Kgasago, MP , MPhoshoko, Katlego WNgoepe, PLedwaba, R2025-12-092025-12-092025-112261-236Xhttps://doi.org/10.1051/matecconf/202541702002http://hdl.handle.net/10204/14507The electronic structure of lithium manganese oxide cathode materials is dependent on the choice of functional and spin configuration, necessitating a thorough analysis to accurately describe their structural and electronic properties. While these materials are appealing for lithium-ion batteries due to their high capacity, abundance, and low cost, accurately modelling their electronic properties remains challenging due to strong correlations in the manganese d orbitals. In this study, we employ firstprinciples calculations using the GGA+U functional to investigate the influence of spin configurations on the structural and electronic properties of these cathode materials. Our results shows that the antiferromagnetic (AFM) configuration gives a band gap consistent with experimental observations, whereas the ferromagnetic (FM) configuration produces a larger band gap. This shows the critical role of spin configuration in determining the electronic properties of these materials, indicating the importance of precise spin state modelling for accurate materials. These findings shows the importance of benchmarking beyond default ferromagnetic settings, including AFM configurations, to improve the accuracy of calculated properties in Mn-based cathode materials.FulltextenLithium manganese oxide cathode materialsLithium-ion batteriesAntiferromagnetic configurationAFMArticlen/a