NSR Query Results
Output year order : Descending NSR database version of March 21, 2024. Search: Author = O.A.Ponkratenko Found 102 matches. Showing 1 to 100. [Next]2023RU03 Iader.Fiz.Enerh. 24, 22 (2023) A.T.Rudchik, A.A.Rudchik, V.V.Khejlo, K.Rusek, K.W.Kemper, E.Piasecki, A.Stolarz, A.Trzcinska, V.M.Pirnak, O.A.Ponkratenko, E.I.Koshchy, O.E.Kutsyk, A.P.Ilyin, Y.M.Stepanenko, V.V.Uleshchenko, Y.O.Shyrma Reaction 10B(15N, 14C)11C at energy 81 MeV, spectroscopic factors and interaction of 14C + 11C nuclei NUCLEAR REACTIONS 10B(15N, 14C), E=81 MeV; measured reaction products; deduced σ(θ) within the coupled-reaction-channels (CRC) method. ICARE data.
doi: 10.15407/jnpae2023.01.022
2022ME03 Phys.Rev. C 105, 024615 (2022) S.Yu.Mezhevych, N.Keeley, A.T.Rudchik, K.Rusek, K.W.Kemper, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.B.Sakuta Extracting the asymptotic normalization coefficient for the 14C → 13B + p overlap from the 14C(11B, 12C)13B reaction NUCLEAR REACTIONS 14C(11B, 12C), (11B, 11B), E=45 MeV; analyzed σ, σ(θ); deduced asymptotic normalization coefficient for 14C and 13B+p overlap, spectroscopic factors. Coupled reaction channel (CRC) analysis.
doi: 10.1103/PhysRevC.105.024615
2022ME09 Iader.Fiz.Enerh. 23, 12 (2022) S.Yu.Mezhevych, A.T.Rudchik, K.Rusek, K.W.Kemper, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy Reaction 14C(11B, 12C)13B at Elab(11B) = 45 MeV, interaction of 13B + 12C versus that of 10, 11, 12B + 12C NUCLEAR REACTIONS 14C(11B, 12C)13B, E=45 MeV; measured reaction products; deduced σ(θ) using the coupled reaction channels (CRC) method, optical potential parameters; calculated spectroscopic amplitudes of transferred nucleons and clusters within the translational-invariant shell model. The Warsaw University cyclotron U-200P.
doi: 10.15407/jnpae2022.01.012
2022ME11 Iader.Fiz.Enerh. 23, 164 (2022) S.Yu.Mezhevych, A.T.Rudchik, O.A.Ponkratenko, K.Rusek, K.W.Kemper, V.M.Kyrianchuk, A.A.Rudchik, Yu.M.Stepanenko, V.V.Uleshchenko Potentials of interaction of 10, 11, 12, 13B isotopes with 12C NUCLEAR REACTIONS 12C(10B, 10B), E=41.3 MeV; 12C(11B, 11B), E=40 MeV; 13,14C(11B, 12C), E=45 MeV; calculated σ, parameters within the coupled-reaction-channels method (CRC) using previously deduced Woods-Saxon potentials.
doi: 10.15407/jnpae2022.03.164
2022PO13 Ukr.J.Phys. 67, 782 (2022) O.M.Povoroznyk, O.K.Gorpinich, O.A.Ponkratenko On the Peculiarities of Studying Unbound Excited States of 4He Nucleus by α + 3H Interaction NUCLEAR REACTIONS 3H(α, 2t), (α, t3He), (α, dt), E=67.2 MeV; measured reaction products. 4He; deduced σ(θ, E), excitation energies and energy widths of excited levels of 4He nucleus, resonance parameters. Evaluations by the Monte Carlo method.
doi: 10.15407/ujpe67.11.782
2022RU05 Phys.Rev. C 106, 014615 (2022) A.T.Rudchik, A.A.Rudchik, O.O.Chepurnov, K.W.Kemper, N.Keeley, K.Rusek, E.I.Koshchy, S.Kliczewski, S.Yu.Mezhevych, V.M.Pirnak, O.A.Ponkratenko, R.Siudak, H.M.Maridi, A.P.Ilyin, B.V.Mishchenko, Yu.M.Stepanenko, V.V.Uleshchenko, Yu.O.Shyrma, K.A.Chercas, B.Zalewski Comparison of 10B + 6Li and 10B + 7Li elastic scattering: The role of ground state reorientation and breakup NUCLEAR REACTIONS 6Li(10B, 10B), E=51 MeV; measured reaction products, angular distributions; deduced σ(θ), parameters of the optical model potentials, influence of the resonant states on the σ(E) of the α+d breakup. 7Li(10B, 10B), E=51 MeV; analyzed σ(E) and angular distributions from 2007RU13; deduced parameters of the optical model potentials, influence of the resonant states on the σ(E) of the α+t breakup. Comparison to coupled discretized continuum channel (CDCC) calculations. Setup consisting of solid state silicon detectors and gas-filled ionization chamber at U-200P cyclotron of the Heavy Ion Laboratory of the University of Warsaw.
