教育背景
2009-03 至 2013-07, 香港大学,化学,博士
1999-09 至 2003-07, 中国科学技术大学,材料科学与工程,学士
工作履历
2018-09 至 今, 中山大学,材料学院,副教授
2021-05 至 2024-02, 深圳综合粒子设施研究院(借调),正高级工程师/组长
2016-02 至 2018-08, 法兰西公学院(CollegedeFrance),博士后
2013-10 至 2016-01, 日本理化学研究所(RIKEN),博士后
2003-09 至 2009-01, 美国北卡罗来纳州立大学, 化学系, 助理研究员
研究方向
致力于发展和利用先进实验室及同步辐射X射线表征技术,解析能源材料的动态结构演化过程与反应机制。研究兴趣包括:
(1)实验室X射线装置及原位环境实验装置研制;
(2)电池热失控反应机理(XRD-OMS联用、XAFS、TXM);
(3)电池材料结构演化机制(PDF、TR-XRD、SAXS);
(4)水系碱性电池无损检测(CT);
(5)熔盐电化学原位X射线表征技术开发及应用(XAFS,μ-CT);
主持国家自然科学基金面上项目(1项)、深圳市自然科学基金面上项目(1项)、参与科技部重点研发计划仪器专项、深圳市重点产业研发计划项目、香港创新及科技基金(ITF)。为多家上市企业提供同步辐射表征测试及数据分析,主持企业横向课题7项。申请原位反应装置和X射线技术相关发明专利60余项。在包括 J. Am. Chem. Soc., Adv. Mater., Angew. Chem.Int. Ed., Nat. Commun., Nano Lett.等杂志发表论文80余篇,出版中英文学术专著2章节。
主讲课程
《物质结构》《物理化学实验》
学术成果
【主持科研项目】
纵向项目:
1.深圳市科技创新局,深圳市重点产业研发计划(ZDCY20250901113703004),“重202510005熔盐体系乏燃料后处理关键核素分离技术研究”,2026-01 至 2028-12,课题负责人,125/1000万元
2.国家科学技术部,国家重点研发计划基础科研条件与重大科学仪器设备研发重点专项项目(2023YFF0716100),“X射线吸收精细结构波谱分析仪”,2023-12 至 2026-11,子课题负责人,40/1000万元
3.深圳市科技创新委员会,深圳市基础研究专项-面上项目(JCYJ20220530150011024),“高效稳定非晶催化剂的活性结构表征与动态催化机理研究”,2022-10 至 2025-10,主持,30万元
4.国家自然科学基金委,面上项目(21972172),“原位表征阳离子脱嵌调控的电化学-化学复合催化过程及其在析氧反应中的应用”,2020-01 至2023-12,主持,65万
横向项目:
1.境外横向项目,香港GP Technology & Innovation Limited,“碱性Ni-Zn电池性能衰退机制研究和稳定性策略开发”,2025-07 至 2027-06,主持,60万元
2.企业横向项目,“材料PDF测试开发”,2025-04 至2026-04,主持,30万元
3.企业横向项目,“高镍正极升温过程中相变与释氧的反应时序性研究”,2025-07 至 2025-09,主持,30万元
4.企业横向项目,“快时间分辨X 射线衍射技术研究锂离子电池富镍 NCM 材料结构演化机制”,2023-08 至2025-07,主持,15万元
国际合作项目:
1.香港创新科技署(HK ITC),香港创新科技基金(HK ITF)企业支援计划(ESS),项目号B/E015/22,“Development of Rechargeable Ni-Zn Alkaline Batteries with High Energy Density and Long Cycle Life”,2023-06 至 2025-05,课题负责人,65/870万元
【近期学术论文】
第一作者、通讯作者:
[1]Wang, J.; Gu, L.; Wang, C.; Zou, Q.; Li, W.; Zhao, N.; Su, W.; Zhang, Y.; Li, M.; Yang, H. Y.; Yang, C.*, Impact of cation dopant on superstructure and anionic redox properties in Li-ion battery. J. Colloid Interface Sci.2026,702 (Pt 2), 138987.
