Bogolyubov Institute for Theoretical Physics
of the National Academy of Sciences of Ukraine

List of Departments
Department of Theory of Nuclei and Quantum Field Theory

Head of the department – PhD Borys E. Grinyuk.

The department incorporates the Laboratory of Structure of Atomic Nuclei.
Head of the laboratory – Dr. Yulia A. Lashko.

Research fields
  • Quantum field theory and its applications to nuclear and particle physics, astrophysics, cosmology and condensed matter physics
  • Theory of nonperturbative effects in physical systems with the strong interaction
  • Theory of few-nucleon systems
  • Microscopic theory of light nuclei and nuclear reactions
  • Theory of collective excitations of atomic nuclei
  • Theory of many-body quantum systems
  • Representation without isospin for the theory of light nuclei
  • The structure and energy spectra of weakly bound nuclear cluster systems
Vladislav F. Kharchenko
Position: Chief Researcher
Dr.
Prof.
vkharchenko@bitp.kiev.ua

Valentin E. Kuzmichev
Position: Leading Researcher
Dr.
specrada@bitp.kiev.ua

Nikolai M. Petrov
Position: Leading Researcher
Dr.
pet@bitp.kiev.ua

Dmitry V. Anchishkin
Position: Leading Researcher
Dr.
dmanch@bitp.kiev.ua, dmytro.kiev@gmail.com

Vitalij N. Shadura
Position: Senior Researcher
Ph.D.
shadura@bitp.kiev.ua

Vladimir A. Babenko
Position: Senior Researcher
Ph.D.
pet2@ukr.net

Borys E. Grinyuk
Position: Head of the Department
Ph.D.
bgrinyuk@bitp.kiev.ua

Denys V. Zhuravel
Position: Leading Engineer
Ph.D.
lpbest@ukr.net

Olga A. Pushkash
Position: Leading Engineer
olgapushkash@bitp.kiev.ua
Laborarory of Structure of Atomic Nuclei
Yulia A. Lashko
Position: Head of the Laboratory
Dr.
ylashko@gmail.com
Victor S. Vasilevsky
Position: Leading Researcher
Dr.
vsvasilevsky@gmail.com
Aleksander V. Nesterov
Position: Senior Researcher
Dr.
nesterov@bitp.kiev.ua
Mariana D. Soloha-Klymchak
Position: Leading Engineer
mariana_sk@ukr.net
  • The influence of a topological defect in the form of the Abrikosov-Nielsen-Olesen vortex that is known in cosmology and astrophysics under the name of a cosmic string on quantum systems has been studied. A magnetic field is found to be induced in the ground state of relativistic quantum bosonic matter surrounding the cosmic string. The dependence of the total induced ground state magnetic flux on the string flux and tension, as well as on the transverse size of the string, is determined.
    Yu.A. Sitenko
  • The Ter-Martirosyan-Skornyakov equation is simplified using the Mellin integral transformation. An analytical expression for the case of three particles with negative energy is obtained. Simple analytical expressions of the Coulomb transition matrix of a two-particle system with a repulsive potential are obtained based on the analytical solution of the Lippmann-Schwinger equation.
    V.F. Kharchenko
  • A sufficient criterion for a possibility of the spatial collapse effect in an infinite system of Bose particles is established on the basis of the variational principle with the use of Jastrow correlation factors in the wave function. Using the obtained criterion, we show that in hypothetical nuclear matter, if it consisted of α-particles, spatial collapse would take place under the assumption of any αα-interaction potential from the known set of Ali-Bodmer ones.
    B.E. Grinyuk
  • The structure functions of the first excited state of mirror nuclei 14C and 14O are studied within the five-cluster model (three α-particles plus two extra nucleons) on the ground of variational calculations with the use of Gaussian bases. It is shown that the first excited 0+ state as compared to the ground state reveals itself in a change of the spatial structure of the two-nucleon subsystem moving in the field of the 12C cluster. Root mean square radii and relative distances between particles are calculated. Density distributions and electric form factors (both elastic and transition ones) are studied. Pair correlation functions and momentum distributions of particles for the excited state of these nuclei are found. For all the obtained structure functions, a comparison is carried out with the corresponding functions of the ground state. Two main configurations in the ground state and excited one of 14C and 14O nuclei are revealed.
    V.S.Vasilevsky, B.E. Grinyuk
  • A theory for the inducing of magnetic field in the vacuum of quantized fermion field in the background of a cosmic string of nonzero transverse size is elaborated. The dependence of the induced vacuum magnetic field strength on the string flux and tension, as well as on the transverse size of the string and on the distance from the string, is unambiguously determined.
    Cor.-member of the NAS of Ukraine Yu.A. Sitenko
  • Conditions under which a quantum particle can be described using classical quantities are studied. The wavefunction of a quantum particle submitted to a potential field for which all quantum effects vanish, even if Planck's constant is non negligible, is investigated. This problem is equivalent to the problem of the motion of a particle in a refringent medium. In these media, quantum particles have classical momenta, while their wave properties are described by the wave-optics equation. In the 1D case, the particle cannot be found in the region near the origin, since the index of refraction tends to infinity there. For the 3D case with central symmetry, the wave properties are determined by a function, that has a resonance of width of the order of the de Broglie wavelength.
    V.E. Kuzmichev, V.V. Kuzmichev
  • A three-cluster model of the 9ΛBe hypernucleus composed of two alpha-particles and Λ-hyperon has been developed. Input parameters of the model reproduce the experimental binding energy of the binary subsystem 5ΛHe . A good agreement between the calculated energies of the excited 9ΛBe states and the available experimental data has been obtained.
    A.V. Nesterov, Yu.A. Lashko, V.S. Vasilevsky
  • Temperature dependences of the tunneling rate through the screened Coulomb barrier are calculated for pp-, pd-, pt-, dd-, and dt-reactions at room temperatures, and an increase of a few orders of magnitude is demonstrated for the probability of the fusion reactions at only hundreds degrees of the temperature growth.
    B.E. Grinyuk
  • We have adapted a microscopic three-cluster model, which has been developed in nuclear structure laboratory for investigation of atomic nuclei, to studying light hypernuclei. The model has been applied to analyzing the structure of the 9ΛBe hypernucleus, which was considered as a three-cluster system comprising of two alpha particles and a Λ-hyperon. Within the present model, the spectrum of bound and resonance states in the 9ΛBe hypernucleus and phase shifts of elastic and inelastic scattering of a Λ-hyperon on 8Ве nucleus and of an alpha-particle on the Λ5Нe hypernucleus have been studied in detail. It was shown that cluster polarization generates a number of resonant states, most of which are very narrow with a width of less than 100 keV. There is a fairly good agreement between our results and the available experimental data, as well as the results obtained within alternative microscopic and semi-microscopic models.
    V.S. Vasilevsky, Yu. A. Lashko, A.V, Nesterov
  • The effects of Coulomb interaction in the formation of bound and resonant states of mirror light nuclei 7Li-7B, 8Li-8B, 9Be-9B, 11B-11C have been studied in detail. The resonant states with strong, weak and moderate effects of Coulomb interaction have been revealed. It was shown that the Coulomb shift is maximal for bound states because the bound states are more compact than the resonant ones.
    V.S. Vasilevsky
  • A new position-momentum uncertainty relation, which takes into account gravitational interaction of massive particles and generalizes the known relation that was previously proposed in various theoretical models, is obtained. Gravitational corrections to mean-square deviations of position and momentum are written explicitly. It is shown that the minimum length and the minimum momentum depend on the energy of particle relative motion.
