Your search keyword '"A.V. Oleynichenko"' showing total 9 results

1. Relativistic Fock space coupled-cluster study of bismuth electronic structure to extract the Bi nuclear quadrupole moment

Author

Andréi Zaitsevskii, D. E. Maison, A. E. Barzakh, Leonid V. Skripnikov, and A.V. Oleynichenko

Subjects

Chemical Physics (physics.chem-ph), Physics, Nuclear Theory, Atomic Physics (physics.atom-ph), FOS: Physical sciences, Electronic structure, Physics - Atomic Physics, Fock space, Nuclear Theory (nucl-th), symbols.namesake, Coupled cluster, Physics - Chemical Physics, Excited state, Quadrupole, symbols, Physics::Atomic Physics, Atomic physics, Hamiltonian (quantum mechanics), Hyperfine structure, Electric field gradient

Abstract

We report the value of the electric quadrupole moment of $^{209}\mathrm{Bi}$ extracted from the atomic data. For this, we performed electronic structure calculations for the ground $^{4}S_{3/2}^{o}$ and excited $^{2}P_{3/2}^{o}$ states of atomic Bi using the Dirac-Coulomb-Breit Hamiltonian and the Fock space coupled-cluster method with single, double, and full triple amplitudes for the three-particle Fock space sector. The value of the quadrupole moment of $^{209}\mathrm{Bi}, Q{(}^{209}\mathrm{Bi})=\ensuremath{-}418(6)$ mb, derived from the resulting electric field gradient values and available atomic hyperfine splittings is in excellent agreement with molecular data. Due to the availability of the hyperfine constants for unstable isotopes of Bi, current atomic calculation allows also to correct their quadrupole moments.

Published

2021

2. Electron affinity of oganesson

Author

A.V. Oleynichenko, I. I. Tupitsyn, Ephraim Eliav, M. Y. Kaygorodov, Andréi Zaitsevskii, Y. S. Kozhedub, Leonid V. Skripnikov, A. V. Malyshev, V. M. Shabaev, and Anatoly V. Titov

Subjects

Physics, Quantum Physics, Coupled cluster, Electron affinity (data page), Atomic Physics (physics.atom-ph), Yield (chemistry), Operator (physics), Cluster (physics), FOS: Physical sciences, Atomic physics, Configuration interaction, Quantum Physics (quant-ph), Physics - Atomic Physics

Abstract

The electron affinity (EA) of superheavy element Og is calculated by the use of the relativistic Fock-space coupled cluster (FSCC) and configuration interaction methods. The FSCC cluster operator expansion included single, double, and triple excitations treated in a non-perturbative manner. The Gaunt and retardation electron-electron interactions are taken into account. Both methods yield the results that are in agreement with each other. The quantum electrodynamics correction to EA is evaluated using the model Lamb-shift operator approach. The electron affinity of Og is obtained to be 0.076(4) eV., 11 pages, 5 tables, 3 figures

Published

2021

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

Author

A.V. Oleynichenko, Andréi Zaitsevskii, and Ephraim Eliav

Subjects

010504 meteorology & atmospheric sciences, Physics and Astronomy (miscellaneous), General Mathematics, 01 natural sciences, Fock space, relativistic multireference coupled cluster method, Simple (abstract algebra), heavy element compounds, Quantum mechanics, 0103 physical sciences, Computer Science (miscellaneous), Radiative transfer, 010306 general physics, 0105 earth and related environmental sciences, Physics, transition properties, lcsh:Mathematics, Stochastic matrix, lcsh:QA1-939, atomic_molecular_physics, Dipole, Coupled cluster, Finite field, Chemistry (miscellaneous), Computer Science::Programming Languages, Fermi Gamma-ray Space Telescope

Abstract

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.

Published

2020

4. Fourier-transform spectroscopy and relativistic electronic structure calculation on the c3Σ+ state of KCs

Author

A. Kruzins, Ruvin Ferber, Andréi Zaitsevskii, A.V. Oleynichenko, E. A. Pazyuk, M. Tamanis, V. Krumins, and Andrey V. Stolyarov

Subjects

Physics, Dipole, Radiation, Coupled cluster, Molecule, Electronic structure, State (functional analysis), Atomic physics, Potential energy, Spectroscopy, Atomic and Molecular Physics, and Optics, Spectral line, Fourier transform spectroscopy