[2]Wang, C.; Zhang, Y.; Li, Z.; Wang, J.; Zeng, H.; Chen, J.; Liu, Y.; Li, M.; Wang, S.; Yang, C.*, A comprehensive understanding of the structural evolution and capacity contribution of fast-charging NCM cathodes. J. Energy Chem.2026,114, 183-193.
[3]Li, P.; Zou, Q.; Liu, H.; Zhou, W.; Wang, C.; Zhang, Y.; Deng, L.; Li, C.-Y. V.; Yang, C.*, LLZTO ceramic particles regulate in situ polymerization of hybrid electrolytes and enable stable cycling of Li metal batteries. Chem. Eng. J. 2026,531.
[4]Zeng, H.; Hong, E.; Li, P.; Deng, L.; Liu, H.; Pan, J.; Gu, L.; Chen, J.; Gao, L.; Yang, C.*, Enhanced Electrochemical Performance and Membrane Stability of a Hybrid Alkali-Acid Urea Electrolyzer. ACS Sustainable Chem. Eng. 2025,13 (9), 3423-3431.
[5]Wang, J.; Gu, L.; Wang, C.; Zhang, Y.; Su, W.; Xu, Y.; Li, W.; Yang, H. Y.; Yang, C.*, Regulating cation ordering in lithium-rich layered cathodes for enhanced anionic redox reactions. Nano Energy2025,136.
[6]Wang, J.; Gu, L.; Wang, C.; Su, W.; Zhang, Y.; Zeng, H.; Deng, L.; Li, X.; Li, W.; Yang, H. Y.; Yang, C.*, Temperature-controlled construction of honeycomb-ordered structure in layered Li2Ir0.6Ni0.4O3 to enhance the anionic redox activity and stability. Chem. Eng. J. 2025,504.
[7]Wang, J.; Gu, L.; Chen, W.; Su, W.; Wang, C.; Zhang, Y.; Chen, J.; Song, H.; Li, Y.; Li, W.; Yang, H. Y.; Yang, C.*, Ultralow Iridium Dopant (<0.5 at. %) in LiNiO(2) Oxide for Improved Structure Stability. Nano Lett.2025,25 (15), 6024-6031.
[8]Suen, D. W.-S.; Chan, E. M. H.; Deng, L.; Mak, S. L.; Yang, C.*; Lu, X.-Y.; Ouyang, S.; Tsang, C.-W.; Habib, M. R., Functional Electrospun Membranes From Renewable Lignin for Clean Air Applications. Adv. Mater. Sci. Eng.2025,2025 (1).
[9]Lin, X.-S.; Wang, M.-M.; Shu, M.; Li, C.-Y.; Li, H.-J.; Wang, X.; Yang, C.*; Si, R., A lab-based micro-X-ray fluorescence spectrometer with high photon flux and spatial resolution for ancient ceramic research. J. Anal. At. Spectrom. 2025,40 (3), 747-752.
[10]Li, Z.; Wang, C.; Meng, F.; Zhou, Z.; Li, L.; Yang, C.*; Sun, D., Laboratory-based X-ray diffractometer with fast time resolution for operando battery studies. Energy Materials and Devices 2025,3 (1).
[11]Deng, L.; Gu, L.; Li, X.; Su, W.; Zhang, Y.; Chen, J.; Yu, J.; Wang, B.; Tsang, C.-W.; Yang, C.*, Elucidating the degradation mechanisms for capacity fading in cylindrical-type rechargeable alkaline Ni-Zn batteries. Chem. Eng. J. 2025,524.
[12]Chen, J.; Li, Z.; Zeng, H.; Deng, L.; Gu, L.; Wang, C.; Yang, C.*; Sun, D., Design and application of an electrochemical cell for operando X-ray diffraction and absorption studies for electrocatalysts. J. Synchrotron Radiat.2025,32 (Pt 5), 1272-1281.