doi: 10.1103/PhysRevC.106.014615
2022RU07 Iader.Fiz.Enerh. 23, 153 (2022) A.T.Rudchik, A.A.Rudchik, V.V.Khejlo, K.Rusek, K.W.Kemper, E.Piasecki, A.Stolarz, A.Trzcinska, V.M.Pirnak, O.A.Ponkratenko, E.I.Koshchy, O.E.Kutsyk, S.Y.Mezhevych, A.P.Ilyin, Y.M.Stepanenko, V.V.Uleshchenko, Y.O.Shyrma Elastic and inelastic scattering of 15N ions by 10B at energy 81 MeV. Isotopic effects in scattering of 15N + 10B, 15N + 11B 14N + 10B nuclei NUCLEAR REACTIONS 12C(15N, 15N), (15N, 15N'), E=81 MeV; measured reaction products; deduced σ(θ).
doi: 10.15407/jnpae2022.03.153
2021ME06 Acta Phys.Pol. B52, 109 (2021) S.Y.Mezhevych, A.T.Rudchik, A.A.Rudchik, K.W.Kemper, K.Rusek, O.A.Ponkratenko, E.I.Koshchy, S.B.Sakuta 14C(11B, 10B)15C Reaction at Elab = 45 MeV and the 10B+15C Optical Potential NUCLEAR REACTIONS 14C(11B, 10B), E=45 MeV; measured reaction products; deduced spectroscopic amplitudes, σ(θ), optical potential parameters.
doi: 10.5506/aphyspolb.52.109
2021RU08 Phys.Rev. C 103, 044614 (2021) A.T.Rudchik, A.A.Rudchik, O.O.Chepurnov, K.Rusek, N.Keeley, K.W.Kemper, S.Kliczewski, E.Piasecki, A.Trzcinska, Val.M.Pirnak, O.A.Ponkratenko, I.Strojek, E.I.Koshchy, R.Siudak, S.B.Sakuta, A.P.Ilyin, Yu.M.Stepanenko, Yu.O.Shyrma, V.V.Uleshchenko, K.A.Chercas, H.M.Maridi, N.Burtebayev 6Li + 15N interaction at Ec.m. = 23.1 MeV: Validation of the α + d cluster model of 6Li NUCLEAR REACTIONS 6Li(15N, 15N), (15N, 15N'), (15N, 6Li'), E=81 MeV from the U-200P cyclotron of University of Warsaw]; measured reaction products 15N and 6Li, σ(θ) using four ΔE-E telescopes of silicon detectors. 6Li; deduced differential cross sections for the resonances in 6Li, cluster structure of 6Li and the role of 6Li to α+d breakup. Comparison with optical model (OM), coupled-channel (CC) and coupled discretized continuum channel (CDCC) calculations using FRESCO code by including 6Li to α+d breakup, excitation of 15N levels, and the 15N(6Li, 7Li)14N one-neutron pickup reaction channel.
doi: 10.1103/PhysRevC.103.044614
2021RU10 Iader.Fiz.Enerh. 22, 230 (2021) A.T.Rudchik, A.A.Rudchik, O.O.Chepurnov, K.Rusek, K.W.Kemper, E.I.Koshchy, S.Yu.Mezhevych, Val.M.Pirnak, O.A.Ponkratenko, A.Stolarz, R.Siudak, A.P.Ilyin, Yu.M.Stepanenko, V.V.Uleshchenko, Yu.O.Shyrma 6Li(10B, 9Be)7Be reaction mechanisms. Structure and interaction of 9Be + 7Be nuclei NUCLEAR REACTIONS 6Li(10B, 9Be), E=51 MeV; measured reaction products; deduced σ(θ), spectroscopic factors. Comparison with coupled-reaction-channels method (CRC).
