin Yao*, Ya-Xian Yuan*, Zhong-Qun Tian, and Jian-Feng Li*, Real-Time Monitoring of Surface Effects on the Oxygen Reduction Reaction Mechanism for Aprotic Na–O2Batteries,J. Am. Chem. Soc.2021, 143, 20049−20054.

[41] Wei-Qiong Li, Ru-Yu Zhou, Xiao-Ting Wang, Ling-Yun Hu, Xing Chen, Peng-Cheng Guan,Xia-Guang Zhang, Hua Zhang*, Jin-Chao Dong*, Zhong-Qun Tian, Jian-Feng Li*, Identification of the molecular pathways of RuO2electroreduction by in-situ electrochemical surface-enhanced Raman spectroscopy,J. Catal.2021,400, 367–371.

[40] Zhenzhen Wang, Zhiyong Li,*Xia-Guang Zhang, Qingchun Xia, Huiyong Wang, Chenlu Wang, Yanlei Wang, Hongyan He, Yang Zhao, and Jianji Wang*, Tailoring Multiple Sites of Metal–Organic Frameworks for Highly Efficient and Reversible Ammonia Adsorption,ACS Appl. Mater. Interfaces2021, 13, 56025−56034.

[39] Bing Chang,Xia-Guang Zhang, Zhaojun Min, Weiwei Lu, Zhiyong Li, Jikuan Qiu, Huiyong Wang, Jing Fan* and Jianji Wang*, Efficient electrocatalytic conversion of CO2to syngas for the Fischer–Tropsch process using a partially reduced Cu3P nanowire,J. Mater. Chem. A2021, 9, 17876–17884.

[38]Hong Li, Tian-Wen Jiang, Xianxian Qin, Jie Chen, Xian-Yin Ma, Kun Jiang,Xia-Guang Zhang,* and Wen-Bin Cai* Selective Reduction of CO2 to CO on an Sb-Modified Cu Electrode: Spontaneous Fabrication and Physical Insight,ACS Catal.2021, 11, 6846−6856.

[37]Zixi Lyu†,Xia-Guang Zhang†, Yucheng Wang, Kai Liu, Chunyu Qiu, Xinyan Liao,Weihua Yang, Zhaoxiong Xie, and Shuifen Xie* Amplified Interfacial Effect in an Atomically Dispersed RuOx-on-Pd 2D Inverse Nanocatalyst for High-Performance Oxygen Reduction,Angew. Chem. Int. Ed.2021, 60, 16093–16100.(共同第一作者)

[36] Xia-Guang Zhang,* Lei Zhang, Shishi Feng, Haimei Qin, De-Yin Wu,* and Yi Zhao* Light Driven Mechanism of Carbon Dioxide Reduction Reaction to Carbon Monoxide on Gold Nanoparticles: A Theoretical Prediction,J. Phys. Chem. Lett.2021, 12, 1125−1130.

[35] Huajie Ze, Xing Chen, Xiao-Ting Wang, Yao-Hui Wang, Qing-Qi Chen, Jia-Sheng Lin, Yue-Jiao Zhang,*Xia-Guang Zhang,* Zhong-Qun Tian, and Jian-Feng Li* Molecular Insight of the Critical Role of Ni in Pt-Based Nanocatalysts for Improving the Oxygen Reduction Reaction Probed Using anIn SituSERS Borrowing Strategy, J. Am. Chem. Soc.2021, 143, 3, 1318–1322.

[34] Yao-Hui Wang†, Xiao-Ting Wang†, Huajie Ze†,Xia-Guang Zhang, Petar M. Radjenovic, YueJiao Zhang,* Jin-Chao Dong,* Zhong-Qun Tian, and Jian-Feng Li* Spectroscopic Verification of Adsorbed Hydroxy Intermediates in the Bifunctional Mechanism of the Hydrogen Oxidation Reaction,Angew. Chem. Int. Ed.2021, 60, 5708–5711.

[33]Sheng Lin, He Ren, Zhi Wu, Lan Sun*,Xia-Guang Zhang, Yu-Mei Lin, Kelvin H. L. Zhang, Chang-Jian Lin, Zhong-Qun Tian, Jian-Feng Li* Direct Z-scheme WO3-x nanowire-bridged TiO2 nanorod arrays for highly efficient photoelectrochemical overall water splitting,Journal of Energy Chemistry2021,59,721-729.

