Electronic transition dipole moment: A semi‐biorthogonal approach within valence universal coupled cluster framework

Bhattacharya, Debarati; Vaval, Nayana; Pal, Sourav

doi:10.1002/qua.24691

Cited by 6 publications

(3 citation statements)

References 42 publications

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“…Due to the exponential form of the wave operators, the expressions for property matrix elements between the FS CC wavefunctions in terms of cluster amplitudes and model eigenvectors have the form of (quasi-) nonterminating series. Truncating these series, one arrives at computational schemes which had been successfully applied to ab initio calculations of transition probabilities in small systems (see, e.g., [11][12][13] and references therein). The simplest scheme of this kind includes abandoning of all the amplitude-dependent terms, and estimating the required property matrix elements between the FS (R)CC wavefunctions by the transition amplitudes between the corresponding model space functions (e.g., left and right eigenvectors of the effective Hamiltonian) [14,15].…”

Section: Introductionmentioning

confidence: 99%

Finite-Field Calculations of Transition Properties by the Fock Space Relativistic Coupled Cluster Method: Transitions between Different Fock Space Sectors

2020

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Reliable information on transition matrix elements of various property operators between molecular electronic states is of crucial importance for predicting spectroscopic, electric, magnetic and radiative properties of molecules. The finite-field technique is a simple and rather accurate tool for evaluating transition matrix elements of first-order properties in the frames of the Fock space relativistic coupled cluster approach. We formulate and discuss the extension of this technique to the case of transitions between the electronic states associated with different sectors of the Fock space. Pilot applications to the evaluation of transition dipole moments between the closed-shell-like states (vacuum sector) and those dominated by single excitations of the Fermi vacuum (the 1h1p sector) in heavy atoms (Xe and Hg) and simple molecules of heavy element compounds (I2 and TlF) are reported.

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Section: Introductionmentioning

confidence: 99%

Finite-Field Calculations of Transition Properties by the Fock Space Relativistic Coupled Cluster Method: Transitions between Different Fock Space Sectors

2020

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“…Truncating these series, one arrives at computational schemes which had been successfully applied to ab initio calculations of transition probabilities in small systems (see e.g. [11][12][13] and references therein). The simplest scheme of this kind includes abandoning of all the amplitude-dependent terms, and estimating the required property matrix elements between the FS (R)CC wavefunctions by the transition amplitudes between the corresponding model space functions (e.g.…”

Section: Introductionmentioning

confidence: 99%

Finite-Field Calculations of Transition Properties by the Fock Space Relativistic Coupled Cluster Method: Transitions between Different Fock Space Sectors

Zaitsevskii¹,

Oleynichenko²,

Eliav³

2020

Preprint

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Reliable information on transition matrix elements of various property operators between molecular electronic states is of crucial importance for predicting spectroscopic, electric, magnetic and radiative properties of molecules. The finite-field technique is a simple and rather accurate tool for evaluating transition matrix elements of first-order properties in the frames of the Fock space relativistic coupled cluster approach. We formulate and discuss the extension of this technique to the case of transitions between the electronic states associated with different sectors of the Fock space. Pilot applications to the evaluation of transition dipole moments between the closed-shell-like states (vacuum sector) and those dominated by single excitations of the Fermi vacuum (the $1h1p$ sector) in heavy atoms (Xe, Hg) and simple molecules of heavy element compounds (I${}_2$, TlF) are reported.

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“…13 A very efficient implementation of transition dipole moments within the framework of CC2 theory has been reported by Hättig and Köhn using the densityfitting/resolution of the identity approach 14 and Baudin et al 15 as well as Schütz and co-workers 16 using the local correlation approach. The implementation of transition dipole moments for other variants of coupled cluster or related methods, such as similarity transformed EOMCC (STEOMCC), 17 Fock space multireference coupled cluster (FSMRCC), 18,19 and symmetry adapted cluster/configuration interaction (SAC-CI), 20 has also been reported.…”

Section: Introductionmentioning

confidence: 99%

A simple scheme for calculating approximate transition moments within the equation of motion expectation value formalism

Dutta

Neese

2017

The Journal of Chemical Physics

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A simple scheme for calculating approximate transition moments within the framework of the equation of motion coupled cluster method is proposed. It relies on a matrix inversion technique to calculate the excited state left eigenvectors and requires no additional cost over that of the excitation energy calculation. The new approximation gives almost identical UV-Vis spectra to that obtained using the standard equation of motion coupled cluster method with single and double excitations for molecules in a standard test set.

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Electronic transition dipole moment: A semi‐biorthogonal approach within valence universal coupled cluster framework

Cited by 6 publications

References 42 publications

Finite-Field Calculations of Transition Properties by the Fock Space Relativistic Coupled Cluster Method: Transitions between Different Fock Space Sectors

Finite-Field Calculations of Transition Properties by the Fock Space Relativistic Coupled Cluster Method: Transitions between Different Fock Space Sectors

Finite-Field Calculations of Transition Properties by the Fock Space Relativistic Coupled Cluster Method: Transitions between Different Fock Space Sectors

A simple scheme for calculating approximate transition moments within the equation of motion expectation value formalism

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