Phase stability and ionic transport in post-spinel CaV2O4 cathode

Abstract

Calcium-ion batteries (CBs) represent an alternative to lithium-ion technology but their advancement is limited by the lack of high-performance intercalation cathodes. Identified via computational screening, post-spinel CaV2O4 has emerged as a promising candidate, though its practical application is hindered by limited electrochemical capacity. Hence, we investigate the thermodynamic and ionic transport characteristics of CaxV2O4 (0 ≤ x ≤ 1) in this work, by integrating the cluster expansion formalism with Monte Carlo simulations and density functional theory based calculations. We construct the temperature-composition phase diagram of CaxV2O4 revealing several stable phases (α through ζ) that can appear during electrochemical operations at different voltages. Importantly, we observe the formation of the phase at x 0.83 across a 370-590~K temperature window via invariant reactions, which agrees with observations in the experimental voltage profiles. Further, migration barrier calculations confirm that Ca mobility is severely impeded within the α (x 0) and γ (x 0.5) phases. With the strong Ca-vacancy ordering contributing to the high barrier in γ and the persistent two-phase region stretching across the δ (x 0.67) and the γ phases, we expect the accessible electrochemical capacity in the CaV2O4 system to be kinetically limited to at most half the theoretical capacity at 298~K, in agreement with experiments. Strategies including cation doping and particle size reduction can be considered to flatten the potential energy landscape of γ and improve Ca mobility. Our computational findings highlight the interplay between stability and transport and provide design strategies that can enable the practical use of CaV2O4 as a CB cathode.

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