Research Progress of Cathode Materials for Lithium-ion Batteries

Kaijia Lu; Chuanshan Zhao; Yifei Jiang

doi:10.1051/e3sconf/202123301020

All issues

Volume 233 (2021)

E3S Web Conf., 233 (2021) 01020

References

Open Access

Issue		E3S Web Conf. Volume 233, 2021 2020 2^nd International Academic Exchange Conference on Science and Technology Innovation (IAECST 2020)


Article Number		01020
Number of page(s)		7
Section		NESEE2020-New Energy Science and Environmental Engineering
DOI		https://doi.org/10.1051/e3sconf/202123301020
Published online		27 January 2021

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[1] W.B.Liang, S.Y.Li, X.L.Cui. Bulletin of the Chinese Ceramic Society, 38,11(2019). [Google Scholar]

[2] L.S.Zhang, H.Wang, L.Z.Wang. Mater. Lett, 185, 100~103(2016). [Google Scholar]

[3] B.Xu, D.N.Qian, Z.Y.Wang, Mater. Sci. Eng., R, 73, 5~6(2012). [Google Scholar]

[4] X.Y.Cai, L.F.Lai, Z.X.Shen. J. Mater. Chem. A, 5, 30(2017). [Google Scholar]

[5] D.D.Lecce, R.Verrelli, J.Hassoun. Green Chem, 19, 5(2017). [Google Scholar]

[6] X.J.Huang. Materials China, 29,8(2010). [Google Scholar]

[7] R.Koksbang, J.Barker, H.Shi. Solid State Ionics, 84, 1~2(1996). [Google Scholar]

[8] Y.J.Liu, Y.Y.Gao, A.C.Dou. J. Power Sources, 248, 679~684(2014). [Google Scholar]

[9] X.J.Zhai, Y.G.Zhou, Y.Fu. J. Rare Earths, 23, 2(2005). [Google Scholar]

[10] T.Ohzuku, Y.Makimura. Chem. Lett, 30,8(2001). [Google Scholar]

[11] K.Kang, Y.S.Meng, J.Bréger. Science, 311, 5763 (2006). [Google Scholar]

[12] T.Ohzuku, Y.Makimura. Chem. Lett, 1,7(2001). [Google Scholar]

[13] M.M.Thackeray, S.H.Kang, C.S.Johnson. J. Mater. Chem, 17,30(2007). [Google Scholar]

[14] A.V.Potapenko, S.A.Kirillov. J. Energy Chem, 23, 5(2014). [CrossRef] [Google Scholar]

[15] K.Hoang. J. Mater. Chem. A, 2,43(2014). [Google Scholar]

[16] M.M.Thackeray, P.G.Bruce, J.B.Goodenough. Mater. Res. Bull, 18,4(1983). [Google Scholar]

[17] H.W.Lee, P.Muralidharan, R.Ruffo. Nano Lett, 10,10(2010). [Google Scholar]

[18] J.W.Fergus. J. Power Sources, 195,4(2010). [Google Scholar]

[19] A.Padhi, K.S.Nanjundaswamy, J.B.Goodenough. J. Electrochem. Soc, 144,4(1997). [Google Scholar]

[20] V.Legagneur, Y.An, A.Mosbah. Solid State Ionics, 139,1~2(2001). [Google Scholar]

[21] Y.Z.Dong, Y.M.Zhao, Z.D.Shi. Electrochim. Acta, 53,5(2008). [Google Scholar]

[22] A.Yamada, N.Lwane, Y.Harada. Adv. Mater, 22,32(2010). [Google Scholar]

[23] L.Chen, Y.M.Zhao, X.N.An. J. Alloys Compd, 494,1~2(2010). [Google Scholar]

[24] J.C.Kim, C.J.Moore, B.Kang, J. Electrochem. Soc, 158,3(2011). [Google Scholar]

[25] A.Nytén, A.Abouimrane, M.Armand. Electrochem. Commun, 7,2(2005). [Google Scholar]

[26] R.Dominko, M.Bele, M.aberšček. Electrochem. Commun, 8,2(2006). [Google Scholar]

[27] Y.X.Li, Z.L.Gong, Y.Yang. J. Power Sources, 174,2(2007). [Google Scholar]

[28] R.R.Zhao, Z.L.Yang, J.X.Liang. J. Alloys Compd, 689,318~325(2016). [Google Scholar]

[29] K.Q.Li, L.F.Cao, Z.Huang. J. Power Sources, 344,15(2017). [Google Scholar]

[30] M.E.Rethwisch, S.Hildebrand M.Evertz. J. Power Sources, 397,1(2018). [Google Scholar]

[31] Z.D.Peng, Z.G.Gan, K.Du. J. Alloys Compd, 730, 5(2018). [Google Scholar]

[32] L.S.Li Z.Zhang, S.H.Fu. Appl. Surf. Sci, 476,15(2019). [Google Scholar]

[33] Y.Luo, H.Y.Li, T.L.Lu. Electrochim. Acta, 238,1(2017). [Google Scholar]

[34] G.R.Chen, J.An, Y.M.Meng. Nano Energy, 57,157~165(2019). [Google Scholar]

[35] D.M.Liu, X.J.Fan, Z.H.Li. Nano Energy, 58,786~796(2019). [Google Scholar]

[36] P.Y.Guan, L.Zhou, Z.L.Yu. J. Energy Chem, 43,220~235(2020). [CrossRef] [Google Scholar]

[37] S.Q.Yang, P.B.Wang, H.X.Wei. Nano Energy, 63,103889(2019). [Google Scholar]

[38] J.C.Zheng, Z.Yang, Z.J.He. Nano Energy, 53,613~621(2018). [Google Scholar]

[39] Y.Liu, L.B.Tang, H.X.Wei. Nano Energy, 65,140043(2019). [Google Scholar]

[40] V.Ragupathi, P.Panigrahi, G.S.Nagarajan. Appl. Surf. Sci, 495,143541(2019). [Google Scholar]

[41] Z.H.Lei, J.L.Wang, J.Yang. ACS Appl. Mater. Interfaces, 10,43552~43560(2018). [Google Scholar]

[42] X.Zhang, M.Y.Hou, A.G.Tamirate. J. Power Sources, 448,227438(2020). [Google Scholar]