Litcius/Paper detail

CO <sub>2</sub> on Graphene: Benchmarking Computational Approaches to Noncovalent Interactions

Christopher Ehlert, Anna Piras, Ganna Gryn’ova

2023ACS Omega12 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Designing and optimizing graphene-based gas sensors in silico entail constructing appropriate atomistic representations for the physisorption complex of an analyte on an infinite graphene sheet, then selecting accurate yet affordable methods for geometry optimizations and energy computations. In this work, diverse density functionals (DFs), coupled cluster theory, and symmetry-adapted perturbation theory (SAPT) in conjunction with a range of finite and periodic surface models of bare and supported graphene were tested for their ability to reproduce the experimental adsorption energies of CO 2 on graphene in a low-coverage regime. Periodic results are accurately reproduced by the interaction energies extrapolated from finite clusters to infinity. This simple yet powerful scheme effectively removes size dependence from the data obtained using finite models, and the latter can be treated at more sophisticated levels of theory relative to periodic systems. While for small models inexpensive DFs such as PBE-D3 afford surprisingly good agreement with the gold standard of quantum chemistry, CCSD(T), interaction energies closest to experiment are obtained by extrapolating the SAPT results and with nonlocal van der Waals functionals in the periodic setting. Finally, none of the methods and models reproduce the experimentally observed CO 2 tilted adsorption geometry on the Pt(111) support, calling for either even more elaborate theoretical approaches or a revision of the experiment.

Topics & Concepts

Graphenevan der Waals forcePhysisorptionStatistical physicsPerturbation theory (quantum mechanics)ComputationDensity functional theoryNon-covalent interactionsRange (aeronautics)PhysicsAdsorptionMaterials scienceQuantum mechanicsChemistryMoleculeComputer scienceAlgorithmPhysical chemistryHydrogen bondComposite materialAdvanced Chemical Physics StudiesGraphene research and applicationsMolecular Junctions and Nanostructures