2020年

[32] Biao-Feng Zeng, Gan Wang, Qiao-Zan Qian, Zhi-Xin Chen,Xia-Guang Zhang, Zhi-Xing Lu, Shi-Qiang Zhao, An-Ni Feng, Jia Shi, Yang Yang*, Wenjing Hong, Selective Fabrication of Single-Molecule Junctions by Interface Engineering,Small2020, 16, 2004720.

[31]Xia-Guang Zhang*, Shishi Feng, Chao Zhan, De-Yin Wu*, Yi Zhao*, Zhong-Qun Tian, Electroreduction Reaction Mechanism of Carbon Dioxide toC2Products via Cu/Au Bimetallic Catalysis: A Theoretical Prediction,J. Phys. Chem. Lett.2020, 11, 6593-6599.

[30] Zichao Yan, Yaru Liang, Weibo Hua,Xia-Guang Zhang, Weihong Lai, Zhe Hu, Wanlin Wang, Jian Peng, Sylvio Indris, Yunxiao Wang*, Shu-Lei Chou*, Huakun Liu, Shi-Xue Dou, Multiregion Janus-Featured Cobalt Phosphide-Cobalt Composite for Highly Reversible Room-Temperature Sodium-Sulfur Batteries,ACS Nano2020, 14, 10284-10293.

[29] Bao-Yin Wen, Jia-Shen Lin, Yue-Jiao Zhang, Petar M.Radjenovic,Xia-Guang Zhang*, Zhong-Qun Tian, Jian-Feng Li*,Probing Electric Field Distributions in the Double Layer of a Single-Crystal Electrode with Angstrom Spatial Resolution Using Raman Spectroscopy.J. Am. Chem. Soc.2020,142, 11698-11702.

[28] Hua Zhang, Jie Wei,Xia-Guang Zhang, Yue-Jiao Zhang,Petar M.Radjenovic,De-Yin Wu, Feng Pan, Zhong-Qun Tian, Jian-Feng Li*,Plasmon-Induced Interfacial Hot-Electron Transfer Directly Probed by Raman Spectroscopy.Chem2020,6, 689-702.

[27]Wei-YuYang, Jueting Zheng,Xia-Guang Zhang, Li-Chuan Chen, Yu Si, Fei-Zhou Huang*, Wengjing Hong*,Charge Transport through a Water-Assisted Hydrogen Bond in Single-Molecule Glutathione Disulfide Junctions,J. Matter. Chem. C2020, 8, 481-486.

[26]Hai-ShengSu, Hui-Shu Feng, Qing-Qing Zhao,Xia-Guang Zhang, Juan-Juan Sun, Yuhan He, Sheng-Chao Huang, Teng-Xiang Huang, Jin-Hui Zhong*, De-Yin Wu, Bin Ren*, Probing the Local Generation and Diffusion of Active Oxygen Species on a Pd/Au Bimetallic Surface by Tip-Enhanced Raman Spectroscopy.J. Am. Chem. Soc.2020,142, 1341-1347.

2019年

[25] Shuai Tang,Xia-Guang Zhang, Xue-Yang Cui, Hong-Yu Xu, De-Yin Wu, Jia-Wei Yan, Ming-Shen Zheng, Quan-Feng Dong*, Bing-Wei Mao,Mitigating Concentration Polarization for Highly Reversible Plating/Stripping Electrochemistry: Li Versus Na.J. Mater. Chem. A2019,7, 23216-23224.

[24]Chao Zhan†, Gan Wang†,Xia-Guang Zhang, Zhi-Hao Li, Jun-Ying Wei, Yu Si, Yang Yang*, Wenjing Hong*, Zhong-Qun Tian, Sing-molecule Measurement of Adsorption Free Energy at the Solid-Liquid Interface,Angew. Chem. Int. Ed.,2019,58, 14534-14538.

[23]Shuai Tang, Yi-Yang Zhang,Xia-Guang Zhang, Jun-Tao Li, Xue-Yin Wang, Jia-Wei Yan, De-Yin Wu, Ming-Sen Zheng, Quan-Feng Dong*, Bing-Wei Mao*. Stable Na Plating and Stripping Electrochemistry Promoted by In Situ Construction of an Alloy-Based Sodiophilic Interphase.Adv. Mater., 2019, 31 (16), 1807495.

