OLi3-decorated Irida-graphene for High-capacity Hydrogen Storage: A First-principles Study

Abstract

Efficient hydrogen storage in solid-state materials is essential for next-generation energy systems, yet achieving a high gravimetric capacity with optimal adsorption characteristics remains a critical challenge. Although Li-decorated irida-graphene (IG) has shown promising hydrogen storage potential, its capacity is limited to 7wt\%, which, despite exceeding the U.S. DOE target, remains inadequate for large-scale applications. Additionally, Li clustering over extended cycles may compromise adsorption efficiency and structural stability. In this study, we employ first-principles calculations to investigate the hydrogen storage potential of IG decorated with superalkali OLi3 clusters, aiming to enhance the adsorption capacity and stability for advanced hydrogen storage technologies. Our findings show that the OLi3 clusters exhibit a significant binding energy of -3.24 eV, which highlights its strong interaction with the IG. OLi3@IG complex can host up to 12H2 molecules, with optimal maximum storage capacity of 10.00 wt\%. Additionally, the release temperature (TR) and ab initio molecular dynamics (AIMD) simulations indicate that H2 molecules can be efficiently released at operating temperatures under ambient conditions. These results highlight the potential of OLi3-decorated irida-graphene as a promising candidate for reversible hydrogen storage.