    V.E. Kuzmichev, V.V. Kuzmichev
  • The theory of polarization of the vacuum of quantized fermion field in the presence of a topological defect is constructed.
    Corr. Member of the NAS of Ukraine Yu.A. Sitenko
  • Using the method of stereographic projection of the three-dimensional momentum space onto the four-dimensional unit sphere, the analytical solution of the two-particle Lippmann-Schwinger integral equation with the Coulomb interaction at the negative energy has been performed. For the first time, the analytical expressions for the three-dimensional Coulomb transition matrix at the energies that correspond to the fractional values of the interaction parameter have been obtained.
    V.F. Kharchenko
  • The simple semi-phenomenological model which describes the charge independence and charge symmetry breaking of the pion-nucleon coupling constant has been proposed. The model has simple physical meaning and suggests directly proportional dependence of the pion-nucleon coupling constants on the masses of interacting nucleons and pions. On the basis of the proposed model we have found that the charged pion-nucleon coupling constant exceeds the neutral pion-nucleon coupling constant by about 7% indicative of a substantial charge independence breaking of nuclear forces in the pion-nucleon coupling constant.
    V.A. Babenko, N.M. Petrov
  • The continuum model for long-wavelength charge carriers, originating in the tight-binding approximation for the nearest-neighbour interaction of atoms in the crystalline lattice, is applied to consider quantum ground-state effects of electronic excitations in Dirac materials with two-dimensional monolayer honeycomb structures warped into nanocones by a disclination. The magnetic flux circulating in the angular direction around the nanocone apex and the pseudomagnetic flux directed orthogonally to the nanocone surface are shown to be induced in the ground state.
    Corr. Member of the NAS of Ukraine Yu.A. Sitenko
  • New analytical expressions for the three-dimensional Coulomb matrix of transition are derived for energies corresponding to the integral and semi-integer value of the Sommerfeld parameter.
    V.F. Kharchenko
  • Within the framework of a nonperturbative quantum theory of gravitation, based on the quantum generalization of the Hamilton-Jacobi equation of general relativity, it is shown that during the evolution of the early universe the cosmological parameters, i.e., the matter-energy density, the pressure, and the deceleration parameter, may fluctuate between positive and negative values under the influence of quantum corrections to the energy density.
    V.E. Kuzmichev
  • Simple relations connecting the strange s-quark mass to the splittings of the light hyperon masses are obtained on the basis of the phenomenological quark model compatible with the quantum chromodynamics (QCD). The value of strange s-quark mass, calculated in the proposed approach, is in good agreement with the modern evaluations and calculations of this quantity, obtained by the lattice QCD methods.
    V.A. Babenko, N.M. Petrov
  • An alternative way of light nuclei synthesis in the stellar environment through a triple collision of nuclei and the excitation of a narrow resonance state is studied in detail. It is shown that the long-lived resonance state which is a key element of synthesis of carbon ‒ the Hoyle-analog state ‒ exists also in the light nuclei 9Be, 9B, 11B and 11C. Such resonance states are generated by collisions of two alpha-particles with neutrons, protons, tritons, and nuclei 3He, respectively. The Hoyle-analog states are not observed in the nucleus 10B consisting of two alpha-particles and a deuteron.
    V.S. Vasilevsky, Y.A. Lashko, G.F. Filippov
  • Structure characteristics of the lowest excited state of the mirror nuclei 14С and 14О are studied within a five-particle model (three α-particles plus two extra nucleons) in terms of the variational approach with the Gaussian bases. The charge radius of 14О is calculated, and it is explained why this radius is smaller than that of 14С nucleus, although 14О contains two extra protons instead of two extra neutrons in 14С. Both elastic and transition electrical form-factors of 14C and 14O nuclei are calculated.
    V. S. Vasilevsky, B. E. Grinyuk, D. V. Piatnytskyi
  • Within the discrete representation of the harmonic oscillator basis, eigenvalues and eigenfunctions of the potential energy matrix are investigated for a particle in the field of central spherical square-well potentials, Gaussian potential, Yukawa potential and exponential potential. For all the potentials considered, the eigenfunctions of the potential energy operator in the discrete representation are shown to be harmonic oscillator basis functions. In the momentum representation the eigenfunctions of the potential energy operator are proved to be spherical Bessel functions.
    Y.A. Lashko
  • We consider quantum ground state effects in Dirac materials with two-dimensional monolayer structures warped into nanocones by a disclination; the nonzero size of the disclination is taken into account, and a boundary condition at the edge of the disclination is chosen to ensure self-adjointness of the Dirac-Weyl Hamiltonian operator. In the case of carbon, silicium and germanium nanocones, we show that the quantum ground state effects are independent of the disclination size and find circumstances when they are independent of the boundary parameter.
    Yu.A. Sitenko
  • On the basis of Schwinger representation for the Coulomb Green function the possibility of the analytical solution of the Lippmann-Schwinger equation for the three-dimensional Coulomb transition matrix at negative energies has been established in the case of the repulsive interaction and the integer values of Coulomb parameter as well as in the case of repulsive and attractive interactions and half-integer values of Coulomb parameter (1/2 and -1/2, respectively).
    V.F. Kharchenko
  • We considered a set of three-cluster systems (4He, 7Li, 7Be, 8Be, 10Be) within a microscopic model which involves the hyperspherical harmonics to represent intercluster motion. We selected such three-cluster systems which have at least one binary channel. Our aim is to study whether the hyperspherical harmonics are able and under what conditions to describe two-body channel or they are suitable for describing three-cluster continuum only. The main result of the present investigations is that to describe the nondemocratic two-cluster decay or bound states below the two-cluster threshold one needs to use a rather restricted set of the hyperspherical harmonics and hyperradial excitations as well. It was demonstrated that the eigenstates of the three-cluster hamiltonian have correct asymptotic behaviour both for bound states below two-cluster threshold and states in two-cluster continuum.
    Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky
  • On the basis of a simple phenomenological model, by assumption of the one-pion exchange mechanism for the nuclear forces, we establish relations between different pion-nucleon coupling constants that characterize the nucleon-nucleon interaction. The charge independence breaking effect in the pion-nucleon coupling constants is entirely explained by the mass difference between the charged and neutral pions and by the mass difference between the proton and the neutron as well.
    V.A. Babenko, N.M. Petrov
  • We study the influence of boundaries on chiral effects in hot dense relativistic spinor matter in a strong magnetic field which is orthogonal to the boundaries. It is shown that the chiral magnetic effect disappears, whereas the chiral separation effect becomes dependent not only on chemical potential, but on temperature and on a boundary condition as well. These points at a significant role of boundaries for physical systems with hot dense magnetized spinor matter, i.e. compact astrophysical objects (neutron stars and magnetars), relativistic heavy-ion collisions, novel materials known as the Dirac and Weyl semimetals.
    Yu.A. Sitenko
  • New approach to the description of the off-shell Coulomb scattering amplitude that is based on using the Fock's method of the stereographic projection of the momentum space onto the four-dimensional unit sphere has been worked out. New analytical expressions for the partial-wave off-shell Coulomb transition matrices for particles with the repulsive interaction at the ground-state energy have been derived.
    V.F. Kharchenko
  • Charge independence breaking (CIB) in the pion-nucleon coupling constant and the nucleon-nucleon scattering length is considered on the basis of the Yukawa meson theory. The CIB effect in these quantities is almost entirely explained by the mass difference between the charged and the neutral pions. Therewith charge splitting of the pion-nucleon coupling constant is almost the same as charge splitting of the pion mass.
