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Dive into the research topics where S.S. Lukashov is active.

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Featured researches published by S.S. Lukashov.


Journal of Physics B | 2007

Hyperfine coupling of the iodine E0+g, vE = 19 and γ1u, vγ = 18 ion-pair states

M.E. Akopyan; S.S. Lukashov; Yu.D. Maslennikova; S.A. Poretsky; A.M. Pravilov

A considerable difference of iodine emission spectra after optical–optical double resonance excitation of the E0+g, vE = 19, JE ≈ 55 and JE ≈ 85 rovibronic levels is observed. The latter include strong transitions from the γ1u ion-pair state to valence ones. This feature is interpreted as a result of hyperfine coupling of near-resonant E0+g, vE = 19, JE = 81 and γ1u, vγ = 18, Jγ = 80 states. The hyperfine matrix element and dipole moment functions of transitions from the γ state are estimated. The hyperfine g/u mixing of the iodine ion-pair states is observed for the first time.


Journal of Chemical Physics | 2012

Non-adiabatic transitions from I2(E0g+ and D0u+) states induced by collisions with M = I2(X0g+) and H2O

M.E. Akopyan; Vera Baturo; S.S. Lukashov; S.A. Poretsky; A.M. Pravilov

The stepwise two-step two-color and three-step three-color laser excitation schemes are used for selective population of rovibronic levels of the first-tier ion-pair E0(g)(+) and D0(u)(+) states of molecular iodine and studies of non-adiabatic transitions to the D and E states induced by collisions with M = I(2)(X) and H(2)O. Collection and analysis of the luminescence after excitation of the v(E) = 8, 13 and v(D) = 13, 18 vibronic levels of the E and D states in the pure iodine vapor and the gas-phase mixtures with H(2)O provide rate constants for the non-adiabatic transitions to the D and E state induced by collisions with these molecules. Vibrational distributions for the [formula: see text] collision-induced non-adiabatic transitions (CINATs) are obtained. Rather strong λ(lum)(max) ≈ 3400 Å luminescence band is observed in the I(2) + H(2)O mixtures, whereas its intensity is ~100 times less in pure iodine vapor. Radiative lifetimes and quenching rate constants of the I(2)(E,v(E) = 8, 13 and D,v(D) = 13, 18) vibronic state are also determined. Rate constants of the [formula: see text], v(E) = 8-54, CINATs are measured again and compared with those obtained earlier. New data confirm resonance characters of the CINATs found in our laboratory about 10 years ago. Possible reasons of differences between rate constant values obtained in this and earlier works are discussed. It is shown, in particular, that differences in rate constants of non-resonant CINATs are due to admixture of water vapor in iodine.


Journal of Physics B | 2013

Spectroscopic constants and potential energy curve of the iodine weakly bound 1u state correlating with the I(2P1/2) + I(2P1/2) dissociation limit

Michael Akopyan; Vera Baturo; S.S. Lukashov; S.A. Poretsky; A.M. Pravilov

The stepwise three-step three-color laser population of the I2(β1g, νβ, Jβ) rovibronic states via the , νB, JB rovibronic states and rovibronic levels of the 1u(bb) and (bb) states mixed by hyperfine interaction is used for determination of rovibronic level energies of the weakly bound I2(1u(bb)) state. Dunham coefficients of the state, Yi0 (i = 0–3), Yi1 (i = 0–2), Y02 and Y12 for the = 1–5, 8, 10, 15 and ≈ 9–87 ranges, the dissociation energy of the state, De, and equilibrium I–I distance, Re, as well as the potential energy curve are determined. There are aperiodicities in the excitation spectrum corresponding to the β, νβ = 23, Jβ ← 1u(bb), ν1u = 4, 5, J1u progressions in the I2 + Rg = He, Ar mixture, namely, a great number of lines which do not coincide with the R or P line progressions. Their positions conflict with the ΔJ-even selection rule. Furthermore, they do not correspond to the ΔJ-odd progression.