doi: 10.15407/jnpae2021.03.230
2020ME10 Acta Phys.Pol. B51, 1949 (2020) S.Y.Mezhevych, A.T.Rudchik, A.A.Rudchik, K.W.Kemper, K.Rusek, O.A.Ponkratenko, e.I.Koshchy, SB.Sakuta 13C(11B, 12C)12B Reaction at 45 MeV, 12C + 12B Interaction Versus that of 12C + 10, 11B NUCLEAR REACTIONS 13C(11B, 12C), E=45 MeV; measured reaction products, 12C, 12B; deduced parameters of WS optical potentials, spectroscopic amplitudes, σ(θ). Comparison with available data.
doi: 10.5506/APhysPolB.51.1949
2019RU01 Acta Phys.Pol. B50, 753 (2019) A.T.Rudchik, A.A.Rudchik, O.E.Kutsyk, K.W.Kemper, S.Kliczewski, K.Rusek, E.Piasecki, A.Trzcinska, E.I.Koshchy, Val.M.Pirnak, O.A.Ponkratenko, I.Strojek, V.A.Plujko, A.Stolarz, S.B.Sakuta, R.Siudak, O.V.Herashchenko, A.P.Ilyin, Yu.M.Stepanenko, Yu.O.Shyrma, V.V.Uleshchenko Elastic and Inelastic Scattering of 15N Ions by 12C at 81 MeV and the Effect of Transfer Channels NUCLEAR REACTIONS 12C(15N, 15N), (15N, 15N'), E=81 MeV; measured reaction products; deduced σ(θ), deformation parameters, parameters of Woods-Saxon potentials.
doi: 10.5506/APhysPolB.50.753
2019RU04 Nucl.Phys. A992, 121638 (2019) A.T.Rudchik, A.A.Rudchik, O.E.Kutsyk, K.W.Kemper, K.Rusek, E.Piasecki, A.Trzcinska, S.Kliczewski, E.I.Koshchy, Val.M.Pirnak, O.A.Ponkratenko, I.Strojek, V.A.Plujko, S.B.Sakuta, R.Siudak, A.P.Ilyin, Yu.M.Stepanenko, Yu.O.Shyrma, V.V.Uleshchenko 12C(15N, 14C)13N reaction at 81 MeV. Competition between one and two particle transfers
doi: 10.1016/j.nuclphysa.2019.121638
2018PO09 Acta Phys.Pol. B49, 313 (2018) O.A.Ponkratenko, E.I.Koshchy, Val.M.Pirnak, A.A.Rudchik, A.T.Rudchik, K.Rusek, Yu.M.Stepanenko, V.V.Uleshchenko, Yu.O.Shyrma Comparative Analysis of the Light Nuclei Diffractive Scattering on 12C NUCLEAR REACTIONS 12C(3He, 3He'), (α, α'), (6He, 6He'), (6Li, 6Li'), (7Li, 7Li'), (7Be, 7Be'), (8He, 8He'), (8B, 8B'), (8Li, 8Li'), (9Be, 9Be'), (10Be, 10Be'), (10B, 10B'), (11Li, 11Li'), (11Be, 11Be'), (11B, 11B'), (11C, 11C'), (12Be, 12Be'), (12C, 12C'), (13C, 13C'), (14N, 14N'), (16O, 16O'), (18O, 18O'), (20Ne, 20Ne'), E=1-200 MeV/nucleon; analyzed available data; deduced maxima of σ(Einc, θ), reduced diffraction radius rd.
doi: 10.5506/aphyspolb.49.313
2018RU03 Nucl.Phys. A971, 138 (2018) A.T.Rudchik, A.A.Rudchik, L.M.Muravynets, K.W.Kemper, K.Rusek, E.I.Koshchy, E.Piasecki, A.Trzcinska, Val.M.Pirnak, O.A.Ponkratenko, I.Strojek, A.Stolarz, V.A.Plujko, S.B.Sakuta, R.Siudak, A.P.Ilyin, Yu.M.Stepanenko, Yu.O.Shyrma, V.V.Uleshchenko 7Li(15N, 14C)8Be reaction at 81 MeV and 14C + 8Be interaction versus that of 13C + 8Be NUCLEAR REACTIONS 7Li(15N, 14C)8Be, E=81 MeV; measured reaction products angular distributions to 8Be gs and first two excited states; deduced σ(θ); calculated σ(θ) using CRC (Coupled Reaction Channels) FRESCO code with potential from earlier analyses and spectroscopic amplitudes using TISM (Translationally Invariant Shell Model) code DESNA. 8Be(14C, 13C), E not given;13C(8Be, 7Li), E not given; calculated σ(θ) using CRC; deduced WS potential parameters to be used for the 7Li(15N, 14C)8Be.