    V.A. Babenko, N.M. Petrov
  • The structure functions of the mirror nuclei 14С and 14O are studied within a model "three alpha-particles plus two extra nucleons". The charge density distributions, form factors, pair correlation functions, and the momentum distributions of particles are found for these nuclei. Two spatial configurations are revealed in the ground state of 14С and 14O nuclei. The unknown experimental charge r.m.s. radius of 14O nucleus is predicted.
    B.E. Grinyuk, D.V. Piatnytskyi
  • Theoretical analysis of bound and resonance states in 10Be nucleus is performed within a microscopic three-cluster model. This nucleus is represented as three-cluster system comprised of two alpha particles and a dineutron. The latter is two neutrons correlated in the space, which form a pseudo-bound state. The processes of elastic and inelastic scattering of alpha particles from 6He and dineutron from 8Be are also investigated. Within the present model, nuclei 6Не and 8Ве are considered as two-cluster systems, which consist of alpha particle and dineutron and two alpha particles, respectively. One of main aims of the present investigation is to study how cluster polarization of nuclei 6Не and 8Ве affects the structure of bound and resonance states in 10Ве and elastic and inelastic processes as well. It is shown that nuclei 6Не and 8Ве are substantially changed their size and shape when they interact with alpha particle and dineutron, respectively. It is also shown that the cluster polarization strongly changes a mutual attraction of clusters in the compound system and leads to larger energy of bound states and smaller energy and width of resonance states of the three-cluster system. Within the present model, we obtain good agreement of theoretical results with available experimental data for discrete and continuous spectrum states in 10Ве.
    Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky
Articles in journals, other publications
  1. K.A.Bugaev, O.V.Vitiuk, B.E. Grinyuk, P.P.Panasiuk, N.S. Yakovenko, E.S.Zherebtsova, V. V. Sagun, O. I. Ivanytskyi, L.V.Bravina, D. B. Blaschke, S. Kabana, S. V. Kuleshov, A.V.Taranenko, E.E.Zabrodin, and G. M. Zinovjev. Induced surface and curvature tension equation of state for hadron resonance gas in finite volumes and its relation to morphological thermodynamics. Int. J. Mod. Phys. A (2021), 24 p. https://doi.org/10.1142/S0217751X21410098
  2. B.E.Grinyuk. Can Nuclear Matter Consist of α-Particles? УФЖ 67, № 1, с. 17 - 21 (2022). http:// doi.org/10.15407/ujpe67.1.17
  3. B.E.Grinyuk, I.V.Simenog. Model-independent solution of nd-scattering problem in the quartet state. – UJP 67, No. 5, p.322-326 (2022). https://doi.org/10.15407/ujpe67.5.322
  4. Oleksandr V. Vitiuk, Valery M. Pugatch, Kyrill A. Bugaev, Nazar S. Yakovenko, Pavlo P. Panasiuk, Elizaveta S. Zherebtsova, Vasyl M. Dobishuk, Sergiy B. Chernyshenko, Borys E. Grinyuk, Violetta Sagun, Oleksii Ivanytskyi. Colliding and Fixed Target Mode in a Single Experiment – a Novel Approach to Study the Matter under New Extreme Conditions. – Particles, Vol. 5, Issue 3, p. 245–264 (2022). https://doi.org/10.3390/particles5030022
  5. B. E. Grinyuk, D.V. Piatnytskyi, V.S.Vasilevsky. The lowest excited states of 14C and 14O nuclei within a five-cluster model. – Nuclear Physics A (2022). https://doi.org/10.1016/j.nuclphysa.2022.122588
  6. V.F. Kharchenko. "On the analytical solving of Ter Martirosian - Skornyakov Equation for Three Particles at Negative Energies", Ukrainian Journal of Physics, 2022, vol. 67, n. 8, p. 559-560
  7. D. Anchishkin, V. Gnatovskyy, D. Zhuravel, and V. Karpenko, Selfinteracting Particle-Antiparticle System of Bosons, Phys. Rev. C 105, 045205 (2022).
  8. D. Anchishkin, Single-particle spectra in relativistic heavy-ion collisions within the thermal quantum field theory, J. Phys. G: Nucl. Part. Phys. 49, 055109 (2022).
  9. Babenko V. A., Petrov N. M. On the quartic anharmonic oscillator and the Padé-approximant averaging method. Mod. Phys. Lett. A, 2022, Vol. 37, No. 25, 2250172. [DOI: https://doi.org/10.1142/S0217732322501723]
  10. Yurii A. Sitenko, Volodymyr M. Gorkavenko, and Maria S. Tsarenkova, Magnetic flux in the vacuum of quantum bosonic matter in the cosmic string background, Phys. Rev. D 2022,Vol. 106, No. 10, 105010 (20 pp.). DOI: 10.1103/PhysRevD.106.105010.
  11. V.M. Gorkavenko, Т.V. Gorkavenko, Yu.A. Sitenko, and M.S. Tsarenkova, Induced vacuum current and magnetic flux in quantum scalar matter in the background of a vortex defect with the Neumann boundary condition, Ukr. J. Phys. 2022, Vol. 67, No. 1, 3-10.
Preprints
  1. B.E. Grinyuk, K.A. Bugaev. About Conditions of Spatial Collapse in an Infinite System of Bose Particles. arXiv:2201.07900v1[cond-mat.quant-gas] 19 Jan 2022
  2. B.E. Grinyuk. Can Nuclear Matter Consist of α-Particles? arXiv: 2202.07724 [nucl-th] 15 Feb 2022
  3. B.E. Grinyuk, D.V. Piatnytskyi, V.S.Vasilevsky. The lowest excited states of 14C and 14O nuclei within a five-cluster model. arXiv:2210.15891v1 [nucl-th] 28 Oct 2022
  4. V.M. Gorkavenko, Т.V. Gorkavenko, Yu.A. Sitenko, and M.S. Tsarenkova, Induced vacuum energy density of quantum charged scalar matter in the background of an impenetrable magnetic tube with the Neumann boundary condition, arXiv:2212.03801 [hep-th] (2022).
  5. V.E. Kuzmichev, V.V. Kuzmichev. "The Hubble tension from the standpoint of quantum cosmology", arXiv:2211.16394 [gr-qc] (2022).