[13]Zeng, H.; Liu, Z.; Qi, J.; Chen, J.; Zeng, Y.; Yang, C.; Li, Z.; Wang, C.; Gu, L.; Zhang, Y.; Shu, M.; Yang, C.*, Dynamic Cation Intercalation Facilitating Chemical Oxidation of Water and Surface Stabilization During the Oxygen Evolution Reaction. Energy Environ. Mater. 2024,8 (2).
[14]Zeng, H.; Chen, J.; Wang, C.; Qi, J.; Liu, Z.; Li, M.; Gu, L.; Wang, J.; Hong, E.; Zhang, Y.; Xu, J.; Yang, C.*, Understanding the pH-Dependent Catalytic Activity for the Layered LixCoO2 Oxygen Evolution Catalysts. ACS Mater. Lett.2024,6 (6), 2295-2303.
[15]Li, M.; Qi, J.; Zeng, H.; Chen, J.; Liu, Z.; Gu, L.; Wang, J.; Zhang, Y.; Wang, M.; Zhang, Y.; Lu, X.; Yang, C.*, Structural impacts on the degradation behaviors of Ir-based electrocatalysts during water oxidation in acid. J. Colloid Interface Sci. 2024,674, 108-117.
[16]Hong, Z.; Li, P.; Zou, Q.; Gu, L.; Wang, J.; Deng, L.; Wang, C.; Zhang, Y.; Li, M.; Chen, J.; Si, R.; Yang, C.*, Metal Organic Framework (MOF-808) Incorporated Composite Polymer Electrolyte for Stable All-Solid-State Lithium Batteries. ACS Appl. Energy Mater. 2024,7 (24), 11967-11976.
[17]Hong, E.; Zeng, H.; Qiao, X.; Deng, L.; Gu, L.; Wang, J.; Chen, J.; Guan, M.; Li, M.; Zhou, Z.; Yang, C.*, Degradation of a Bipolar Membrane in a Hybrid Acid/Alkali Electrolyzer Studied by X-ray Computed Tomography. ACS Appl. Mater. Interfaces 2024,16 (39), 52414-52422.
[18]Hong, E.; Yang, Z.; Zeng, H.; Gao, L.; Yang, C.*, Recent Development and Challenges of Bipolar Membranes for High Performance Water Electrolysis. ACS Mater. Lett. 2024,6 (5), 1623-1648.
[19]Gu, L.; Zhang, Y.; Kong, Q.; Yang, C.*, Synchrotron X‐ray Characterization Techniques for the Development of Aqueous Zinc Ion Batteries. ChemElectroChem2024,11 (7).
[20]Xia, Z.; Sun, Y.; Jiang, Y.; Chen, L.; Zhao, C.; Dai, C.; Wei, Z.; Zhang, G.; Yu, Y.; Wang, H.; Zhang, Z.; Xie, J.; Zhou, S.; Zhang, Q.; Li, X.; Shuai, J.; Yang, C.*; Liu, S., Two-Dimensional Graphitic Carbon Nitride for Improving the Performance of Organic Solar Cells. J. Phys. Chem. Lett.2023,14 (29), 6532-6541.
[21]Qi, J.; Zhong, X. Y.; Zeng, H. Y.; Wang, C.; Liu, Z. F.; Chen, J. J.; Gu, L.; Hong, E. N.; Li, M. X.; Li, J.; Yang, C.*, In-situ study for the elastic structure evolutions of three-dimensional Ir-O framework during the oxygen evolution reaction in acid. Nano Res.2023,16 (7), 9022-9030.
[22]Qi, J.; Yang, M.; Zeng, H.; Jiang, Y.; Gu, L.; Zhao, W.; Liu, Z.; Liu, T.; Yang, C.*; Si, R., Understanding the stabilization effect of the hydrous IrOx layer formed on the iridium oxide surface during the oxygen evolution reaction in acid. Inorg. Chem. Front. 2023,10 (3), 776-786.
