Modeling phase transformations in Mn-rich disordered rocksalt cathodes with machine learning interatomic potentials
Abstract
Mn-rich disordered rocksalt (DRX) cathode materials exhibit a phase transformation from a disordered to a partially disordered spinel-like structure (-phase) during electrochemical cycling. In this computational study, we used charge-informed molecular dynamics with a fine-tuned CHGNet foundation potential to investigate the phase transformation in LiMnTiOF. Our results indicate that transition metal migration occurs and reorders to form the spinel-like ordering in an FCC anion framework. The transformed structure contains a higher concentration of non-transition metal (0-TM) face-sharing channels, which are known to improve Li transport kinetics. Analysis of the Mn valence distribution suggests that the appearance of tetrahedral Mn is a consequence of spinel-like ordering, rather than the trigger for cation migration as previously suggested. Calculated equilibrium intercalation voltage profiles demonstrate that the -phase, unlike the ordered spinel, exhibits solid-solution signatures at low voltage. A higher Li capacity is obtained than in the DRX phase. This study provides atomic insights into solid-state phase transformation and its relation to experimental electrochemistry, highlighting the potential of machine learning interatomic potentials for understanding complex oxide materials.
Cite
@article{arxiv.2506.20605,
title = {Modeling phase transformations in Mn-rich disordered rocksalt cathodes with machine learning interatomic potentials},
author = {Peichen Zhong and Bowen Deng and Shashwat Anand and Tara Mishra and Gerbrand Ceder},
journal= {arXiv preprint arXiv:2506.20605},
year = {2025}
}