Russian Journal of Physical Chemistry A | 2009

Ion-pair states in the complexes of iodine molecule with rare gases

M.E. Akopyan; S.S. Lukashov; S.A. Poretsky; A.M. Pravilov

The luminescence excitation spectra and the luminescence spectra of the I2 + Rg (Rg = He, Ar, Xe; pRg = 2–20 Torr) mixtures measured at room temperature by the method of double optical resonance in the spectral range corresponding to the population of the I2(f0g+, vf = 8.9) levels and in its vicinity are analyzed in this work. The experimental data and their interpretation, according to which these spectra can be explained by the energy transfer in the intermediate I2(B0u+) and final I2(f0g+) states of the free iodine molecule rather than by the optical population, luminescence, and predissociation of the ion-pair RgI2(IP) complexes, are discussed. It is shown that these data can be explained only with account taken of the optical population of the RgI2(IP) complexes.


Journal of Chemical Physics | 2008

Dynamics and mechanism of the E→D, D′, β, γ, and δ nonadiabatic transitions induced in molecular iodine by collisions with CF4 and SF6 molecules

M.E. Akopyan; S.S. Lukashov; S.A. Poretsky; A.M. Pravilov; A.S. Torgashkova; Alexei A. Buchachenko; Yury V. Suleimanov

Nonadiabatic transitions among the first-tier ion-pair states of the iodine molecule in collisions with CF(4) and SF(6) partners are investigated by detecting the luminescence following the optical-optical double resonance excitation of the E0(g) (+)-state to the vibrational levels v(E)=8, 13, and 19. Total and partial rate constants, as well as vibrational product state distributions, are determined. It is found that electronic energy transfer in all channels is predominantly assisted by excitation of the dipole-allowed nu(3) and nu(4) modes of the partner. The measurements are accompanied by quantum scattering calculations that implement a close coupling treatment for the electronic and vibrational degrees of freedom and combine diatomics-in-molecule and long-range models for diabatic potential energy surfaces and coupling matrix elements. The analysis of experimental and theoretical data shows that the transitions without excitation of the partner are due to short-range couplings, whereas the vibrational excitation of the partner in the D0(u) (+) channel originates from the long-range coupling of two transition dipole moments: electronic of the iodine molecule and vibrational of the partner. Unexpectedly efficient excitations of the partner in the other ion-pair states, which are not coupled to the initial E0(g) (+)-state by the transition dipole, are interpreted within the postcollision mechanism. Qualitatively, this implies that during a single collision the long-range nonadiabatic transitions to D, nu(3) and D, nu(4) channels are followed by secondary short-range transitions without changing the state of the partner.


Journal of Chemical Physics | 2016

Heterogeneous and hyperfine interactions between valence states of molecular iodine correlating with the I(2P1/2) + I(2P1/2) dissociation limit

Vera Baturo; I N Cherepanov; S.S. Lukashov; S.A. Poretsky; A.M. Pravilov; Anatoly I. Zhironkin

Detailed analysis of interactions between all 0g (+), 1u, and 0u (-) weakly bound states of iodine molecule correlating with the I((2)P1/2) + I((2)P1/2) (bb) dissociation limit has been performed. For this purpose, the 0u (-) (bb) state has been described using analysis of rotationally resolved excitation spectra of luminescence from the g0g (-) state populated in a three-step three-color perturbation facilitated excitation scheme via the 0u (-) state. Energies of 41 rovibrational levels, molecular constants, and potential energy curve have been determined. Energy gaps between closest rovibrational levels of the 0u (-) and 0g (+), 1u (bb) states are found to be large, ∼6 cm(-1). However, interaction of all three 0g (+), 1u, and 0u (-) (bb) states has been observed. It has been found that the 0u (-) and 1u electronic states are mixed by heterogeneous interactions, while their mixing with the 0g (+) one is due to hyperfine interactions predominantly. Admixture coefficients and electronic matrix elements of the coupling between the 0g (+) ∼1u, 0g (+)∼0u (-), and 0u (-) ∼1u states have been estimated.


Journal of Chemical Physics | 2015

Observation and deperturbation of near-dissociation ro-vibrational structure of the Cs2 state 0u+ (A1Σu+∼b3Π0+u) at the asymptote 6S1/2 + 6P1/2

Wenliang Liu; Rundong Xu; Jizhou Wu; Jinxin Yang; S.S. Lukashov; Vladimir B. Sovkov; Xingcan Dai; Jie Ma; Liantuan Xiao; Suotang Jia

New ro-vibrational structures of cold Cs2 in the 0u(+) state near the asymptote 6S1/2 + 6P1/2 are resolved. The variation of the rotational constants shows that the related energy spectra are strongly perturbed. An analysis of new data along with the empirical and theoretical information available from other sources is performed. For this purpose the model of spin-orbit coupling of the Hunds case (a) states A(1)Σu(+)∼b(3)Πu proposed by Bai et al. [Phys. Rev. A 83, 032514 (2011)] is extrapolated to the dissociation limit, and the parameters of the extrapolation are fitted from the near-dissociation experimental data.


