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Main Authors: Gautam, Siddharth, Cole, David R., Dudás, Zoltán Imre, Dhiman, Indu
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.17699
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author Gautam, Siddharth
Cole, David R.
Dudás, Zoltán Imre
Dhiman, Indu
author_facet Gautam, Siddharth
Cole, David R.
Dudás, Zoltán Imre
Dhiman, Indu
contents Adsorption in nanoporous materials is one strategy that can be used to store hydrogen at conditions of temperature and pressure that are economically viable. Adsorption capacity of nanoporous materials depends on surface area which can be enhanced by incorporating a hierarchical pore structure. We report grand canonical Monte Carlo (GCMC) simulation results on the adsorption of hydrogen in hierarchical models of silicalite that incorporate 4 nm wide mesopores in addition to the 0.5 nm wide micropores at 298 K, using different force fields to model hydrogen. Our results suggest that incorporating mesopores in silicalite can enhance adsorption by at least 20% if electrostatic interactions are not included and up to 100% otherwise. Incorporating electrostatic interactions results in higher adsorption by close to 100% at lower pressures for hierarchical silicalite whereas for unmodified silicalite, it is less significant at all pressures. Hydroxylating the mesopore surface in hierarchical silicalite results in an enhancement in adsorption at pressures below 1 atm and suppression by up to 20 % at higher pressures. Temperature dependence at selected pressures exhibits expected decrease in adsorption amounts at higher temperatures. These findings can be useful in the engineering, selection, and optimization of nanoporous materials for hydrogen storage.
format Preprint
id arxiv_https___arxiv_org_abs_2403_17699
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Simulation of hydrogen adsorption in hierarchical silicalite: Role of electrostatics and surface chemistry
Gautam, Siddharth
Cole, David R.
Dudás, Zoltán Imre
Dhiman, Indu
Materials Science
Chemical Physics
Adsorption in nanoporous materials is one strategy that can be used to store hydrogen at conditions of temperature and pressure that are economically viable. Adsorption capacity of nanoporous materials depends on surface area which can be enhanced by incorporating a hierarchical pore structure. We report grand canonical Monte Carlo (GCMC) simulation results on the adsorption of hydrogen in hierarchical models of silicalite that incorporate 4 nm wide mesopores in addition to the 0.5 nm wide micropores at 298 K, using different force fields to model hydrogen. Our results suggest that incorporating mesopores in silicalite can enhance adsorption by at least 20% if electrostatic interactions are not included and up to 100% otherwise. Incorporating electrostatic interactions results in higher adsorption by close to 100% at lower pressures for hierarchical silicalite whereas for unmodified silicalite, it is less significant at all pressures. Hydroxylating the mesopore surface in hierarchical silicalite results in an enhancement in adsorption at pressures below 1 atm and suppression by up to 20 % at higher pressures. Temperature dependence at selected pressures exhibits expected decrease in adsorption amounts at higher temperatures. These findings can be useful in the engineering, selection, and optimization of nanoporous materials for hydrogen storage.
title Simulation of hydrogen adsorption in hierarchical silicalite: Role of electrostatics and surface chemistry
topic Materials Science
Chemical Physics
url https://arxiv.org/abs/2403.17699