Computational identification and experimental realization of lithium vacancy introduction into the olivine LiMgPO4

Enciso-Maldonado, Leopoldo; Dyer, Matthew S.; Jones, Michael D.; Li, Ming; Payne, Julia L.; Pitcher, Michael J.; Omir, Mona K.; Claridge, John B.; Blanc, Fr�d�ric; Rosseinsky, Matthew J.

doi:10.1021/cm504518q

Computational identification and experimental realization of lithium vacancy introduction into the olivine LiMgPO4

Enciso-Maldonado, Leopoldo; Dyer, Matthew S.; Jones, Michael D.; Li, Ming; Payne, Julia L.; Pitcher, Michael J.; Omir, Mona K.; Claridge, John B.; Blanc, Fr�d�ric; Rosseinsky, Matthew J.

Authors

Leopoldo Enciso-Maldonado

Matthew S. Dyer

Michael D. Jones

MING LI MING.LI@NOTTINGHAM.AC.UK
Associate Professor

Julia L. Payne

Michael J. Pitcher

Mona K. Omir

John B. Claridge

Fr�d�ric Blanc

Matthew J. Rosseinsky

Abstract

Calculation of the energetics of aliovalent substitution into the olivine LiMgPO4 suggests that replacement of Mg2+ by In3+ is the most effective way to introduce lithium vacancies and thus generate Li ion conductivity. Experimental synthesis accesses materials with up to 17% Li vacancy content. An order-of-magnitude increase in the high-temperature hopping rates probed by 7Li NMR spin–lattice relaxation, and over 2 orders of magnitude increase in the room-temperature Li+ ion conductivity measured by impedance spectroscopy is observed upon the introduction of In3+ ions and Li vacancies. NMR spectroscopy and calculations reveal that the energy barrier to site-to-site hopping is 0.3–0.5 eV, comparable with best-in-class nonoxide systems such as argyrodite, but NMR-derived hopping rates, and impedance spectroscopy shows that longer range transport is less facile with activation energies in the range of 0.7–1 eV. Calculations suggest that this is because the Li vacancies are strongly bound to the In3+ dopants, suggesting that high lithium mobilities in oxides are accessible but high conductivities require strategies to separate defect from dopant.

Citation

Enciso-Maldonado, L., Dyer, M. S., Jones, M. D., Li, M., Payne, J. L., Pitcher, M. J., Omir, M. K., Claridge, J. B., Blanc, F., & Rosseinsky, M. J. (2015). Computational identification and experimental realization of lithium vacancy introduction into the olivine LiMgPO4. Chemistry of Materials, 27(6), 2074-2091. https://doi.org/10.1021/cm504518q

Journal Article Type	Article
Acceptance Date	Feb 12, 2015
Online Publication Date	Feb 12, 2015
Publication Date	Jan 1, 2015
Deposit Date	Jul 25, 2018
Print ISSN	0897-4756
Electronic ISSN	1520-5002
Publisher	American Chemical Society
Peer Reviewed	Peer Reviewed
Volume	27
Issue	6
Pages	2074-2091
DOI	https://doi.org/10.1021/cm504518q
Public URL	https://nottingham-repository.worktribe.com/output/1103044
Publisher URL	https://pubs.acs.org/doi/10.1021/cm504518q

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