Using
both computations and experiments, we demonstrate that the
performance of Li-excess cation-disordered rocksalt cathodes can be
improved by Mg substitution. Mg reduces the amount of Li in the compound
that is strongly bound to F and thereby increases the capacity. This
enables the use of fluorination as a tool to improve stability of
the compounds without significant loss of capacity. Mg emerged as
the most optimal substitution element from a systematic computational
study aimed at identifying inactive doping elements with a strong
enough bonding strength to fluorine to displace Li from the F environments.
Our results also show that capacity can be traded for cycle life depending
on whether Mg is substituted for Li or for the redox metal. This design
strategy should be considered in fluorinated cathodes, which will
facilitate the design of optimized disordered rocksalt oxyfluoride
cathodes.