Articles in journals, other publications
  1. Yu.A. Sitenko. Induced vacuum magnetic field in the comic string background, Phys. Rev. D 2019, Vol. 104, No.4, 045013 (P.1-29). (Q1) https://doi.org/10.1103/PhysRevD.104.045013
  2. V.E. Kuzmichev, V.V. Kuzmichev. "Classical behavior of a quantum particle in a refringent medium", American Journal of Physics, Vol. 89 (8), p. 793-798, 2021. (Q3/Q4) DOI: 10.1119/10.0003966
  3. Бабенко В. А., Петров Н. М. Про квантовий ангармонічний осцилятор та апроксимації Паде. Ядерна фізика та енергетика, 2021, т. 22, № 2, с. 127–142. [Babenko V. A., Petrov N. M. On the Quantum Anharmonic Oscillator and Padé Approximations. Nuclear Physics and Atomic Energy, 2021, Vol. 22, No. 2, P. 127–142.] (Q3) https://doi.org/10.15407/jnpae2021.02.127
  4. D. Anchishkin, V. Gnatovskyy, D. Zhuravel, V. Karpenko, Relativistic Selfinteracting Particle-Antiparticle System of Bosons. Journal of Phys. and Electr. 28 (2), 3-18 (2020). DOI 10.15421/332016
  5. O.S. Stashko, D.V. Anchishkin, O.V. Savchuk, M.I. Gorenstein, Thermodynamic properties of interacting bosons with zero chemical potential. Journal of Phys. G: Nucl. Part. Phys. 48, No.5, 055106 (2021), (Q2). DOI: 10.1088/1361-6471/abd5a5
  6. K. A. Bugaev, O. V. Vitiuk, B. E. Grinyuk, N. S. Yakovenko, E. S. Zherebtsova, V. V. Sagun, O. I. Ivanytskyi, D. O. Savchenko, L. V. Bravina, D. B. Blaschke, G. R. Farrar, S. Kabana, S. V. Kuleshov, E. G. Nikonov, A.V.Taranenko, E. E. Zabrodin, and G. M. Zinovjev. Chemical freeze-out of light nuclei in high energy nuclear collisions and resolution of the hyper-triton chemical freeze-out puzzle. –J. Phys.: Conf. Ser. 1690 (2020) 012123 (6 p.) doi: 10.1088/1742-6596/1690/1/012123
  7. David Blashke, Larissa Bravina, Kyryll Bugaev, Glenis R. Farrar, Boris Grinyuk, Oleksii Ivanitskyi, Sonya Kabana, Sergey V. Kuleshov, Irina K. Potashnikova, Violetta Sagun, Arkadiy Taranenko, Oleksandr V.Vitiuk, Evgeny Zabrodin, Xiaoming Zhang, Daicui Zhou. Thermal production of sexaquarks in heavy-ion collisions. International Journal of Modern Physics A Vol. 36, No. 25, 2141005 (2021). (Q3/Q4) https://doi.org/10.1142/S0217751X21410050
  8. B. E. Grinyuk, K. A. Bugaev. About Conditions of Spatial Collapse in an Infinite System of Bose Particles. УФЖ, 2021, т. 66, № 12, с. 1024-1026 (Q4) https://doi.org/10.15407/ujpe66.12.1024
  9. A.V. Nesterov, Yu. A. Lashko, V. S. Vasilevsky, "Structure of the ground and excited states in Λ9Be nucleus", Nucl. Phys. A, vol. 1016 (2021) 122325 (24 pp.) (Q1/Q2) https://doi.org/10.1016/j.nuclphysa.2021.122325
  10. A.V. Nesterov, M. Solokha-Klymchak. "Properties of 4ΛH hypernucleus in three-cluster microscopic models", Ukr. J. Phys., vol. 66 (2021) № 10, p. 846-856 (Q3/Q4) https://doi.org/10.15407/ujpe66.10.846
  11. Н. Калжигитов, В.С. Василевский, Н.Ж. Такибаев, В.O. Курмангалиева. "Исследование эффектов кластерной поляризации в ядре 6Li", Известия НАН Республики Казахстан. Серия физ.-мат., т. 5 (2021) № 339, с. 25–32. https://doi.org/10.32014/2021.2518-1726.81
Preprints
  1. V.F. Kharchenko, Coulomb transition matrix with fractional values of interaction parameter, arXiv: 2105.13092 v1 [quant-ph] 27 May 2021, p.p. 1-4.
  2. D. Anchishkin, V. Gnatovskyy, D. Zhuravel, V. Karpenko, Selfinteracting Particle-Antiparticle System of Bosons, arXiv: 2102.02529 [nucl-th].
  3. K.A. Bugaev, O.V. Vitiuk, B.E. Grinyuk, P.P. Panasiuk, N.S. Yakovenko, E.S. Zherebtsova, V.V. Sagun, O.I. Ivanytskyi, L.V. Bravina, D.B. Blaschke, S. Kabana, S.V. Kuleshov, A.V. Taranenko, E.E. Zabrodin, and G.M. Zinovjev. Induced surface and curvature tension equation of state for hadron resonance gas in finite volumes and its relation to morphological thermodynamics. arXiv: 2104.05351v1 [hep-ph].
  4. Oleksandr V. Vitiuk, V.M. Pugatch, K.A. Bugaev, P.P. Panasiuk, Nazar Yakovenko, Boris Grinyuk, E.S. Zherebtsova, M. Blricher, L.V. Bravina, A.V. Taranenko, E.E. Zabrodin. Triple nuclear collisions – a new method to explore the matter properties under new extreme conditions. arXiv: 2108.02711v1 [hep-ph].
Articles in journals, other publications
  1. V.F. Kharchenko. Analytical solutions for three-dimensional Coulomb transition matrix at negative energy and integer values of interaction parameter. – Canadian Journal of Physics, Vol. 98, No.4, 375-378(2020) https://doi.org/10.1139/cjp-2019-0338
  2. V.E. Kuzmichev, V.V. Kuzmichev. Uncertainty principle in quantum mechanics with Newton's gravity. – Eur. Phys. J. C, Vol. 80, No. 3, p. 248 (7 p.), 2020.
  3. B.E. Grinyuk, I.V. Simenog. On the Temperature Role in the Tunneling Process at the Low-Energy Nuclear Fusion. – Ukr. J. Phys. 2020, Vol.65, No. 11, p. 958-962.
  4. D. Zhuravel, D. Anchishkin, R. Hayn, P. Lombardo, St. Schäfer. Non-equilibrium electronic transport through a quantum dot with strong Coulomb repulsion in the presence of a magnetic field. – J. Phys.: Condens. Matter. 32, No. 16, p.165601 (2020).
  5. D. Duisenbay, N. Kalzhigitov, K. Katō, V.O. Kurmangaliyeva, N.Zh. Takibayev, V.S. Vasilevsky. Effects of the Coulomb interaction on parameters of resonance states in mirror three-cluster nuclei. – Nucl. Phys. A, 2020, vol. 996, 121692, (30 pp).
  6. V.S. Vasilevsky, Yu.A. Lashko. How the antisymmetrization affects a cluster-cluster interaction: two-cluster systems. –Ann. Phys., vol. 415, 168114, (22 pp) 2020.
  7. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov. Influence of the Pauli principle on two-cluster potential energy. – In Proc. of the 24th European conference on few-body problems in physics, 2-4 September, 2019, the University of Surrey,Guildford, UK, SciPost Phys. Proc., 2020, vol. 3, 021, 9 pp.
  8. N. Kalzhigitov, N.Zh. Takibayev, V.S. Vasilevsky, E.M. Akzhigitova, V.O. Kurmangaliyeva. A microscopic two-cluster model of processes in 6Li. – News of the National Academy of sciences of the Republic of Kazakhstan, Phys.-Math. Series, 2020, vol. 4, N 332, pp. 86-94.
  9. S.Ya. Goroshenko, A.V. Nesterov, V.A. Nesterov. Complete numerical calculation of the interaction energy for two uniformly charged spheroids. Example of heavy ions. – Nucl. Phys. At. Energy, 21 (2020), 13-20.
  10. N. Takibayev, V.O. Kurmangaliyeva, K. Katō, V.S. Vasilevsky. Few-Body Reactions and Processes in Neutron Star Envelopes. –Springer Proceedings in Physics, 2020, vol. 238, pp. 157–161.
