广东省储能材料国际联合研究中心
广东省国际科技合作基地-储能材料国际联合研究中心(广东省储能材料国际联合研究中心,以下简称研究中心)于2023年8月获广东省科技厅批准立项建设,是华南师范大学获批的第2个省国际科技合作基地。
研究中心与发达国家开展储能材料合作研究和核心关键技术攻关,在此基础上形成自主的储能材料核心关键技术;同时,与一带一路国家开展合作,解决一带一路国家的储能材料的关键技术问题。
研究中心建设旨在引进来、走出去的合作模式,建立有效的引进、吸收、再创新、成果转化与应用的合作机制,攻克储能材料的核心关键技术,打破国外在关键技术上的垄断,把广东省储能产能输送到一代一路国家,推动广东储能产业发展,促进“一带一路”国家发展战略实施。
代表性成果:
[1] Z.Q. Fan#, X.Z. Zhou#, J.W. Qiu, Z. Yang, C.X. Lei, Z.Q. Hao, J.H. Li,* L. Li,* R.H. Zeng,* S.-L. Chou*,Sulfur-rich additive-induced interphases enable highly stable 4.6 V LiNi0.5Co0.2Mn0.3O2 | | graphite pouch cells, Angew. Chem. Int. Ed. 2023, e202308888.
[2] Y.W. Wu,# M.J. Lai,# J.F. Liang, J.Y. Liang, D.Y. Zhang, R.H. Zeng,* J.H. Li, Z.G. Xu, P. Chuangchanh, M. Du, X.-L. Wu*, Advanced 1D metal−organic coordination polymer for lithium-ion batteries: designing, synthesis, and working mechanism, ACS Appl. Mater. Interfaces, 2023, 15, 1452−1462.
[3] X.Y. Yang,# H. Deng,# J.F. Liang, J.Y. Liang, R.H Zeng,* R.R. Zhao, Q. Chen, M.Z. Chen, Y.F. Luo,* S.L. Chou*, Facile synthesis of a LiC15H7O4/graphene nanocomposite as a high-property organic cathode for lithium-ion batteries, ACS Appl. Mater. Interfaces, 2022, 14, 56808−56816.
[4] R.H. Zeng,*,# Y.W. Wu,# S.H. Qian, L. Li, H. Zhang, Q. Chen, Y.F. Luo,* S.-L. Chou*, Graphene-supported naphthalene-based polyimide composite as a high-performance sodium storage cathode, ACS Appl. Mater. Interfaces, 2022, 14, 11448−11456.
[5] Dan Li, G.Z. Lin, Z.X. Huang, X. Y. Tang, Z.J. Wu, Z.X. Li, D.Y. Zhang, P. Chuangchanh, R. H. Zeng*, Effect of different shell structure on lithium storage properties of MoS2 anode, J. Electroanal. Chem., 2022, 905:115972.
[6] M. M. Feng, R. H. Zeng*, S.-L. Chou, F. L. Gu*, Enhancing the understanding of the redox properties of lithium-inserted anthraquinone derivatives by regulating molecular structure, J. Electroanal. Chem., 2021,887:115172.
[7] F.H. Chen, Y.W. Wu, H.H. Zhang, Z.T. Long, X.X. Lin, M.Z. Chen, Q. Chen, Y.F. Luo, S.-L. Chou, R.H. Zeng*, The Modulation of discharge plateau of benzoquinone for sodium-ion batteries, Int. J. Min. Met Mater., 2021, 28(10):1675-1683.
[8] Y.W. Wu, X.J. Chen, G.Z. Lin, X.X. Zhu, J.W. Qiu, Y.F. Luo, Z.G. Xu, Q. Chen, V. Ganesh, R. H. Zeng*, C14H6O4Na2/graphene composite as a high performance sodium storage cathode, J. Electroanal. Chem., 2020,877:114749.
[9] Y.W. Wu, G.Z. Lin, X.M. Zhou, J. Chen, J.Y. Zhuang, Q. Chen, Y.F. Luo, D.S. Lu, V. Ganesh, R. H. Zeng*, Exploring structural stability mechanism of TiO2 encapsulated in 3Dflower-like SnS2 anode for lithium ion batteries, J. Electroanal. Chem., 2020,857:113740.
[10] Y.J. Ye, Z.X. Li, J.X. Pan, G.Z. Lin, Z.S. Zhu, R.T. Ye, Y.F. Luo, V. Ganesh, R.R. Zhao, D. Shu, R. H. Zeng*, Enhanced lithium storage properties achieved by TiO2 reinforced 2D CuO clusters, Sustain. Mater. and Techno., 2019, 21: e00097.
[11] Y.W. Wu, R. H. Zeng*, J.M. Nan, D. Shu, Y.C. Qiu,* S.-L. Chou*, Quinone Electrode Materials for Rechargeable Lithium/Sodium Ion Batteries, Adv. Energy. Mater., 2017,7,1700278. [12] X.J. Chen, Y.W. Wu, Z.K. Huang, X.Y. Yang, W.J. Li, L. C. Yu, R. H. Zeng*, Y.F Luo*, S.-L. Chou*, C10H4O2S2/graphene composite as a cathode material for sodium-ion batteries. J. Mater. Chem. A, 2016, 4,18409–18415.
[13]Y.F. Zhu, Y.H. Chu, J.H. Liang, Y.S. Li, Z.L. Yuan, W.T. Li, Y.Q. Zhang, X.X. Pan, S. L. Chou, L.Z. Zhao*, R. H. Zeng*, Tucked flower-like SnS2/Co3O4 composite for high-performance anode material in lithium-ion batteries, Electrochim Acta, 2016,190: 843–851.
[14] M.X. Lv, F. Zhang, Y.W. Wu, M.J. Chen, C.F. Yao, J.M. Nan, D. Shu, R. H. Zeng*, H.P. Zeng*, S.-L. Chou*, Heteroaromatic organic compound with conjugated multi- carbonyl as cathode material for rechargeable lithium batteries, Sci. Rep., 2016, 6:23515.
[15] K. N. Shang, W. T Li, Y. M. Liu, W. G. Zhang, H. Yang, J.Q. Xie, Z.Y. Liu, S-L. Chou, L.Z. Zhao*, R. H. Zeng*, A novel shuttle-like Fe3O4–Co3O4 self-assembling architecture with highly reversible lithium storage, RSC Adv., 2015, 5,70527-70535.