doi: 10.1016/j.nuclphysa.2018.01.014
2017ME04 Phys.Rev. C 95, 034607 (2017) S.Yu.Mezhevych, A.T.Rudchik, A.A.Rudchik, O.A.Ponkratenko, N.Keeley, K.W.Kemper, M.Mazzocco, K.Rusek, S.B.Sakuta Cluster structure of 17O NUCLEAR REACTIONS 13C(11B, 7Li)17O, E=45 MeV; measured particle spectra, σ(θ) using ΔE-E telescopes at the Heavy Ion Laboratory of the University of Warsawa; analyzed σ(θ) data by coupled-channel Born approximation (CCBA) calculations 17O; deduced levels, α+13C spectroscopic factors from a comparison of experimental data and the calculations at forward angles for the compound nucleus using code HELGA.
doi: 10.1103/PhysRevC.95.034607
2017RU01 Nucl.Phys. A958, 234 (2017) A.T.Rudchik, A.A.Rudchik, L.M.Muravynets, K.W.Kemper, K.Rusek, E.Piasecki, A.Trzcinska, E.I.Koshchy, Val.M.Pirnak, O.A.Ponkratenko, I.Strojek, A.Stolarz, O.V.Herashchenko, Yu.M.Stepanenko, V.A.Plujko, S.B.Sakuta, R.Siudak, A.Szczurek Elastic and inelastic scattering of 15N ions by 7Li at 81 MeV versus that of 14N ions by 7Li at 80 and 110 MeV NUCLEAR REACTIONS 7Li(15N, 15N), (15N, 15N'), E=81 MeV;7Li(14N, 14N), (14N, 14N'), E=80, 110 MeV. 7Li measured E(7Li), I(θ, 7Li) using ΔE-E Si telescopes; deduced σ(θ); calculated spectroscopic amplitudes, deformation. σ(θ), reaction σ using CC within TISM (Translational Invariant Shell Model); deduced potential parameters.
doi: 10.1016/j.nuclphysa.2016.12.007
2016RU02 Nucl.Phys. A947, 161 (2016) A.T.Rudchik, K.A.Chercas, K.W.Kemper, K.Rusek, A.A.Rudchik, O.V.Herashchenko, E.I.Koshchy, Val.M.Pirnak, E.Piasecki, A.Trzcinska, S.B.Sakuta, R.Siudak, I.Strojek, A.Stolarz, A.P.Ilyin, O.A.Ponkratenko, Yu.M.Stepanenko, Yu.O.Shyrma, A.Szczurek, V.V.Uleshchenko Elastic and inelastic scattering of 15N ions by 9Be at 84 MeV NUCLEAR REACTIONS 9Be(15N, 15N), (15N, 15N'), E=84 MeV; measured reaction products by four ΔE-E telescopes at different angles; deduced σ(θ) to discrete states; calculated 9Be+15N double-folding potential using M3Y potential and charge distribution in both nuclei from literature, σ(θ) using optical model and CRC; deduced reaction mechanism, potential parameters, deformation.
doi: 10.1016/j.nuclphysa.2016.01.002
2015RU05 Nucl.Phys. A939, 1 (2015) A.T.Rudchik, O.V.Herashchenko, K.W.Kemper, K.Rusek, S.Kliczewski, K.A.Chercas, A.A.Rudchik, E.I.Koshchy, Val.M.Pirnak, E.Piasecki, A.Trczinska, S.B.Sakuta, R.Siudak, I.Strojek, A.Stolarz, A.O.Barabash, A.P.Ilyin, O.A.Ponkratenko, Yu.M.Stepanenko, Yu.O.Shyrma, V.V.Uleshchenko, J.Choinski, A.Szczurek 15N elastic and inelastic scattering by 11B at 84 MeV NUCLEAR REACTIONS 11B(15N, 15N), (15N, 15N'), E=84 MeV;measured reaction products using ICARE set-up ΔE-E gas and semiconductor telescopes; deduced σ(θ); calculated σ(θ) using optical model and CC. 11B, 15N deduced deformation parameters, ground and excited states reorientation, potential parameters.