[22]Xia-Guang Zhang, Yuxiu Liu, Chao Zhan, Xi Jin, Qijin Chi, De-Yin Wu*, Yi Zhao*, Zhong-Qun Tian. Reaction Selectivity for Plasmon-Driven Carbon Dioxide Reduction on Silver Clusters: A Theoretical Prediction.J. Phys. Chem. C, 2019, 123 (17), 11101−11108.

[21]Chao Zhan, Zi-Yuan Wang,Xia-Guang Zhang, Xue-Jiao Chen, Yi-Fan Huang, Shu Chen, Jian-Feng Li, De-Yin Wu*, Martin Moskovits, Zhong-Qun Tian*. Interfacial Construction of Plasmonic Nanostructures for the Utilization of the Plasmon-Excited Electrons and Holes.J. Am. Chem. Soc., 2019, 141 (20), 8053−8057.

[20]Yu Gu†, Hong-Yu Xu†,Xia-Guang Zhang†, Wei-Wei Wang, Jun-Wu He, Shuai Tang, Jia-Wei Yan, De-Yin Wu*, Ming-Sen Zheng, Quan-Feng Dong, Bing-Wei Mao*. Lithiophilic Faceted Cu(100) Surfaces: High Utilization of Host Surface and Cavities for Lithium Metal Anodes.Angew. Chem. Int. Ed., 2019, 58 (10), 3092–3096.(共同第一作者)

[19] Wenchao Ma†, Shunji Xie†,Xia-Guang Zhang†, Fanfei Sun, Jincan Kang, Zheng Jiang, Qinghong Zhang*, De-Yin Wu*, Ye Wang*. Promoting Electrocatalytic CO2Reduction to Formate via Sulfur-Boosting Water Activation on Indium Surfaces.Nat. Commun., 2019, 10, 892.(共同第一作者)

[18] Jin-Chao Dong,Xia-Guang Zhang, Valentín Briega-Martos, Xi Jin, Ji Yang, Shu Chen, Zhi-Lin Yang, De-Yin Wu, Juan Miguel Feliu*, Christopher T. Williams, Zhong-Qun Tian, Jian-Feng Li*, In Situ Raman Spectral Evidence for Oxygen Reduction Reaction Intermediates at Platinum Single-Crystal Surfaces.Nature Energy, 2019, 4, 60–67.

2018年

[17]Xia-Guang Zhang, Xi Jin, De-Yin Wu*, Zhong-Qun Tian. Selective Electrocatalytic Mechanism of CO2Reduction Reaction to CO on Silver Electrodes: A Unique Reaction Intermediate.J. Phys. Chem. C, 2018, 122 (44), 25447–25455.

[16] Hai-Sheng Su†,Xia-Guang Zhang†, Juan-Juan Sun, Xi Jin, De-Yin Wu, Xiao-Bing Lian, Jin-Hui Zhong*, Bin Ren*. Real-Space Observation of Atomic Site-Specific Electronic Properties of a Pt Nanoisland/Au(111) Bimetallic Surface by Tip-Enhanced Raman Spectroscopy.Angew. Chem. Int. Ed., 2018, 57 (40), 13177–13181(共同第一作者)

[15]Shuai Tang, Zhi Qiu, Xue-Yin Wang, Yu Gu,Xia-Guang Zhang, Wei-Wei Wang, Jia-Wei Yan, Ming-SenZheng*, Quan-Feng Dong, Bing-Wei Mao*.A Room-Temperature Sodium Metal Anode Enabled by a Sodiophilic Layer.Nano Energy, 2018, 48, 101–106.

[14]Jia-Jia Chen, Jian-Chuan Ye,Xia-Guang Zhang, Mark D. Symes, Shao-Cong Fan, De-Liang Long, Ming-Sen Zheng, De-Yin Wu, Leroy Cronin*, Quan-Feng Dong*. Design and Performance of Rechargeable Sodium Ion Batteries, and Symmetrical Li-Ion Batteries with Supercapacitor-Like Power Density Based upon Polyoxovanadates.Adv. Energy Mater., 2018, 8 (6), 1701021.

[13]Chao-Yu Li†, Jin-Hong Gao†, Jun Yi†,Xia-Guang Zhang, Xiao-Dan Cao, Meng Meng, Chen Wang, Ya-Ping Huang, San-Jun Zhang, De-Yin Wu, Chuan-Liu Wu*, Jian-Hua Xu, Zhong-Qun Tian, Jian-Feng Li*. Plasmon-Enhanced Ultrasensitive Surface Analysis Using Ag Nanoantenna.Anal. Chem., 2018, 90 (3), 2018−2022.

