Na-ion Batteries. Laure Monconduit

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1.7. References

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      Carlier, D., Cheng, J.H., Berthelot, R., Guignard, M., Yoncheva, M., Stoyanova, R., Hwang, B.J., and Delmas, C. (2011). The P2-Na_2/3Co_2/3Mn_1/3O₂ phase: Structure, physical properties and electrochemical behavior as positive electrode in sodium battery. Dalton Transactions, 40(36), 9306–9312.

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      Clement, R., Billaud, J., Armstrong, R., Singh, G., Rojo, T., Bruce, P.G., and Grey, C.P. (2016). Structurally stable Mg-doped P2-Na_2/3Mn_1-yMg_yO₂ sodium-ion battery cathodes with high rate performance: Insights from electrochemical, NMR and diffraction studies. Energy & Environmental Science, 9(10), 3240–3251.

      Clement, R.J., Bruce, P.G., and Grey, C.P. (2015). Review-manganese-based P2-type transition metal oxides as sodium-ion battery cathode materials. Journal of the Electrochemical Society, 162(14), A2589–A2604.

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      Deng, J., Luo, W. B., Chou, S. L., Liu, H. K., & Dou, S. X. (2018). Sodium‐Ion Batteries: From Academic Research to Practical Commercialization. Advanced Energy Materials, 8(4), 1701428.

      Deng, J.Q., Luo, W.B., Lu, X., Yao, Q.R., Wang, Z.M., Liu, H.K., Zhou, H.Y., and Dou, S.X. (2018). High energy density sodium-ion battery with industrially feasible and air-stable O3-type layered oxide cathode. Advanced Energy Materials, 8(5), 1701610.

      Didier, C., Guignard, M., Denage, C., Szajwaj, O., Ito, S., Saadoune, I., Darriet, J., and Delmas, C. (2011). Electrochemical Na-deintercalation from NaVO₂. Electrochemical and Solid State Letters, 14(5), A75–A78.

      Dyer, L.D., Borie, B.S., and Smith, G.P. (1954). Alkali metal nickel oxides of the type MNiO₂. Journal of the American Chemical Society,

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