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Importance of Van der Waals Interactions in Hydrogen\nAdsorption on a Silicon-carbide Nanotube Revisited with vdW-DFT and\nQuantum Monte Carlo

Genki I. Prayogo, Hyeondeok Shin, Anouar Benali, Ryo Maezono, Kenta Hongo

2021Europe PMC (PubMed Central)16 citationsDOIOpen Access PDF

Abstract

DFT is a valuable tool for calculating adsorption energies toward designing materials for hydrogen storage. However, dispersion forces being absent from the theory, it remains unclear how the consideration of van der Waals (vdW) interactions affects such calculations. For the first time, we applied diffusion Monte Carlo (DMC) to evaluate the adsorption characteristics of a hydrogen molecule on a (5,5) armchair silicon-carbide nanotube (H$_2$-SiCNT). Within the framework of density functional theory (DFT), we also benchmarked various exchange-correlation functionals, including those recently developed for treating dispersion or vdW interactions. We found that the vdW-corrected DFT methods agree well with DMC, whereas the local (semilocal) functional significantly over (under)-binds. Furthermore, we fully optimized the H$_2$-SiCNT geometry within the DFT framework and investigated the correlation between structure and charge density. The vdW contribution to adsorption was found to be non-negligible at approximately 1 kcal/mol per hydrogen molecule, which amounts to 9-29 % of the ideal adsorption energy required for hydrogen storage applications.

Topics & Concepts

van der Waals forceDensity functional theoryAdsorptionDiffusion Monte CarloMoleculeQuantum Monte CarloComputational chemistryHydrogenChemical physicsMaterials scienceCarbon nanotubeMonte Carlo methodChemistryPhysical chemistryNanotechnologyHybrid Monte CarloOrganic chemistryMarkov chain Monte CarloMathematicsStatisticsHydrogen Storage and MaterialsAdvanced Chemical Physics StudiesBoron and Carbon Nanomaterials Research