Hydrogen (H 2 ) energy has been recognized as a prominent choice for sustainable green energy applications. The primary obstacle lies in its storage, emphasizing the need for an efficient storage medium. Taking this into consideration and utilizing first-principles density functional theory, we conducted an extensive study to explore the H 2 adsorption potential of the biphenylene (BPN) monolayer decorated with superalkali NLi 4 clusters. The NLi 4 cluster exhibits a binding energy of −3.21 eV/ NLi 4 , when positioned on both sides of the BPN. The cluster binds to the BPN monolayer via an electronic charge transfer mechanism, leading to the creation of a positive charge on the Li atoms, which facilitates the polarized H 2 adsorption through electrostatic and van der Waals interactions. Under maximum hydrogenation, the 2NLi 4 @BPN complex can adsorb 24 H 2 molecules with a gravimetric density of 11.5 wt %, surpassing the latest criterion of the Department of Energy, 5.5 wt %. Ab initio molecular dynamics simulations at 300 K unveil H 2 reversibility and the thermal stability of the 2NLi 4 @BPN complex. Thermodynamic analysis and desorption temperature studies reveal the feasibility of reversible H 2 storage under ambient conditions. The energetics and high gravimetric density of NLi 4 -decorated BPN make it a prospective material for reversible hydrogen storage.