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A Computational Insight on the Effect of Encapsulation and Li Functionalization on Si<sub>12</sub>C<sub>12</sub> Heterofullerene for H<sub>2</sub> Adsorption: A Strategy for Effective Hydrogen Storage

Ankita Jaiswal, Brahmananda Chakraborty, Sridhar Sahu

2023ACS Applied Energy Materials30 citationsDOI

Abstract

This article presents the hydrogen storage capacity of Ar encapsulated and Li functionalized Si 12 C 12 heterofullerene using state-of-the-art Density Functional Theory (DFT) simulations. We find that the Li atom regioselectively prefers to bind at the top of the tetragonal sites of Ar encapsulated Si 12 C 12 heterofullerene with a maximum binding energy of 2.02 eV. Our study reveals that inert gas Ar encapsulation inside bare Si 12 C 12 provides greater stability to the heterofullerene by reducing the distortion. Hence, it provides a steady platform for Li decoration and successive H 2 adsorption. The adsorption energies of sequentially hydrogen-adsorbed Si 12 C 12 Li 6, Ne@Si 12 C 12 Li 6, and Ar@Si 12 C 12 Li 6 are compared, and it is observed that H 2 molecules prefer to adsorb over Li decorated Ar@Si 12 C 12 with maximum adsorption energy. Each Li atom decorated over Ar@Si 12 C 12 adsorbs a maximum of 5 H 2 molecules with an optimum adsorption energy of 0.11–0.22 eV, resulting in a gravimetric density of 9.7 wt % which is well above the US-DoE target. The adsorption mechanism of H 2 molecules over Ar@Si 12 C 12 Li 6 has been thoroughly investigated using the electrostatic map and topological analyses. The type of interaction involved in the adsorption of H 2 molecules over the Ar@Si 12 C 12 Li 6 surface is found to be a weak noncovalent interaction. Thermodynamic study reveals that almost all the 30 H 2 molecules remain adsorbed over the system at a low temperature of 100–120 K and undergo maximum desorption at 250–400 K, maintaining the structural integrity, which infers that the Ar@Si 12 C 12 Li 6 nanocage can be considered as a potential hydrogen storage material.

Topics & Concepts

AdsorptionDensity functional theoryMoleculeHydrogen storageChemisorptionHydrogenBinding energyDesorptionChemistrySurface modificationNanocagesMaterials sciencePhysical chemistryChemical physicsComputational chemistryAtomic physicsOrganic chemistryCatalysisPhysicsHydrogen Storage and MaterialsBoron and Carbon Nanomaterials ResearchSuperconductivity in MgB2 and Alloys
A Computational Insight on the Effect of Encapsulation and Li Functionalization on Si<sub>12</sub>C<sub>12</sub> Heterofullerene for H<sub>2</sub> Adsorption: A Strategy for Effective Hydrogen Storage | Litcius