Your search keyword '"Jagau, Thomas-C."' showing total 3 results

1. Characterizing metastable states beyond energies and lifetimes: Dyson orbitals and transition dipole moments.

Author

Jagau, Thomas-C. and Krylov, Anna I.

Subjects

*METASTABLE state energies, *MOLECULAR orbitals, *DIPOLE moments, *APPROXIMATION theory, *QUANTUM mechanics, *WAVE functions

Abstract

The theoretical description of electronic resonances is extended beyond calculations of energies and lifetimes. We present the formalism for calculating Dyson orbitals and transition dipole moments within the equation-of-motion coupled-cluster singles and doubles method for electron-attached states augmented by a complex absorbing potential (CAP-EOM-EA-CCSD). The capabilities of the new methodology are illustrated by calculations of Dyson orbitals of various transient anions. We also present calculations of transition dipole moments between transient and stable anionic states as well as between different transient states. Dyson orbitals characterize the differences between the initial neutral and final electron-attached states without invoking the mean-field approximation. By extending the molecular-orbital description to correlated many-electron wave functions, they deliver qualitative insights into the character of resonance states. Dyson orbitals and transition moments are also needed for calculating experimental observables such as spectra and cross sections. Physically meaningful results for those quantities are obtained only in the framework of non-Hermitian quantum mechanics, e.g., in the presence of a complex absorbing potential (CAP), when studying resonances. We investigate the dependence of Dyson orbitals and transition moments on the CAP strength and illustrate how Dyson orbitals help understand the properties of metastable species and how they are affected by replacing the usual scalar product by the so-called c-product. [ABSTRACT FROM AUTHOR]

Published

2016

2. Linear-response theory for Mukherjee's multireference coupled-cluster method: Static and dynamic polarizabilities.

Author

Jagau, Thomas-C. and Gauss, Jürgen

Subjects

*COUPLED mode theory (Wave-motion), *POLARIZABILITY (Electricity), *QUANTUM perturbations, *APPROXIMATION theory, *ELECTRONIC excitation, *MOLECULAR dynamics

Abstract

The formalism of response theory is applied to derive expressions for static and dynamic polarizabilities within the state-specific multireference coupled-cluster theory suggested by Mukherjee and co-workers (Mk-MRCC) [J. Chem. Phys. 110, 6171 (1998)]. We show that the redundancy problem inherent to Mk-MRCC theory gives rise to spurious poles in the Mk-MRCC response functions, which hampers the reliable calculation of dynamic polarizabilities. Furthermore, we demonstrate that in the case of a symmetry-breaking perturbation a working response theory is obtained only if certain internal excitations are included in the responses of the cluster amplitudes. Exemplary calculations within the singles and doubles approximation (Mk-MRCCSD) are carried out on aryne compounds to illustrate the impact of a multireference ansatz on the polarizability. [ABSTRACT FROM AUTHOR]

Published

2012

3. Linear-response theory for Mukherjee's multireference coupled-cluster method: Excitation energies.

Author

Jagau, Thomas-C. and Gauss, Jürgen

Subjects

*MICROCLUSTERS, *ELECTRONIC excitation, *FORCE & energy, *APPROXIMATION theory, *BENZYNES, *GROUND state (Quantum mechanics), *WAVE functions

Abstract

The recently presented linear-response function for Mukherjee's multireference coupled-cluster method (Mk-MRCC) [T.-C. Jagau and J. Gauss, J. Chem. Phys. 137, 044115 (2012)] is employed to determine vertical excitation energies within the singles and doubles approximation (Mk-MRCCSD-LR) for ozone as well as for o-benzyne, m-benzyne, and p-benzyne, which display increasing multireference character in their ground states. In order to assess the impact of a multireference ground-state wavefunction on excitation energies, we compare all our results to those obtained at the single-reference coupled-cluster level of theory within the singles and doubles as well as within the singles, doubles, and triples approximation. Special attention is paid to the artificial splitting of certain excited states which arises from the redundancy intrinsic to Mk-MRCC theory and hinders the straightforward application of the Mk-MRCC-LR method. [ABSTRACT FROM AUTHOR]

Published

2012