  11. Pierre Lombardo, Roland Hayn, Denis Zhuravel, Steffen Schäfer. Kondo-assisted switching between three conduction states in capacitively coupled quantum dots. – Phys. Rev. Research 2, 033387 (2020). doi: 10.1103/PhysRevResearch.2.033387
  12. K.A. Bugaev, A.I. Ivanitskyi, B.E. Grinyuk, I.P. Yakimenko. Bose-Einstein Condensation Phase Transition of Quantum Hard Spheres and New Relations between Bosonic and Fermionic Pressures. – Ukr. J. Phys. 2020, Vol.65, No. 11, p. 963-972.
  13. K.A. Bugaev, O.V. Vitiuk, B.E. Grinyuk, V.V. Sagun, N.S. Yakovenko, O.I. Ivanitskyi, G.M. Zinovjev, D.B. Blaschke, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, S. Kabana, S.V. Kuleshov, G.R. Farrar, E.S. Zherebtsova and A.V. Taranenko. Second virial coefficients of light nuclear clusters and their chemical freeze-out in nuclear collisions. – Euro. Phys. J. A 56, 293—1-15 (2020).
Preprints
  1. B.E. Grinyuk, K.A. Bugaev, V.V. Sagun, O.I. Ivanytskyi, D.L. Borisyuk, A.S. Zhokhin, G.M. Zinovjev, D.B. Blaschke, L.V. Bravina, E.E. Zabrodin, E. G. Nikonov, G. Farrar, S. Kabana, S.V. Kuleshov and A.V. Taranenko. Classical excluded volumes of loosely bound light (anti)nuclei and their chemical freeze-out in heavy ion collisions. – Int. J. Mod. Phys. E, p. 1-15; arXiv:2004.05481v1 [hep-ph] (2020).
  2. V.O. Kurmangaliyeva, N. Kalzhigitov, N. Takibayev, V.S. Vasilevsky. Resonance structure of 8Be with the two-cluster resonating group method. – а ArXiv e-prints nucl-th/2006.04525, (35 pp.), 2020.
  3. K.A. Bugaev, O.V. Vitiuk, B.E. Grinyuk, N.S. Yakovenko, E.S. Zherebtsova, V.V. Sagun, O.I. Ivanytskyi, D.O. Savchenko, L.V. Bravina, D.B. Blaschke, G.R. Farrar, S. Kabana, S.V. Kuleshov, E.G. Nikonov, A.V. Taranenko, E.E. Zabrodin, and G.M. Zinovjev. Chemical freeze-out of light nuclei in high energy nuclear collisions and resolution of the hyper-triton chemical freeze-out puzzle. – arXiv: 2011.09292v1 [nucl-th], 6 p., 18 Nov 2020.
  4. V.E. Kuzmichev, V.V. Kuzmichev. On the conditions for the classicality of a quantum particle. – arXiv:2007.11886 [quant-ph], 12p.
Papers at conferences and seminars
  1. K.A. Bugaev, B.E. Grinyuk, A.I. Ivanytskyi, V.V. Sagun, D.O. Savchenko, G.M. Zinovjev, O.V. Vitiuk, N.S. Yakovenko, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, S. Kabana, D.B. Blaschke, A.V. Taranenko and E.S. Zherebtsova, «Multiplicities of light nuclear clusters in high energy nuclear collisions and solution of the hyper-triton puzzle» at the International Conference on New Frontiers in Physics (ICNFP2020), Kolymbari, Crete, Greece, September 4-12, 2020 (запрошена секційна за проектом No. 0120U100935).
  2. K.A. Bugaev, B.E. Grinyuk, A.I. Ivanytskyi, V.V. Sagun, D.O. Savchenko, G.M. Zinovjev, O.V. Vitiuk, N.S. Yakovenko, E.G. Nikon, L.V. Bravina, E.E. Zabrodin, S. Kabana, D.B. Blaschke, A.V. Taranenko and E.S. Zherebtsova, «Chemical freeze-out of light nuclei in high energy nuclear collisions and resolution of the hyper-triton chemical freeze-out puzzle», invited seminar at the Kyiv Institute for Nuclear Research, Department of High Energy Physics, Kyiv, October 29, 2020 (запрошений семінар за проектом No. ЦО-5-1/2018 цільової програми).
Articles in journals, other publications
  1. Yu.A. Sitenko, V.M. Gorkavenko. Induced vacuum magnetic flux in quantum spinor matter in the background of a topological defect in two-dimensional space, Phys. Rev. D 2019, Vol. 100, No.8, 085011 (P.1-36).
  2. Yu.A. Sitenko, V.M. Gorkavenko. Polarization of the vacuum of quantized spinor field by a topological defect in two-dimensional space, Ukr. J. Phys. 2019, Vol. 64, No. 11, 1069-1077 (Укр. фіз. журн. 2019, Vol. 64, No. 11, 1062-1069).
  3. V.E. Kuzmichev, V.V. Kuzmichev. Generalized uncertainty principle in quantum cosmology for the maximally symmetric space, Ukr. J. Phys., 2019, Vol. 64, No. 2, p. 100-108.
  4. В.Є. Кузьмичов, В.В. Кузьмичов. Узагальнений принцип невизначеності у квантовій космології, УФЖ, 2019, Vol. 64, No. 11, p. 1043-1046.
  5. В.Є. Кузьмичов, В.В. Кузьмичов. Квантові поправки до динаміки гравітаційної системи, УФЖ, 2019, Vol. 64, No. 12, p. 1135-1139.
  6. Babenko V., Pavlovych V., Gulik V. The pulsed subcritical amplifier of neutron flux driven by high-intensity neutron generator. Nuclear Technology and Radiation Protection, 2019, Vol. 34, No. 1, P. 1–12.
  7. Бабенко В.А., Петров Н.М. О свойствах бегущей константы связи сильного взаимодействия в области низких энергий. Ядерна фізика та енергетика, 2019, т. 20, № 1, с. 5–17. [Babenko V.A., Petrov N.M. Properties of the running coupling constant of strong interaction at low energies. Nuclear Physics and Atomic Energy, 2019, Vol. 20, No. 1, P. 5–17.]
  8. Бабенко В.А., Петров Н.М. О нарушении зарядовой независимости и зарядовой симметрии константы пион-нуклонной связи. Ядерная Физика, 2019, т. 82, № 6, с. 541–552. [Babenko V.A., Petrov N.M. On the breakdown of charge independence and charge symmetry of the pion-nucleon coupling constant. Physics of Atomic Nuclei, 2019, Vol. 82, No. 6, P. 662–672.]
  9. K.A. Bugaev, B.E. Grinyuk, A.I. Ivanytskyi, V.V. Sagun, D.O. Savchenko, G.M. Zinovjev, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, D.B. Blaschke, S. Kabana, A.V. Taranenko. On separate chemical freeze-outs of hadrons and light (anti)nuclei in high energy nuclear collisions. 2019, J.Phys.: Conf.Ser. 1390 012038 doi: 10.1088/1742-6596/1390/1/012038
  10. K. Bugaev, A. Ivanytskyi, V. Sagun, B. Grinyuk, D. Savchenko, G. Zinovjev, E. Nikonov, L. Bravina, E. Zabrodin, D. Blaschke, A. Taranenko, L. Turko. Hard-Core Radius of Nucleons within the Induced Surface Tension Approach, Universe 5 (2), 63 (2019).
  11. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov. Properties of a potential energy matrix in oscillator basis,Ann. Phys., 2019, vol. 409, 167930, (26 pp.)