[23]Luo, J. Y.; Li, S. J.; Xu, J. Y.; Chai, M. Y.; Gao, L.; Yang, C.*; Shi, X. T., Biomimetic Strain-Stiffening Hydrogel with Crimped Structure. Adv. Funct. Mater.2021,31 (43).
[24]Ge, J. H.; Lai, Y. C.; Guan, M. H.; Xiao, Y. H.; Kuang, J.; Yang, C.*, Nickel borate with a 3D hierarchical structure as a robust and efficient electrocatalyst for urea oxidation. Environmental Science-Nano2021,8 (5), 1326-1335.
[25]Yang, C.; Rousse, G.; Louise Svane, K.; Pearce, P. E.; Abakumov, A. M.; Deschamps, M.; Cibin, G.; Chadwick, A. V.; Dalla Corte, D. A.; Anton Hansen, H.; Vegge, T.; Tarascon, J. M.; Grimaud, A., Cation insertion to break the activity/stability relationship for highly active oxygen evolution reaction catalyst. Nat. Commun.2020,11 (1), 1378.
[26]Yang, C.; Nikiforidis, G.; Park, J. Y.; Choi, J.; Luo, Y.; Zhang, L.; Wang, S. C.; Chan, Y. T.; Lim, J.; Hou, Z. M.; Baik, M. H.; Lee, Y.; Byon, H. R., Designing Redox-Stable Cobalt-Polypyridyl Complexes for Redox Flow Batteries: Spin-Crossover Delocalizes Excess Charge. Adv. Energy Mater. 2018,8 (14).
[27]Yang, C.; Batuk, M.; Jacquet, Q.; Rousse, G.; Yin, W.; Zhang, L.; Hadermann, J.; Abakumov, A. M.; Cibin, G.; Chadwick, A.; Tarascon, J.-M.; Grimaud, A., Revealing pH-Dependent Activities and Surface Instabilities for Ni-Based Electrocatalysts during the Oxygen Evolution Reaction. ACS Energy Lett.2018,3 (12), 2884-2890.
[28]Wong, R. A.#; Yang, C.#; Dutta, A.; O, M.; Hong, M.; Thomas, M. L.; Yamanaka, K.; Ohta, T.; Waki, K.; Byon, H. R., Critically Examining the Role of Nanocatalysts in Li–O2 Batteries: Viability toward Suppression of Recharge Overpotential, Rechargeability, and Cyclability. ACS Energy Lett. 2018,3 (3), 592-597.
[29]Yang, C.; Fontaine, O.; Tarascon, J. M.; Grimaud, A., Chemical Recognition of Active Oxygen Species on the Surface of Oxygen Evolution Reaction Electrocatalysts. Angew. Chem. Int. Ed. Engl. 2017,56 (30), 8652-8656.
[30]Yang, C.; Wong, R. A.; Hong, M.; Yamanaka, K.; Ohta, T.; Byon, H. R., Unexpected Li2O2 film growth on carbon nanotube electrodes with CeO2 nanoparticles in Li–O2 batteries. Nano Lett. 2016,16 (5), 2969-2974.
合作作者:
[1]Chen, Q.; Li, Y.; Ma, W.; Shi, H.; Yang, C.; Li, C.; He, J., Lateral CO diffusion on micropatterned Ag/CuO arrays enables efficient CO2-to-C2+ electroreduction. Nanoscale2026.
[2]Zhong, W.; Chen, Y.; Chen, P.; Chen, Q.; Yang, C.; Zhang, N.; Liu, X.; Lin, Z., Balancing Hydrogen Evolution and Hydrogenation Reaction via Facet Engineering for Efficient Conversion of Nitrate to Ammonia in Actual Wastewater. Angew. Chem. Int. Ed. Engl. 2025,64 (19), e202503117.
