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Paramagnetic NMR Shielding Tensors Based on Scalar Exact Two-Component and Spin–Orbit Perturbation Theory

Florian Bruder, Yannick J. Franzke, Florian Weigend

2022The Journal of Physical Chemistry A35 citationsDOI

Abstract

The temperature-dependent Fermi-contact and pseudocontact terms are important contributions to the paramagnetic NMR shielding tensor. Herein, we augment the scalar-relativistic (local) exact two-component (X2C) framework with spin–orbit perturbation theory including the screened nuclear spin–orbit correction for the EPR hyperfine coupling and g tensor to compute these temperature-dependent terms. The accuracy of this perturbative ansatz is assessed with the self-consistent spin–orbit two-component and four-component treatments serving as reference. This shows that the Fermi-contact and pseudocontact interaction is sufficiently described for paramagnetic NMR shifts; however, larger deviations are found for the EPR spectra and the principle components of the EPR properties of heavy elements. The impact of the perturbative treatment is further compared to that of the density functional approximation and the basis set. Large-scale calculations are routinely possible with the multipole-accelerated resolution of the identity approximation and the seminumerical exchange approximation, as shown for [CeTi6O3(OiPr)9(salicylate)6].

Topics & Concepts

ParamagnetismHyperfine structureAnsatzCoupled clusterMultipole expansionScalar (mathematics)Tensor (intrinsic definition)PhysicsElectron paramagnetic resonancePerturbation theory (quantum mechanics)Fermi contact interactionElectromagnetic shieldingChemistryCondensed matter physicsAtomic physicsQuantum mechanicsMoleculeMathematicsGeometryAdvanced NMR Techniques and ApplicationsMagnetism in coordination complexesSynthesis and Properties of Aromatic Compounds
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