Benchmarking dispersion and geometrical counterpoise corrections for cost-effective large-scale DFT calculations of water adsorption on graphene

Benchmarking dispersion and geometrical counterpoise corrections for cost-effective large-scale DFT calculations of water adsorption on graphene

The physisorption of water on graphene is investigated with the hybrid density functional theory (DFT)‐functional B3LYP combined with empirical corrections, using moderate‐sized basis sets such as 6‐31G(d). This setup allows to model the interaction of water with graphene going beyond the quality of...

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Veröffentlicht in:Journal of computational chemistry 2014-09, Vol.35 (24), p.1789-1800
Hauptverfasser: Lorenz, Marco, Civalleri, Bartolomeo, Maschio, Lorenzo, Sgroi, Mauro, Pullini, Daniele
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Sprache:eng
Schlagworte:
Adsorbed water
Adsorption
B3LYP
Boron
Boron nitride
Computer simulation
Density functional theory
Dispersion
Electric properties
First principles
Graphene
Molecules
Simulation
Substrates
Water chemistry
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container_end_page 1800
container_issue 24
container_start_page 1789
container_title Journal of computational chemistry
container_volume 35
creator Lorenz, Marco
Civalleri, Bartolomeo
Maschio, Lorenzo
Sgroi, Mauro
Pullini, Daniele
description The physisorption of water on graphene is investigated with the hybrid density functional theory (DFT)‐functional B3LYP combined with empirical corrections, using moderate‐sized basis sets such as 6‐31G(d). This setup allows to model the interaction of water with graphene going beyond the quality of classical or semiclassical simulations, while still keeping the computational costs under control. Good agreement with respect to Coupled Cluster with singles and doubles excitations and perturbative triples (CCSD(T)) results is achieved for the adsorption of a single water molecule in a benchmark with two DFT‐functionals (Perdew/Burke/Ernzerhof (PBE), B3LYP) and Grimme's empirical dispersion and counterpoise corrections. We apply the same setting to graphene supported by epitaxial hexagonal boron nitride (h‐BN), leading to an increased interaction energy. To further demonstrate the achievement of the empirical corrections, we model, entirely from first principles, the electronic properties of graphene and graphene supported by h‐BN covered with different amounts of water (one, 10 water molecules per cell and full coverage). The effect of h‐BN on these properties turns out to be negligibly small, making it a good candidate for a substrate to grow graphene on. © 2014 Wiley Periodicals, Inc. The adsorption of water on graphene is computationally investigated via density functional theory combined with empirical corrections. This allows for going beyond the quality of classical or semiclassical simulations, while still keeping the computational costs under control. To model the water adsorption, 1 and 10 water molecules per cell were used as well as a full coverage of the graphene surface. Additionally, the same setup is applied to hexagonal boron nitride supported graphene.
doi_str_mv 10.1002/jcc.23686
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The effect of h‐BN on these properties turns out to be negligibly small, making it a good candidate for a substrate to grow graphene on. © 2014 Wiley Periodicals, Inc. The adsorption of water on graphene is computationally investigated via density functional theory combined with empirical corrections. This allows for going beyond the quality of classical or semiclassical simulations, while still keeping the computational costs under control. To model the water adsorption, 1 and 10 water molecules per cell were used as well as a full coverage of the graphene surface. 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Comput. Chem</addtitle><description>The physisorption of water on graphene is investigated with the hybrid density functional theory (DFT)‐functional B3LYP combined with empirical corrections, using moderate‐sized basis sets such as 6‐31G(d). This setup allows to model the interaction of water with graphene going beyond the quality of classical or semiclassical simulations, while still keeping the computational costs under control. Good agreement with respect to Coupled Cluster with singles and doubles excitations and perturbative triples (CCSD(T)) results is achieved for the adsorption of a single water molecule in a benchmark with two DFT‐functionals (Perdew/Burke/Ernzerhof (PBE), B3LYP) and Grimme's empirical dispersion and counterpoise corrections. We apply the same setting to graphene supported by epitaxial hexagonal boron nitride (h‐BN), leading to an increased interaction energy. 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subjects Adsorbed water
Adsorption
B3LYP
Boron
Boron nitride
Computer simulation
Density functional theory
Dispersion
Electric properties
First principles
Graphene
Molecules
Simulation
Substrates
Water chemistry
title Benchmarking dispersion and geometrical counterpoise corrections for cost-effective large-scale DFT calculations of water adsorption on graphene
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