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Relativistic EOM-CCSD for Core-Excited and Core-Ionized State Energies Based on the Four-Component Dirac–Coulomb(−Gaunt) Hamiltonian

Loïc Halbert, Marta L. Vidal, Avijit Shee, Sonia Coriani, André Severo Pereira Gomes

2021Journal of Chemical Theory and Computation53 citationsDOIOpen Access PDF

Abstract

We report an implementation of the core–valence separation approach to the four-component relativistic Hamiltonian-based equation-of-motion coupled-cluster with singles and doubles theory (CVS-EOM-CCSD) for the calculation of relativistic core-ionization potentials and core-excitation energies. With this implementation, which is capable of exploiting double group symmetry, we investigate the effects of the different CVS-EOM-CCSD variants and the use of different Hamiltonians based on the exact two-component (X2C) framework on the energies of different core-ionized and -excited states in halogen- (CH3I, HX, and X–, X = Cl–At) and xenon-containing (Xe, XeF2) species. Our results show that the X2C molecular mean-field approach [Sikkema, J.; J. Chem. Phys. 2009, 131, 124116], based on four-component Dirac–Coulomb mean-field calculations (2DCM), is capable of providing core excitations and ionization energies that are nearly indistinguishable from the reference four-component energies for up to and including fifth-row elements. We observe that two-electron integrals over the small-component basis sets lead to non-negligible contributions to core binding energies for the K and L edges for atoms such as iodine or astatine and that the approach based on Dirac–Coulomb–Gaunt mean-field calculations (2DCGM) are significantly more accurate than X2C calculations for which screened two-electron spin–orbit interactions are included via atomic mean-field integrals.

Topics & Concepts

Hamiltonian (control theory)Excited statePhysicsCoulombCore (optical fiber)Component (thermodynamics)Dirac equationRelativistic quantum chemistryIonizationAtomic physicsDirac (video compression format)Quantum mechanicsIonElectronOpticsMathematical optimizationNeutrinoMathematicsAdvanced Chemical Physics StudiesAtomic and Molecular PhysicsMagnetism in coordination complexes