Optics and Spectroscopy | 2010

Optical population of iodine molecule ion-pair states via MI2 vdW complexes, M = I2, Xe, of valence states correlating with the third, I(2P1/2) + I(2P1/2), dissociation limit

S.S. Lukashov; S.A. Poretsky; A.M. Pravilov; E. I. Khadikova; E. V. Shevchenko

The first results of measurements and analysis of excitation spectra of the λlum = 3250 Å luminescence corresponding to I2(D0u+ → X0g+) transition as well as luminescence at λlum = 3400 Å, where I2(D′2g → A′2u and/or β1g → A1u) transitions occur, observed after three-step, λ1 + λf + λ1, λ1 = 5321–5508.2 Å, λf = 10644.0 Å, laser excitation of pure iodine vapour and I2 + Xe mixtures at room temperature via MI2 vdW complexes, M = I2, Xe, of the I2(0g+, 1u(bb)) valence states correlating with the third, I(2P1/2) + I(2P1/2) (I2(bb)), dissociation limit are presented. Luminescence spectra in the λlum = 2200–3500 Å spectral range are also analyzed. Strong luminescence from the I2(D) and, probably, I2(D′ and β) states is observed. We discuss three alternative mechanisms of optical population of the IP state. In our opinion, the mechanism including the MI2 complexes is the most probable.


Optics and Spectroscopy | 2010

Optical population of iodine molecule ion-pair states via valence states correlating with the third, I(2P1/2) + I(2P1/2), dissociation limit and their MI2 vdW complexes, M = I2, Xe

S.S. Lukashov; S.A. Poretsky; A.M. Pravilov; E. I. Khadikova; E. V. Shevchenko

The first results of measurements and analysis of excitation spectra of the I2(D0u+ → X0g+) and I2(D0u+ → X0g+ and/or β1g → A1u) luminescence, observed after three-step, λ1 + λf + λ1, λ1 = 5508–5530 Å, λf = 10644.0 Å, laser excitation of pure iodine vapour and I2 + Xe mixtures at room temperature via bound parts of the I2(0g+, 1u(bb)) valence states correlating with the third, I(2P1/2) + I(2P1/2), dissociation limit and their MI2 vdW complexes, M = I2, Xe, are presented. Luminescence spectra in the λlum = 2200–5000 Å spectral range are also analyzed. Strong luminescence from the I2(D, γ, D′, and/or β) states is observed, though the two latter may be populated in optical transitions in a free iodine molecule if hyperfine coupling of the I2(0g+ and 1u(bb)) state rovibronic levels occurs. We discuss possible mechanisms of optical population of the IP state.


Journal of Physics B | 2016

Molecular parameters for weakly bound 2g(aa, ab) and states of molecular iodine and dipole moment functions of transitions to these states

Vera Baturo; I N Cherepanov; S.S. Lukashov; S.A. Poretsky; A.M. Pravilov

Weakly bound valence states of 2g symmetry, correlating with the I(2 P 3/2) + I(2 P 3/2) (aa) and I(2 P 3/2) + I(2 P 1/2) (ab) dissociation limits, as well as (ab) state, were studied using vibrationally resolved luminescence spectra corresponding to transitions from δ2u(3 P 2) and g (3 P 1) ion-pair states, in molecular iodine, respectively, populated using a three-step three-color laser excitation scheme. Spectroscopic constants and potential energy curves of the valence states are determined for the first time. Dipole moment functions of δ2u → 2g(aa, ab) and g → (ab) transitions are found to exponentially decrease.

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A.M. Pravilov

Saint Petersburg State University

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S.A. Poretsky

Saint Petersburg State University

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M.E. Akopyan

Saint Petersburg State University

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Vera Baturo

Saint Petersburg State University

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A.S. Torgashkova

Saint Petersburg State University

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Alexander Petrov

Petersburg Nuclear Physics Institute

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E. I. Khadikova

Saint Petersburg State University

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Yu.D. Maslennikova

Saint Petersburg State University

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