[3]Zhao, S.; Liu, Z.; Chen, R.; Deng, Y.; Yang, C.; Zhang, P., Engineering a zero-strain CoNb₂O₆ anode via ZIF-67-derived sol-gel pyrolysis for ultra-stable lithium-ion capacitors. Chem. Eng. J. 2025,520.
[4]Qiao, X.; Cao, X.; Zhang, Y.; Chen, W.; Yang, C.; Li, Z.; Zhou, X.; Shen, K.; Zhou, Z., Determining the Effect of Grain Size on the Microstructure and Oxidation of Nuclear Graphite. Carbon Energy2025,8 (1).
[5]Liang, X.; Su, D.; Tang, Y.; Xi, B.; Yang, C.; Xiu, H.; Wang, J.; Liu, C.; Wang, M.; Chai, Y., Lab-on-device investigation of phase transition in MoOx semiconductors. Nat. Commun. 2025,16 (1), 4784.
[6]Wang, K.; Fu, J.; Dong, H.; Huang, B.; Liu, J.; Tian, L.; Feng, J.; Yang, C.; Lou, C.; Xu, L.; Sun, T.; Luo, H.; Xu, S.; Yin, G.; Zhang, H.; Tang, M., Enabling Highly Efficient Neodymium Luminescence for Near‐Infrared Phosphor‐Converted Light‐Emitting Diode Applications. Small Struct. 2024,5 (9).
[7]Sun, D.; Yang, C.; Meng, F.; Zhou, Z.; Ni, M.; Cui, Y.; Karlsson, U., The implementation and reflection of the “4R-4M” experimental methodology in the design and construction of experimental facilities in major national science and technology infrastructure. Chin. Sci. Bull. 2024.
[8]Huang, N. Y.; Li, B.; Wu, D.; Chen, Z. Y.; Shao, B.; Chen, D.; Zheng, Y. T.; Wang, W.; Yang, C.; Gu, M.; Li, L.; Xu, Q., Crystal Engineering of MOF-Derived Bimetallic Oxide Solid Solution Anchored with Au Nanoparticles for Photocatalytic CO2 Reduction to Syngas and C2 Hydrocarbons. Angew. Chem. Int. Ed. Engl.2024,63 (21), e202319177.
【发明专利】
[1]一种同步辐射x射线吸收光谱和质谱联用的电池装置与测试方法(CN112485275B)
[2]一种可原位测试x射线衍射和质谱分析的电池装置与方法 CN112436204B
[3]一种铱氧水合物催化剂的制备方法 CN112517002B
[4]一种拉曼与质谱联用的原位检测密封电解池装置CN212646486U
[5]一种红外光谱与在线电化学质谱联用的电化学测试装置 CN115144355B
[6]与瞬态质谱仪联用的光催化多反应体系在线气体检测装置 CN112881507B
[7]一种适用于原位x射线衍射测试的电解池装置 CN112485310B
[8]一种红外光谱与在线电化学质谱联用的电化学测试装置 CN218212632U
[9]一种用于同步辐射xas和xrd原位电池阵列自动化测试装置 CN217180659U
[10]一种适用于同步辐射xas测试的原位电化学电解池CN212646538U
[11]一种与瞬态质谱仪联用的多电池体系气体检测装置 CN216132981U
[12]一种同步辐射xas与质谱联用的流动电化学测试装置与方法 CN113533403B
[13]一种与瞬态质谱仪联用的多组合气体检测反应装置 CN112892417B
[14]一种同步辐射xas与质谱联用的流动电化学测试装置 CN216144728U
[15]一种原位催化反应设备 CN116637572B
[16]一种联合ct-dems的水系电池原位检测装置及方法 CN119064390B
[17]一种同步辐射x射线吸收光谱和质谱联用的电池装置与测试方法 CN112485275A
[18]一种可原位测试x射线衍射和质谱分析的电池装置与方法 CN112436204A
[19]一种扫描电化学瞬态质谱成像装置及检测方法 CN117269267A
[20]一种红外光谱与在线电化学质谱联用的电化学测试装置 CN115144355A