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A case study of density functional theory and domain-based local pair natural orbital coupled cluster for vibrational effects on EPR hyperfine coupling constants: vibrational perturbation theory versus <i>ab initio</i> molecular dynamics

Alexander A. Auer, Van Anh Tran, Bikramjit Sharma, Georgi L. Stoychev, Dominik Marx, Frank Neese

2020Molecular Physics20 citationsDOIOpen Access PDF

Abstract

Local approximations of high-level ab initio methods make superior accuracy in the computation of molecular properties accessible by drastically decreasing computational times. As a consequence, these methods become applicable not only for large systems but also in schemes for which large numbers of calculations are necessary. In this work, we apply a recently developed open-shell implementation of the domain-based pair natural orbital coupled cluster singles doubles (DLPNO-CCSD) approach for the computation of vibrational corrections to the isotropic values of electron paramagnetic resonance (EPR) hyperfine coupling constants. We assess density functional theory (DFT) and DLPNO-CCSD approaches using two common but very different schemes: (1) vibrational perturbation theory based on equilibrium geometries, and (2) explicit canonical ensemble averages using configuration snapshots sampled from revPBE0-D3(0) ab initio molecular dynamics simulations. Both approaches are found to yield very similar results for the spin probe 2,2,3,4,5,5-hexamethylperhydroimidazol-1-oxyl (HMI) and are both feasible for systems of around 30 atoms. However, the numerical stability required for higher derivatives can become a limitation for local correlation methods in the case of vibrational perturbation theory.

Topics & Concepts

Coupled clusterDensity functional theoryPerturbation theory (quantum mechanics)Ab initioElectron paramagnetic resonanceHyperfine structureChemistryCoupling constantAb initio quantum chemistry methodsAtomic physicsPhysicsMolecular physicsComputational chemistryQuantum mechanicsMoleculeElectron Spin Resonance StudiesMagnetism in coordination complexesPhotochemistry and Electron Transfer Studies