Abstract

The Ti:Saphire laser operated within 13800 - 11800 cm − 1 range was used to excite the c 3 Σ + state of KCs molecule directly from the ground X 1 Σ + state. The laser-induced fluorescence (LIF) spectra of the c 3 Σ + → a 3 Σ + transition were recorded with Fourier-transform spectrometer within 8000 to 10000 cm − 1 range. Overall 673 rovibronic term values belonging to both e / f -components of the c 3 Σ + ( Ω = 1 ± ) state of 39 KCs, covering vibrational levels from v = 0 to about 45, and rotational levels J ∈ [ 11 , 149 ] were determined with the accuracy of about 0.01 cm − 1 ; among them 7 values for 41 KCs. The experimental term values with v ∈ [ 0 , 22 ] were involved in a direct point-wise potential reconstruction for the c 3 Σ + ( Ω = 1 ± ) state, which takes into account the Ω -doubling effect caused by the spin-rotational interaction with the nearby c 3 Σ + ( Ω = 0 − ) state. The analysis and interpretation were facilitated by the fully-relativistic coupled cluster calculation of the potential energy curves for the B 1 Π , c 3 Σ + , and b 3 Π states, as well as of spin-forbidden c − X and spin-allowed c − a transition dipole moments; radiative lifetimes and vibronic branching ratios were calculated. A comparison of relative intensity distributions measured in vibrational c → a LIF progressions with their theoretical counterparts unambiguously confirms the vibrational assignment suggested in [J. Szczepkowski, et al., JQSRT, 204, 133–137 (2018)].

Published

2021

5. Ab initio study and assignment of electronic states in molecular RaCl

Author

Robert Berger, Thomas F. Giesen, Ephraim Eliav, R. F. Garcia Ruiz, A.V. Oleynichenko, Alexander A. Breier, T. A. Isaev, and Andréi Zaitsevskii

Subjects

Physics, Chemical Physics (physics.chem-ph), Radiation, 010504 meteorology & atmospheric sciences, Electronic correlation, Ab initio, chemistry.chemical_element, FOS: Physical sciences, 01 natural sciences, Diatomic molecule, Atomic and Molecular Physics, and Optics, Radium, Coupled cluster, chemistry, Laser cooling, Physics - Chemical Physics, Vibronic spectroscopy, Physics::Atomic Physics, Atomic physics, Hyperfine structure, Spectroscopy, 0105 earth and related environmental sciences

Abstract

Radium compounds have attracted recently considerable attention due to both development of experimental techniques for high-precision laser spectroscopy of molecules with short-lived nuclei and amenability of certain radium compounds for direct cooling with lasers. Currently, radium monofluoride (RaF) is one of the most studied molecules among the radium compounds, both theoretically and recently also experimentally. Complementary studies of further diatomic radium derivatives are highly desired to assess the influence of chemical substitution on diverse molecular parameters, especially on those connected with laser cooling, such as vibronic transition probabilities, and those related to violations of fundamental symmetries. In this article high-precision \emph{ab initio} studies of electronic and vibronic levels of diatomic radium monochloride (RaCl) are presented. Recently developed approaches for treating electronic correlation with Fock-space coupled cluster methods are applied for this purpose. Theoretical results are compared to an early experimental investigation by Lagerqvist and used to partially reassign the experimentally observed transitions and molecular electronic levels of RaCl. Effective constants of $\mathcal{P}$-odd hyperfine interaction $W_{\rm{a}}$ and $\mathcal{P,T}$-odd scalar-pseudoscalar nucleus-electron interaction $W_{\rm{s}}$ in the ground electronic state of RaCl are estimated within the framework of a quasirelativistic Zeroth-Order Regular Approximation approach and compared to parameters in RaF and RaOH., Comment: 18 pages, 2 figures, 5 tables

Published

2020

6. Towards High Performance Relativistic Electronic Structure Modelling: The EXP-T Program Package

Author

A.V. Oleynichenko, Andréi Zaitsevskii, and Ephraim Eliav

Subjects

Software, Perspective (geometry), Coupled cluster, business.industry, Computer science, Electronic structure, Supercomputer, business, Data structure, Scaling, Computational science, Fock space

Abstract

Modern challenges arising in the fields of theoretical and experimental physics require new powerful tools for high-precision electronic structure modelling; one of the most perspective tools is the relativistic Fock space coupled cluster method (FS-RCC). Here we present a new extensible implementation of the FS-RCC method designed for modern parallel computers. The underlying theoretical model, algorithms and data structures are discussed. The performance and scaling features of the implementation are analyzed. The software developed allows to achieve a completely new level of accuracy for prediction of properties of atoms and molecules containing heavy and superheavy nuclei.