  12. V.S. Vasilevsky, K.Katō. On three-cluster disintegration of 9Ве, Phys. Sci. Thechnol., 2019, vol. 6, № 1, pp. 4-10.
  13. A.D. Duisenbay, N.Zh. Takibayev, V.S. Vasilevsky, V.O. Kurmangaliyeva, E.M. Akzhigitova. Form factors and density distributions of protons and neutrons in 7Li and 7Be, News of the National Academy of sciences of the Republic of Kazakhstan, Phys.-Math. Series, 2019, vol. 3, N 325, pp. 71-76.
Preprints
  1. V.F. Kharchenko. Coulomb transition matrix at negative energy and integer values of interaction parameter, arXiv: 1905.13479 [quant-ph] 31 May 2019. p.p. 1 - 7.
  2. V.E. Kuzmichev, V.V. Kuzmichev. Uncertainty principle in quantum mechanics with Newton's gravity, arXiv:1911.01176 [quant-ph] (2019), 10 p.
  3. Babenko V.A., Petrov N.M. On the Charge Dependence of the Pion-Nucleon Coupling Constant and Nucleon-Nucleon Low-Energy Scattering Parameters. arXiv:1908.10124 [hep-ph], 2019, 13 P.
  4. A.D. Duisenbay, N. Kalzhigitov, K. Katō, V.O. Kurmangaliyeva, N.Zh. Takibayev, V.S. Vasilevsky. Effects of the Coulomb interaction on parameters of resonance states in mirror three-cluster nuclei. arXiv: nucl-th/1905.07711, (54pp), 2019.
  5. V.S. Vasilevsky, Yu.A. Lashko. How the antisymmetrization affects a cluster-cluster interaction: two-cluster systems, arXiv: nucl-th/1909.07610, (45 pp), 2019.
Papers at conferences and seminars
  1. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov.Influence of the Pauli principle on two-cluster potential energy.In Proc. of the 24th European conference on few-body problems in physics, 2-4 September, 2019, the University of Surrey,Guildford, UK, arXiv: nucl-th/1910.005046, (10 pp), 2019.
  2. S.Ya. Goroshchenko, A.V. Nesterov, V.A. Nesterov Complete numerical calculation of the interaction energy for two uniformly charged spheroids. Example of heavy ions. Abstracts of Conference Problems of theoretical and mathematical physics, September 24-26, 2019, Kyiv, Ukraine. P. 77.
  3. V.S. Vasilevsky, B.E. Grinyuk, D.V. Piatnytskyi. Structure Features of Mirror Nuclei 14С and 14О within a Five-Cluster Model. – Book of Abstructs of the Bogolyubov Kyiv Conference Problems of Theoretical and Mathematical Physics, 24-26 of September, Kyiv, 2019, p.81.
  4. Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky, Two-cluster potential energy and the Pauli principle, accepted for publication in Proc. of the 38th International Workshop on Nuclear Theory, June 23 – 29, 2019, Rila Mountains, Bulgaria, Heron Press, Sofia, Bulgaria, 2019.
  5. Yu.A. Sitenko. Field-theoretical formalism for quantum systems in extreme conditions (запрошена), Різдвяні дискусії 2019, Кафедра теоретичної фізики Львівського національного університету ім. Івана Франка, Львів, 10-11 січня 2019.
  6. Yu.A. Sitenko, V.M. Gorkavenko. Polarization of the vacuum of quantized spinor field by a topological defect in two-dimensional space (пленарна), XI Bolyai-Gauss-Lobachevsky Conference Non-Euclidean, non-commutative geometry and Quantum Physics, ІТФ НАН України, Київ, 19-24 травня 2019.
  7. Ю.A. Ситенко. Релятивістична квантова ферміонна матерія в екстремальних умовах (запрошена), Cемінар пам'яті П.І. Фоміна КВАНТОВА ТЕОРІЯ ПОЛЯ ТА КОСМОЛОГІЯ, Інститут прикладної фізики НАН України, Суми, 20 червня 2019.
  8. Yu.A. Sitenko. Quantum relativistic fermion matter in particle, astroparticle and condensed matter physics (запрошена), SEENET-MTP Assessment Meeting, ICTP, Trieste, Italy, 20-23 October 2019.
  9. V.V. Kuzmichev, V.E. Kuzmichev. Quantum corrections to the dynamics of the gravitational system in quantum cosmology XI Bolyai-Gauss-Lobachevsky (BGL-2019) Conference: Non-Euclidean, Non-Commutative Geometry and Quantum Physics (Kiev, Ukraine, May 19-24, 2019). Book of Abstracts. p. 22 (пленарна доповідь)
  10. V.E. Kuzmichev, V.V. Kuzmichev. Generalized uncertainty principle in quantum cosmology XI Bolyai-Gauss-Lobachevsky (BGL-2019) Conference: Non-Euclidean, Non-Commutative Geometry and Quantum Physics (Kiev, Ukraine, May 19-24, 2019). Book of Abstracts. p. 23 (пленарна доповідь)
  11. V.V. Kuzmichev, V.E. Kuzmichev. The matter-energy intensity distribution in a quantum gravitational system Bogolyubov Kyiv Conference Problems of Theoretical and Mathematical Physics (Kiev, Ukraine, September 24-26, 2019). Program & Abstracts. p. 31 (пленарна доповідь)
  12. Бабенко В.О., Петров М.М. Стосовно порушення зарядової незалежності та зарядової симетрії ядерних сил. Семінар пам'яті І. В. Сименога, 31 січня 2019 р., Інститут теоретичної фізики НАН України, Київ. (усна доповідь).
