Open AccessA Density Functional Theory Study of the Ionic and Electronic Transport Mechanisms in LiFeBO3 Battery Electrodes
Author(s) -
Simon Loftager,
J. M. GarcíaLastra,
Tejs Vegge
Publication year - 2016
Publication title -
the journal of physical chemistry c
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.401
H-Index - 289
eISSN - 1932-7455
pISSN - 1932-7447
DOI - 10.1021/acs.jpcc.6b03456
Subject(s) - density functional theory , electrochemistry , chemical physics , ion , ionic bonding , phase (matter) , diffusion , polaron , cathode , materials science , battery (electricity) , lithium (medication) , electrode , electron , chemistry , computational chemistry , thermodynamics , physics , endocrinology , medicine , power (physics) , organic chemistry , quantum mechanics
Lithium iron borate is an attractive cathode material for Li-ion batteries due to its high specific capacity and low-cost, earth-abundant constituents. However, experiments have observed poor electrochemical performance due to the formation of an intermediate phase, that is, LixFeBO3, which leads to large overvoltages at the beginning of charge. Using a convex-hull analysis, based on Hubbard-corrected density functional theory (DFT+U), we identify this intermediate phase as Li0.5FeBO3. Moreover, we show by means of the nudged elastic band (NEB) method, that the origin of these adverse electrochemical effects can be explained by an intrinsically low Li-ion and electron/hole-polaron mobility in Li0.5FeBO3 due to high activation barriers for both the ionic and electronic transport. These studies include the effects of the experimentally reported commensurate modulation. We have also investigated the Li-ion/hole diffusion through the interface between Li0.5FeBO3 and LiFeBO3, which is found not to result in ad...
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