Structure Prediction of Li--Sn and Li--Sb Intermetallics for Lithium-ion Batteries Anodes.
Chemistry of Materials
American Chemical Society
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Mayo, M., & Morris, A. (2017). Structure Prediction of Li--Sn and Li--Sb Intermetallics for Lithium-ion Batteries Anodes.. Chemistry of Materials https://doi.org/10.1021/acs.chemmater.6b04914
A variety of new stable and metastable Li–Sn and Li–Sb intermetallics are presented using the ab initio random structure searching (AIRSS) and species swapping methods. There include LiSn2–P4/mmm, Li2Sn3–P-1, Li7Sn9–P42/n, Li3Sn2–P21/m, Li5Sn3–Im-3m, Li2Sn– Cmcm, Li8Sn3–R-3m, Li3Sn–P32, Li7Sn2–P-1, Li4Sn–P21, Li5Sn–P6/mmm, Li7Sn–Fmmm, LiSb–P4/mmm, Li8Sb5–Fd-3m, Li8Sb3–P2/c, Li4Sb–C2/m, Li9Sb2–P-3m1, Li5Sb–P6/mmm, Li6Sb–R-3m, Li8Sb–Pc and Li9Sb–Cmcm. The Li–Sn theoretical voltage curve was calculated to high–accuracy mainly from experimentally known structures and shows excellent agreement with experimental electrochemical cycling measurements previously reported. Li2Sn was found on the convex hull to within density–functional theory accuracy and its mechanical stability was investigated by calculating the density of states of the phonon spectrum. The new structures obtained by AIRSS show a consistent structural evolution of Li–Sn phases as Li concentration is increased. First principles NMR calculations on the hexagonal– and cubic–Li3Sb phases are performed. Our NMR results are compared to findings of Johnston et al., Chemistry of Materials (2016) 28, 4032 and proposed as a diagnostic tool to interpret experimental data.
External DOI: https://doi.org/10.1021/acs.chemmater.6b04914
This record's URL: https://www.repository.cam.ac.uk/handle/1810/265162