  13. Б.Є. Гринюк. 80 років від дня народження Івана Васильовича Сименога, науковця і вчителя. – Семінар, присвячений пам'яті Івана Васильовича Сименога. ІТФ ім.М.М.Боголюбова НАН України, 31 січня 2019 р., Київ. (усна доповідь)
  14. K.A. Bugaev, A.I. Ivanytskyi, V.V. Sagun, B.E. Grinyuk, D.O. Savchenko, G.M. Zinovjev, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, D.B. Blaschke, S. Kabana, and A.V. Taranenko. Possible signals of two QCD phase transitions at NICA-FAIR energies. EPJ Web of Conferences 204, 03001 (2019). doi:10.1051/epjconf/201920403001
  15. Б.Є. Гринюк, В.С. Василевський, Д.В. П'ятницький. Особливості структури найнижчих збуджених станів дзеркальних ядер 14С і 14О. – Семінар Проблеми теоретичної фізики, присвячений пам'яті академіка Олексія Ситенка. ІТФ ім. М. М. Боголюбова НАН України, 14 лютого 2019 р., Київ. (усна доповідь)
  16. V.S. Vasilevsky, B.E. Grinyuk, D. V. Piatnytskyi. Structure Features of Mirror Nuclei 14С and 14О within a Five-Cluster Model. – Bogolyubov Kyiv Conference Problems of Theoretical and Mathematical Physics, 24-26 of September, Kyiv. (стендова)
  17. D. Blaschke, L. Bravina, K. Bugaev, G. Farrar, B. Grinyuk, O. Ivanytskyi, S. Kabana, V. Sagun, A. Taranenko, E. Zabrodin, Xiaoming Zhang, and Daicui Zhou. Thermal Production of Sexaquarks in Heavy Ion Collisions. – Quark Matter 2019 (the XXVIII International Conference on Ultrarelativistic Nucleus-Nucleus Collisions), 3-9 of November, Wuhan, China, 2019. (poster)
  18. K.A. Bugaev, V.V. Sagun, B.E. Grinyuk, A.S. Zhokhin, A.I. Ivanytskyi, D.A. Savchenko, G.M. Zinovjev, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, S. Kabana, D.B. Blaschke and A.V. Taranenko, Updated signals of two QCD phase transitions in heavy ion collisions, at the 8-th International Conference on New Frontiers in Physics (ICNFP2019), Kolymbari, Crete, Greece, August 21-29, 2019. (invited section lecture)
  19. K.A. Bugaev, B.E. Grinyuk, A.I. Ivanytskyi, V.V. Sagun, A.S. Zhokhin, D.A. Savchenko, G.M. Zinovjev, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, S. Kabana, D.B. Blaschke and A.V. Taranenko, Classical excluded volume of loosely bound light (anti)nuclei and their chemical freeze-out in HIC, at the 8-th International Conference on New Frontiers in Physics (ICNFP2019), Kolymbari, Crete, Greece, August 21-29, 2019. (invited section talk)
  20. D. Blaschke, L. Bravina, K. Bugaev, G. Farrar, B. Grinyuk, O. Ivanytskyi, S. Kabana, V. Sagun, A.Taranenko, E. Zabrodin, Xiaoming Zhang and Daicui Zhou, Thermal production of Sexaquarks in Heavy Ion Collisions, at the 8-th International Conference on New Frontiers in Physics (ICNFP2019), Kolymbari, Crete, Greece, August 21-29, 2019. (invited section talk)
  21. K.A. Bugaev, V.V. Sagun, B.E. Grinyuk, A.S. Zhokhin, A.I. Ivanytskyi, D.A. Savchenko, G.M. Zinovjev, E.G. Nikonov, L.V. Bravina, E.E. Zabrodin, S. Kabana, D.B. Blaschke and A.V. Taranenko, Heavy ion collisions at NICA-FAIR energies and possible signals of two QCD phase transitions, at The II International Workshop on Theory of Hadronic Matter Under Extreme Conditions, Dubna, JINR, Russian Federation, 16-19 September 2019. (invited plenary talk)
  22. Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky, Two-cluster potential energy and the Pauli principle, 38th International Workshop on Nuclear Theory, June 23 – 29, 2019, Rila Mountains, Bulgaria, 2019 (пленарна).
  23. Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky, Influence of the Pauli principle on two-cluster potential energy, 24th European Few Body Conference, September 2-6, 2019, Guildford, Surrey, United Kingdom (усна доповідь).
  24. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov, Role of the Pauli principle in cluster-cluster interaction, Bogolyubov Kyiv Conference Problems of theoretical and mathematical physics, Kyiv, September 24-26, 2019 (усна доповідь).
  25. Ю.А. Лашко, В.С. Василевський, Г.Ф. Філіппов. Властивості матриці потенціальної енергії двочастинкової системи, Семінар присвячений памяті І. В. Сименога,ІТФ ім. М.М. Боголюбова НАН України, 31січня 2019 р. (Пленарна).
  26. В.С. Василевський, К. Като. Загадковий резонанс та фоторозщеплення 9Ве, Семінар Проблеми теоретичної фізики присвячений пам'яті академіка О.Г. Ситенка, ІТФ ім. М.М. Боголюбова НАН України, 14лютого 2019 р. (Пленарна).
  27. A.D. Duisenbay, N. Kalzhigitov, K. Katō, V.O. Kurmangaliyeva, N.Zh. Takibayev, V.S. Vasilevsky. Effects of the Coulomb interaction on parameters of resonance states in mirror three-cluster nuclei, The 6th International workshop Nuclear Physics, Nuclear Astrophysics and Cosmic Rays,Almaty, Kazakhstan, 14-18 April, 2019. (Пленарна).
  28. A.D. Duisenbay, N.Zh. Takibayev, V.S. Vasilevsky. Application of the resonating group method for studying the structure and reactions in 7Li and 7Be, The 6th International Workshop Nuclear Physics, Nuclear Astrophysics and Cosmic Rays, Almaty, Kazakhstan, 16-18 April 2019, Al-Farabi Kazakh National University.(Пленарна).
  29. N. Kalzhigitov, N.Zh. Takibayev, V.S. Vasilevsky Investigation of processes in 6Li within the resonating group method., The 6th International Workshop Nuclear Physics, Nuclear Astrophysics and Cosmic Rays, Almaty, Kazakhstan, 16-18April 2019,Al-Farabi Kazakh National University. (Пленарна).
  30. K. Katō, N. Takibayev, V.S. Vasilevsky. Symplectic Coherent-State Basis in the OCM Calculations of Nuclear Cluster System,The 6th International workshop Nuclear Physics,Nuclear Astrophysics and Cosmic Rays,Almaty, Kazakhstan, 14-18 April, 2019,Al-Farabi Kazakh National University. (Пленарна).
  31. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov. Two-Cluster Potential Energy and the Pauli Principle. In Proc. of the 36th International Workshop on Nuclear Theory, 25 June – 1 July 2019, the Rila Mountains, Bulgaria, Book of Abstracts p.25. (Пленарна).
  32. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov. Influence of the Pauli principle on two-cluster potential energy.The 24th European conference on few-body problems in physics, 2-4 September, 2019, the University of Surrey,Guildford, UK. (усна).
  33. V.S. Vasilevsky, A.D. Duisenbay, N. Kalzhigitov, K. Katō, V.O. Kurmangaliyeva, N.Zh. Takibayev. Effects of the Coulomb interaction on parameters of resonance states in mirror three-cluster nuclei, The Bogolyubov Kyiv Conference, Problems of Theoretical and Mathematical Physics, Bogolyubov Institute for Theoretical Physics, September 24-26, Kyiv,Ukraine. (усна).
  34. Yu.A. Lashko, V.S. Vasilevsky, G.F. Filippov. Role of the Pauli principle in cluster-cluster interactionThe Bogolyubov Kyiv Conference, Problems of Theoretical and Mathematical Physics, Bogolyubov Institute for Theoretical Physics, September 24-26, Kyiv,Ukraine.(усна).
  35. S.Ya. Goroshchenko, A.V. Nesterov, V.A. Nesterov, Conference Problems of theoretical and mathematical physics, September 24-26, 2019, Kyiv, Ukraine. P. (стендова).
Articles in journals, other publications
  1. Yu.A. Sitenko. Chiral effects in magnetized quantum spinor matter in particle and astroparticle physics, Intern. J. Mod. Phys. A, 2018, Vol.33, No. 34, 1845020 (13 pp.).
  2. Yu.A. Sitenko, V.M. Gorkavenko. Properties of the ground state of electronic excitations in carbon-like nanocones, Low Temp. Phys. 2018, Vol. 44, No. 12, 1261-1271 /Fiz. Nizk. Temp., 2018, Vol. 44, No. 12, 1618-1629.
  3. Yu.A. Sitenko, V.M. Gorkavenko. Non-Euclidean geometry, nontrivial topology and quantum vacuum effects, Universe, 2018, Vol. 4, No. 2, 23, (12 pp.).
  4. V.F. Kharchenko. Partial wave off-shell Coulombamplitudes at excited-state energy, Canadian Journal of Physics, Vol. 96, No.8 (2018 ) p.p. 933 - 937.
  5. В.А. Бабенко, Н.М. Петров. Об оценке массы странного кварка на основе экспериментальных данных об октете легчайших барионов. Ядерна фізика та енергетика, 2018, т. 19, № 3, с. 227-236. [Babenko V. A., Petrov N. M. On the estimation of the strange quark mass from the experimental data on the light baryon octet. Nuclear Physics and Atomic Energy, 2018, Vol. 19, No. 3, P. 227-236.].
