The hydrogen storage capacity of superalkali OLi3-decorated inorganic graphenylene SiC (IGP-SiC) has been explored using first-principles calculations employing the GGA-PBE functional. Notably, OLi3 is found to be strongly bonded to the IGP-SiC monolayer with a binding energy of -3.89 eV. Thus, a positive charge is developed on the lithium atom of OLi3 due to charge redistribution, which enhances its hydrogen adsorption energy. The interaction of H2 with OLi3@IGP-SiC involves charge polarization as well as orbital and van der Waals interactions. Our calculations reveal a remarkable hydrogen storage capacity of 10.93 wt %, surpassing the DOE-recommended limit of 6.5 wt %, where the hydrogen adsorption energy is found to be in the range of -0.19 to -0.15 eV/H2. To assess the thermal stability and reversibility of hydrogen storage exhibited by OLi3@IGP-SiC, ab initio molecular dynamics (AIMD) simulations were performed at temperatures of 100, 200, and 300 K. Hydrogen adsorption energy (E H2 ad) of OLi3@IGP-SiC can be tuned by applying an electric field. It is noticed that E H2 ad in OLi3@IGP-SiC + 1H2 is increased from -0.197 eV/H2 (at zero electric field) to -0.657 eV/H2 upon application of a +0.055 V/Å electric field. Furthermore, by employing the climbing-image nudged elastic band method, the hydrogen diffusion energy barrier is found to be 0.054 eV. Therefore, the OLi3-decorated IGP-SiC monolayer designed in this study may serve as a potential reversible hydrogen storage material.
Ramchiary et al. (Mon,) studied this question.