Hydrogen Storage on a New 2D Orthorhombic Boron Nitride Allotrope

Abstract

Hydrogen is a clean and renewable energy carrier, but its reversible storage near ambient conditions remains a major challenge. Here, density functional theory (DFT) combined with ab initio molecular dynamics (AIMD) is employed to assess the newly predicted 2D orthorhombic diboron dinitride (o-B2N2) monolayer, in pristine and Li-functionalized forms, as a hydrogen storage medium. On the pristine surface, H2 physisorbs with binding energies of −0.158 to −0.174 eV. Li atoms anchor strongly at the hexagonal hollow sites (𝐸bind from −0.979 to −1.321 eV, strongest at the B-rich H1 site), donate 0.65–0.84 |𝑒| to the substrate, and render the semiconducting monolayer metallic. A positive cluster formation energy (+0.171 eV per Li pair) and a 5 ps AIMD simulation at 400 K confirm that the Li adatoms remain dispersed, without clustering. Each Li+ center polarizes and binds up to five H2 molecules, with average adsorption energies of −0.207 to −0.336 eV/H2, within the optimal window for room-temperature reversible storage. The 4Li@o-B2N2(20H2) system attains a theoretical gravimetric capacity of 15.12 wt% and a practical capacity of 10.99 wt% under realistic operating conditions (charging at 30 atm/25 ∘C; release at 3 atm/100 ∘C). These results establish Li-functionalized o-B2N2 as a promising hydrogen storage material that merits experimental exploration.