  6. В.А. Бабенко, В.Н. Павлович. Изучение свойств самоподдерживающейся цепной ядерной реакции в топливосодержащих массах объекта Укрытие в случае переменной скорости поступления воды. Ядерна фізика та енергетика, 2018, т. 19, № 1, с. 21-30. [Babenko V.A., Pavlovych V N. Study of the properties of self-sustaining nuclear chain reaction in the fuel-containing masses of the Ukryttya object for the case of varying velocity of water inflow. Nuclear Physics and Atomic Energy, 2018, Vol. 19, No. 1, P. 21-30.]
  7. V.A. Babenko, V.I. Gulik, V.M. Pavlovych. The pulsed subcritical amplifier of neutron flux driven by high-intensity neutron generator. Nuclear Technology and Radiation Protection, 2018, Vol. 33, No. 3.
  8. V.E. Kuzmichev, V.V. Kuzmichev. Quantum dynamics of the early universe, Ukr. J. Phys., V. 63, No. 3, p. 196-203 (2018).
  9. V.E. Kuzmichev, V.V. Kuzmichev. The matter-energy intensity distribution in a quantum gravitational system, Quantum Stud.: Math. Found., V. 5, 245-255 (2018).
  10. V.S. Vasilevsky, Yu. A. Lashko, G.F. Filippov. Two- and three-cluster decays of light nuclei with the hyperspherical harmonics, Phys.Rev.C., 2018, vol. 97, p.064605 (16 pages)
  11. V.S. Vasilevsky, K. Katō, N. Takibayev.Systematic investigation of the Hoyle-analog states in light nuclei, Phys. Rev. C, vol. 98, N2, 024325, (14 pp), 2108;
Papers at conferences and seminars
  1. V.S. Vasilevsky, K. Katō, N. Takibayev. The Hoyle-analog states in light nuclei, Proc. of the 4th International workshop State of the Art in Nuclear Cluster Physics, Galveston, Texas, USA, 14-18 May, 2018, AIP Conference Proceeding, vol. 2038, N1, 020022(8 pp), 2018.
  2. Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky. Democratic and nondemocratic motion of three clusters with the hyperspherical harmonics. In Proc. of the 36th International Workshop on Nuclear Theory, 25 June - 1 July 2017, the Rila Mountains, Bulgaria, Heron Press, Sofia, Bulgaria, eds. M. Gaidarov and N. Minkov, 2017, vol. 36, pp. 244-253.
Articles in journals, other publications
  1. V.F. Kharchenko. Solution of the Lippmann-Schwinger equation for a partial wave transition matrix with repulsive Coulomb interaction, Ukr. J. Phys., Vol. 62 No.3 (2017) p.p. 263 - 270.
  2. V.E. Kuzmichev, V.V. Kuzmichev. Behaviour of the gravitational system close to the Planck epoch, Ukr. J. Phys., 2017, Vol. 62, No. 6, p. 545-553.
  3. V.E. Kuzmichev, V.V. Kuzmichev. The matter-energy intensity distribution in a quantum gravitational system, Quantum Stud.: Math. Found. (2017). https://doi.org/10.1007/s40509-017-0115-0
  4. Бабенко В.А., Петров Н.М. О связи между зарядовой и нейтральной константами пион-нуклонной связи в модели Юкавы. Письма в ЭЧАЯ, 2017, т. 14, № 1, с. 26-39.
  5. Бабенко В.А., Петров Н.М. О влиянии различия масс пи-мезонов (π±-π0) и нуклонов (n-p) на нарушение зарядовой независимости ядерных сил. Ядерна фізика та енергетика, 2017, т. 18, № 1, с. 13-21.
  6. Yu.A. Lashko, G.F. Filippov, V.S. Vasilevsky. Microscopic three-cluster model of 10Be, Nucl. Phys., A958, 2017, pp. 78-100.
  7. V.S. Vasilevsky, N.Zh. Takibayev, A.D. Duisenbay. Microscopic description of 8Li and 8B nuclei within three-cluster model, Ukr. J. Phys., 62, N6, 2017, pp. 461-472.
  8. V.S. Vasilevsky, K. Katō, N.Zh. Takibayev. Formation and decay of resonance states in 9Be and 9B nuclei. Microscopic three-cluster model investigations, Phys. Rev. C, 2017, 96, №3, 034322, 14 pp.
  9. K. Katō, V.S. Vasilevsky, N.Zh. Takibayev. Nuclear Cluster Dynamics in Nucleo-Synthesis in Neutron Stars, in book Neutron Stars. Physics, Properties and Dynamics, editors N. Zh. Takibayev and K. Boshkayev, Nova Science Publishers, Inc., New-York, Chapter 6, 2017, pp. 173-226.
  10. B.E. Grinyuk, D.V. Piatnytskyi. Structure of 14N nucleus within a five-cluster model. Ukr. J. Phys., vol. 62, № 10, 2017, p. 835-844.
Articles in journals, other publications
  1. Yu.A. Sitenko. Hot dense magnetized ultrarelativistic spinor matter in a slab, Phys.Rev.D - 2016. - V.94, No.8. - 085014 (P.1-14).
  2. Yu.A. Sitenko. On the chiral separation effect, Europhys.Lett. - 2016. - V.114, No.20. - 61001 (P.1-4).
  3. Yu.A. Sitenko. Self-adjointness and the Casimir effect with confined quantized spinor matter, J.Phys.Conf.Series - 2016 - V.670. - 012048 (P.1-15).
  4. V.M. Gorkavenko, I.V. Ivanchenko, Yu.A. Sitenko. Induced vacuum current and magnetic field in the background of a vortex, Intern.J.Mod.Phys.A - 2016 - V.31, No.6 - 1650017 (P.1-11).
  5. Yu.A. Sitenko. Hot dense magnetized spinor matter in particle and astroparticle physics: the role of boundaries, Odessa Astronomical Publications - 2016. - V.29. - 12-18.
  6. Yu.A.Sitenko, V.M.Gorkavenko, Self-adjoitness, confinement and the Casimir effect, Facta Universitatis. Series Physics, Chemistry and Technology - 2016 - V. 14, No. 3 - 319-335.
  7. V.F. Kharchenko. Analytical expressions for partial wave two-body Coulomb transition matrices at ground -state energy, Annals of Physics, Vol. 374 ( 2016 ) p.p. 16 - 26.
  8. Бабенко В.А., Петров Н.М. Изучение зарядовой зависимости пион-нуклонной константы связи с использованием данных о нуклон-нуклонном взаимодействии при низких энергиях. Ядерная Физика, 2016, т. 79, № 1, с. 8-12.
  9. Бабенко В.А., Петров Н.М. О нарушении изоспиновой инвариантности константы пион-нуклонной связи и длины нуклон-нуклонного рассеяния. Ядерна фізика та енергетика, 2016, т. 17, № 2, с. 143-149.
  10. Бабенко В.А., Петров Н.М. О связи между зарядовой и нейтральной константами пион-нуклонной связи в модели Юкавы. Письма в ЭЧАЯ, 2017, т. 14, № 1, с. 1-14.
  11. D.V. Piatnytskyi. Structure of 14C and 14О nuclei calculated in the variational approach. УФЖ, т. 61, № 8, 2016, с. 674-680.