[12]Bei Jiang,Xia-Guang Zhang, Kun Jiang, De-Yin Wu*, Wen-Bin Cai*. Boosting Formate Production in Electrocatalytic CO2Reduction over Wide Potential Window on Pd Surfaces.J. Am. Chem. Soc., 2018, 140 (8), 2880−2889.

[11]Chen Jia-li,Zhang Xia-guang, Wu De-yin*, Tian Zhong-qun. DFT Study of Water Assisted Hydrogen Dissociation on Gold Nanoparticles.J. Electrochem., 2018, 24 (3), 199–206.

2017 年

[10]Hua Zhang,Xia-Guang Zhang, Jie Wei, Chen Wang, Shu Chen, Han-Lei Sun, Ya-Hao Wang, Bing-Hui Chen*, Zhi-Lin Yang, De-Yin Wu, Jian-Feng Li*, Zhong-Qun Tian. Revealing the Role of Interfacial Properties on Catalytic Behaviors by in Situ Surface-Enhanced Raman Spectroscopy.J. Am. Chem. Soc., 2017, 139 (30), 10339−10346.

[9]Ran Pang*,Xia-Guang Zhang, Jian-Zhang Zhou*, De-Yin Wu*, Zhong-Qun Tian. SERS Chemical Enhancement of Water Molecules from Halide Ion Coadsorption and Photoinduced Charge Transfer on Silver Electrodes.J. Phys. Chem. C, 2017, 121 (19), 10445–10454.

[8]Li-Kun Yang*,Xia-Guang Zhang, Fang-Zu Yang*, De-Yin Wu*, Xiang-Yang Liu, Zhong-Qun Tian. Competing Mechanisms in the Acetaldehyde Functionalization of Positively Charged Hydrogenated Silicene.ChemPhysChem, 2017, 18 (3), 281–286.

2016年

[7]Yong Chen†, Jia-Qiang Ren†,Xia-Guang Zhang, De-Yin Wu, Ai-Guo Shen*, Ji-Ming Hu*. Alkyne-Modulated Surface-Enhanced Raman Scattering-Palette for Optical Interference-Free and Multiplex Cellular Imaging.Anal. Chem., 2016, 88 (12), 6115−6119.

[6]Run-Wen Yan, Xi Jin, Si-Yuan Guan,Xia-Guang Zhang, Ran Pang, Zhong-Qun Tian, De-Yin Wu*, Bing-Wei Mao*. Theoretical Study of Quantum Conductance of Conjugated and Nonconjugated Molecular Wire Junctions.J. Phys. Chem. C, 2016, 120 (22), 11820−11830.

[5]Dongmei Zhang, Wei Shen,Xiaguang Zhang, Huili Sun, Rongxing He, Ming Li*. Rational Design of Carbazolyl and Aryl Phosphine Oxide (APO) Based Ambipolar Host Materials for Blue Electrophosphorescence: A Density Functional Theory Study.RSC Adv., 2016, 6 (42), 35416–35424.

2015年

[4] Huili Sun, Wei Shen,Xiaguang Zhang, Dongmei Zhang, Ming Li*. Theoretical Investigations of the Electronic Structures of Carbazole-Based Triphenylphosphine Oxide Derivatives, Potential Bipolar Host Materials in Blue-Phosphorescent Devices.J. Mol. Model., 2015, 21, 320.

[3]Xiaguang Zhang, Wei Shen, Dongmei Zhang, Yongzhen Zheng, Rongxing He, Ming Li*. Theoretical Investigation of Dihydroacridine and Diphenylsulphone Derivatives as Thermally Activated Delayed Fluorescence Emitters for Organic Light-Emitting Diodes.RSC Adv., 2015, 5 (64), 51586–51591.

[2]Xiaguang Zhang, Wei Shen, Huili Sun, Rongxing He, Ming Li*. Identifying Efficient Blue-Phosphorescent Polymer Light-Emitting Diode Host Materials Based on Carbazole Derivatives with C/Si-Centered Substituents using Density Functional Theory.J. Mol. Model., 2015, 21, 178.

[1]Xiaguang Zhang, Wei Shen, Huili Sun, Pei Yu, Rongxing He, Ming Li*. The DFT Study on Non-Conjugated Polymer Host Materials Based on Styrene Derivatives for Phosphorescent Polymer Light-Emitting Diodes.J. Phys. Org. Chem., 2015, 28 (8), 554–563.