Elucidating Structural Transition Dynamics in the Magnesium Cathode MgCr2O4

Multivalent batteries, e.g., those based on magnesium (Mg), are promising candidates for next-generation energy storage due to their high volumetric energy densities and low cost. However, the corresponding ion migration and structural transition mechanisms are often linked and difficult to observe directly. Here, we report the direct investigation of atomic transport pathways of cations in spinel magnesium chromate (MgCr2O4) by using aberration-corrected scanning transmission electron microscopy (STEM). Cr atoms are directly observed to reversibly occupy the otherwise vacant octahedrally coordinated interstitial sites, passing through tetrahedral sites normally occupied by Mg. Furthermore, imaging and electron energy loss spectroscopy show that electron irradiation induces the formation of Mg and O vacancies, facilitating the migration of Cr and leading to an irreversible phase transition. These results demonstrate the ability of STEM to capture the pathway of deleterious point defects that can result in undesirable phase transitions.

Automated summary

This study directly investigates the atomic transport pathways of cations in spinel magnesium chromate using STEM, revealing the reversible occupation of interstitial sites by Cr atoms and the formation of vacancies induced by electron irradiation, leading to irreversible phase transitions.