Published

2020

7. Ab initio relativistic treatment of the a3Π−X1Σ+, a′3Σ+−X1Σ+ and A1Π−X1Σ+ systems of the CO molecule

Author

E. A. Pazyuk, Andréi Zaitsevskii, Andrey V. Stolyarov, A.V. Oleynichenko, N. S. Mosyagin, and A. V. Kudrin

Subjects

Physics, Radiation, 010504 meteorology & atmospheric sciences, Ab initio, Fine-structure constant, Quantum number, 01 natural sciences, Atomic and Molecular Physics, and Optics, Fock space, Dipole, Coupled cluster, Atomic electron transition, Radiative transfer, Atomic physics, Spectroscopy, 0105 earth and related environmental sciences

Abstract

The spin-forbidden a 3 Π − X 1 Σ + , a ′ 3 Σ + − X 1 Σ + and spin-allowed A 1 Π − X 1 Σ + electronic transitions dipole moments of carbon monoxide have been ab initio studied in the framework of multi-reference Fock space coupled cluster method combined with the finite-field approach and the generalized relativistic pseudo-potential model for the effective introducing the relativity in all-electron correlation treatment. Radiative lifetimes, τ i ( v ′ , J ′ ) , of the upper i ∈ [ a 3 Π , A 1 Π ] states were evaluated as a function of vibrational, v ′ , and rotational, J ′ , quantum numbers. The τ a -values derived for the triplet a 3 Π 1 ( 0 , 1 ) and a 3 Π 2 ( 0 , 2 ) states at the highest level of computation were found to be 2.59 and 142 ms, which are near perfect agreement with their best experimental counterparts (J. J. Gilijamse, et al., J. Chem. Phys., 127, 221102 (2007)). The intercombination a − X , a ′ − X transition probabilities were numerically proved to be proportional to α 2 , where α = e 2 / ℏ c is the fine structure constant.

Published

2021

8. Diagonal and off-diagonal hyperfine structure matrix elements in KCs within the relativistic Fock space coupled cluster theory

Author

Ephraim Eliav, V. M. Shabaev, Andréi Zaitsevskii, Leonid V. Skripnikov, and A.V. Oleynichenko

Subjects

Chemical Physics (physics.chem-ph), Physics, Atomic Physics (physics.atom-ph), Diagonal, FOS: Physical sciences, General Physics and Astronomy, 02 engineering and technology, Computational Physics (physics.comp-ph), 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, Physics - Atomic Physics, 0104 chemical sciences, Electronic states, Fock space, Matrix (mathematics), Coupled cluster, Physics - Chemical Physics, Molecule, Physics::Atomic Physics, Physical and Theoretical Chemistry, 0210 nano-technology, Physics - Computational Physics, Hyperfine structure

Abstract

The four-component relativistic Fock space coupled cluster method is used to describe the magnetic hyperfine interaction in low-lying electronic states of the KCs molecule. Both diagonal and off-diagonal matrix elements as functions of the internuclear separation $R$ are calculated within the finite-field scheme. The resulting matrix elements exhibit very weak dependence on $R$ for the separations exceeding 8 \AA , whereas in the vicinity of the ground-state equilibrium the deviation of molecular HFS matrix elements from the atomic values reaches 15\%. The dependence of the computed HFS couplings on the level of core correlation treatment is discussed., Comment: 3 figures

Published

2020

9. Relativistic Fock Space Coupled Cluster Method for Many-Electron Systems: Non-Perturbative Account for Connected Triple Excitations

Author

Ephraim Eliav, Leonid V. Skripnikov, A.V. Oleynichenko, and Andréi Zaitsevskii

Subjects

Physics, 010504 meteorology & atmospheric sciences, Physics and Astronomy (miscellaneous), lcsh:Mathematics, General Mathematics, Operator (physics), Extrapolation, relativistic coupled cluster method, heavy-element compounds, Electronic structure, lcsh:QA1-939, 01 natural sciences, Fock space, Computational physics, Coupled cluster, Chemistry (miscellaneous), 0103 physical sciences, Computer Science (miscellaneous), Cluster (physics), high-precision electronic structure modeling, 010306 general physics, Parametrization, excited states, 0105 earth and related environmental sciences, Numerical stability

Abstract

The Fock space relativistic coupled cluster method (FS-RCC) is one of the most promising tools of electronic structure modeling for atomic and molecular systems containing heavy nuclei. Until recently, capabilities of the FS-RCC method were severely restricted by the fact that only single and double excitations in the exponential parametrization of the wave operator were considered. We report the design and the first computer implementation of FS-RCC schemes with full and simplified non-perturbative account for triple excitations in the cluster operator. Numerical stability of the new computational scheme and thus its applicability to a wide variety of molecular electronic states is ensured using the dynamic shift technique combined with the extrapolation to zero-shift limit. Pilot applications to atomic (Tl, Pb) and molecular (TlH) systems reported in the paper indicate that the breakthrough in accuracy and predictive power of the electronic structure calculations for heavy-element compounds can be achieved. Moreover, the described approach can provide a firm basis for high-precision modeling of heavy molecular systems with several open shells, including actinide compounds.

Published

2020