N. M. Vitkovskaya scite author profile

The lowest two Rydberg and two -* valence excited singlet states of furan ͓referred to as 1 A 2 (3s), 1 B 1 (3p) and 1 B 2 (V), 1 A 1 (VЈ), respectively, at the C 2v ground-state molecular configuration͔ have been studied using the equation-of-motion coupled-cluster singles and doubles method ͑EOM-CCSD͒. Full geometry optimizations with subsequent computation of harmonic vibrational frequencies have been performed in order to locate and characterize stationary points on the potential energy surfaces ͑PES͒. The latter optimization work was enabled by the availability of analytic energy gradient techniques for the EOM-CCSD approach. A major new finding is that both the 1 B 2 (V) and 1 A 1 (VЈ) valence states are unstable with respect to non-totally symmetric distortions at the C 2v configuration. The symmetry breaking in the 1 B 2 (V) state involves an in-plane coordinate of b 2 symmetry. The relaxation process begins on the S 2 adiabatic PES and, after passing through a conical intersection of the S 2 and S 1 PES, continues on the S 1 surface, taking the system finally to the adiabatic minimum of S 1 ( 1 A 2 state͒. The 1 A 1 (VЈ) valence state is found to be unstable with respect to the out-of-plane bending coordinates of b 1 and a 2 symmetry. The resulting relaxed molecular structures have C s and C 2 symmetry, respectively. The present findings are analyzed in terms of a linear vibronic coupling model and spectroscopic implications are discussed.

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Quantum‐chemical models of KOH(KOBu^t)/DMSO superbasic systems and mechanisms of base‐promoted acetylene reactions

Vitkovskaya

Orel

Кобычев

et al. 2020

Int J of Quantum Chemistry

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The mechanisms of fundamental base‐promoted acetylene reactions, namely, nucleophilic addition to the triple C ≡ C bond (vinylation) and nucleophilic addition of acetylenic carbanion to a carbonyl group (ethynylation), are addressed using three models of different complexity—pentasolvate, monosolvate, and anionic—which describe the catalytic superbasic systems MOH(OBut)/DMSO (suspensions of alkali hydroxides or tert‐butoxides in dimethyl sulfoxide). The above acetylene reactions and sequential transformations of reagents arranged by the superbasic center are modeled within the framework of the most complete pentasolvate model, in which the superbase is represented by the KOH·5DMSO (KOBut·5DMSO) complexes. We have developed approaches to the construction of simplified models (monosolvate and anionic) to describe transformations in complex systems. The mechanisms of cascade assemblies of 6,8‐dioxabicyclo[3.2.1]octanes, cyclopentenones, and furan cycles from ketones and acetylenes in the superbasic environment are investigated using a uniform B2PLYP/6‐311+G**//B3LYP/6‐31+G* approach, and the energy profiles of these different carbo‐ and heterocycles are analyzed.

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Theoretical study of excitations in furan: Spectra and molecular dynamics

Gromov

Trofimov

Vitkovskaya

et al. 2004

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The excitation spectra and molecular dynamics of furan associated with its low-lying excited singlet states 1A2(3s), 1B2(V), 1A1(V'), and 1B1(3p) are investigated using an ab initio quantum-dynamical approach. The ab initio results of our previous work [J. Chem. Phys. 119, 737 (2003)] on the potential energy surfaces (PES) of these states indicate that they are vibronically coupled with each other and subject to conical intersections. This should give rise to complex nonadiabatic nuclear dynamics. In the present work the dynamical problem is treated using adequate vibronic coupling models accounting for up to four coupled PES and thirteen vibrational degrees of freedom. The calculations were performed using the multiconfiguration time-dependent Hartree method for wave-packet propagation. It is found that in the low-energy region the nuclear dynamics of furan is governed mainly by vibronic coupling of the 1A2(3s) and 1B2(V) states, involving also the 1A1(V') state. These interactions are responsible for the ultrafast internal conversion from the 1B2(V) state, characterized by a transfer of the electronic population to the 1A2(3s) state on a time scale of approximately 25 fs. The calculated photoabsorption spectrum of furan is in good qualitative agreement with experimental data. Some assignments of the measured spectrum are proposed.

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Exploring acetylene chemistry in superbasic media: A theoretical study of the effect of water on vinylation and ethynylation reactions with acetylene in KOH/DMSO and NaOH/DMSO systems

Vitkovskaya

Orel

Кобычев

et al. 2016

J. Phys. Org. Chem.

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A rapidly developing approach adding new dimensions to acetylene chemistry relying on employment of high basicity media such as alkali metal hydroxide suspensions in dimethyl sulfoxide (DMSO) has been, for the first time, investigated theoretically using ab initio models. Extending our recently introduced model of superbase catalysis with a nondissociated KOH (or NaOH) participation, we present here a model for a superbasic reaction center with the first solvation shell explicitly included. The alkali metal hydroxides in a DMSO solution were found to form KOH·5DMSO and NaOH·4DMSO complexes that are stabilized due to the interligand interaction. Our present MP2/6‐311++G**//B3LYP/6‐31+G* computations show that 1 and 2 water molecules can build themselves into the MOH close surrounding without substantially perturbing the DMSO ligands and easily travel between different insertion positions. Our results predict that the activation energies in the series of reactions of nucleophilic addition to a triple bond with water, methanol, methanethiol, sodium hydrosulfide, and acetone in the presence of dihydrated complexes should be larger than those obtained with the participation of monohydrated ones, which is in fair agreement with the experimental findings. The present model also explains an increase in the ethynylation reaction yield in the presence of water by suppression of the competitive enolization reaction.

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N. M. Vitkovskaya

Core-level electronic spectra in ADC(2) approximation for polarization propagator: Carbon monoxide and nitrogen molecules

Theoretical study of the low-lying excited singlet states of furan

Quantum‐chemical models of KOH(KOBu^t)/DMSO superbasic systems and mechanisms of base‐promoted acetylene reactions

Theoretical study of excitations in furan: Spectra and molecular dynamics

Exploring acetylene chemistry in superbasic media: A theoretical study of the effect of water on vinylation and ethynylation reactions with acetylene in KOH/DMSO and NaOH/DMSO systems

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N. M. Vitkovskaya

Core-level electronic spectra in ADC(2) approximation for polarization propagator: Carbon monoxide and nitrogen molecules

Theoretical study of the low-lying excited singlet states of furan

Quantum‐chemical models of KOH(KOBut)/DMSO superbasic systems and mechanisms of base‐promoted acetylene reactions

Theoretical study of excitations in furan: Spectra and molecular dynamics

Exploring acetylene chemistry in superbasic media: A theoretical study of the effect of water on vinylation and ethynylation reactions with acetylene in KOH/DMSO and NaOH/DMSO systems

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Product

Resources

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Quantum‐chemical models of KOH(KOBu^t)/DMSO superbasic systems and mechanisms of base‐promoted acetylene reactions