doi: 10.1016/j.nuclphysa.2015.02.006
2015RU06 Nucl.Phys. A941, 167 (2015) A.T.Rudchik, O.V.Herashchenko, K.W.Kemper, K.Rusek, S.Kliczewski, K.A.Chercas, A.A.Rudchik, E.I.Koshchy, Val.M.Pirnak, E.Piasecki, A.Trzcinska, S.B.Sakuta, R.Siudak, I.Strojek, A.Stolarz, S.O.Odzhikovskyi, A.P.Ilyin, O.A.Ponkratenko, Yu.M.Stepanenko, Yu.O.Shyrma, V.V.Uleshchenko, A.Szczurek Elastic and inelastic scattering of 14N ions by 11B at 88 MeV versus that of 15N + 11B at 84 MeV NUCLEAR REACTIONS 11B(14N, 14N), (14N, 14N'), E=88 MeV;11B(15N, 15N), E=84 MeV; measured nitrogen energy spectra at angles; deduced σ(θ); calculated σ(θ) using optical model and CC with reorientation and one- and two-step transfer reactions; deduced reaction mechanisms, optical model parameters, spectroscopic amplitudes for different (mainly d, t, 3He, α) clusters, deformation.
doi: 10.1016/j.nuclphysa.2015.06.012
2014RU01 Nucl.Phys. A922, 71 (2014) A.T.Rudchik, S.Kliczewski, K.A.Chercas, K.W.Kemper, E.I.Koshchy, K.Rusek, A.A.Rudchik, S.Yu.Mezhevych, V.M.Pirnak, V.A.Plujko, O.A.Ponkratenko, J.Choinski, B.Czech, R.Siudak, A.Szczurek, A.Stolarz, R.M.Zelinskyi Elastic and inelastic scattering of 6Li + 18O versus 7Li + 18O and 6Li + 16O NUCLEAR REACTIONS 6Li(18O, 18O), (18O, 18O'), E=114 MeV; measured E(particle), I(particle, θ) using ΔE-E Si telescopes; deduced σ(θ); calculated σ(θ), spectroscopic amplitudes of specified clusters using optical potential including one- and two-step transfers and parameters from CC analyses of nearby reactions. 6Li deduced deformation parameters. Compared to data and data of nearby reactions.
doi: 10.1016/j.nuclphysa.2013.10.013
2014RU06 Nucl.Phys. A927, 209 (2014) A.T.Rudchik, K.A.Chercas, K.W.Kemper, A.A.Rudchik, S.Kliczewski, E.I.Koshchy, K.Rusek, S.Yu.Mezhevych, O.A.Ponkratenko, Val.M.Pirnak, V.A.Plujko, J.Choinski, B.Czech, R.Siudak, A.Szczurek 6Li(18O, 17O)7Li reaction and comparison of 6, 7Li + 16, 17, 18O potentials NUCLEAR REACTIONS 6Li(18O, 17O), (18O, 18O), (18O, 18O'), E=114 MeV; measured reaction products. 7Li, 17O deduced σ(Eout, θ); calculated σ(Eout, θ) using CC; deduced spectroscopic amplitudes for various clusters, potential parameters.
doi: 10.1016/j.nuclphysa.2014.04.018
2014RU11 Eur.Phys.J. A 50, 159 (2014) A.T.Rudchik, O.V.Herashchenko, K.W.Kemper, K.Rusek, A.A.Rudchik, E.I.Koshchy, S.Kliczewski, S.Yu.Mezhevych, A.V.Mokhnach, Val.M.Pirnak, O.A.Ponkratenko, V.A.Plujko, J.Choinski, R.Siudak, A.Stolarz, A.Szczurek, A.P.Ilyin, V.V.Uleshchenko Elastic and inelastic scattering of 14N ions by 7Li at 80 MeV (c.m. 26.7 MeV) NUCLEAR REACTIONS 7Li(14N, 14N), (14N, 14N'), E=80 MeV; measured reaction products; deduced σ, σ(θ), spectroscopic amplitudes, parameters of the nucleus-nucleus potentials. Optical model and the coupled-reaction-channels method using a channels-coupling scheme.
doi: 10.1140/epja/i2014-14159-9
2013RU08 Eur.Phys.J. A 49, 74 (2013) A.T.Rudchik, R.M.Zelinskyi, K.W.Kemper, K.A.Chercas, A.A.Rudchik, V.M.Pirnak, V.A.Plujko, O.A.Ponkratenko Energy dependence of the 6Li + 16O elastic scattering versus that of 7Li + 16O NUCLEAR REACTIONS 16O(6Li, 6Li), E=4.5, 5.8, 9, 13, 20, 22.8, 25.7, 29.8, 30, 36, 48, 50.6 MeV;16O(7Li, 7Li), E=50 MeV; calculated, analyzed σ(θ) using optical model and coupled reaction channels; deduced potential parameters. Calculations compared to data.
doi: 10.1140/epja/i2013-13074-y
2012RU09 Iader.Fiz.Enerh. 13, 237 (2012) A.T.Rudchik, R.M.Zelinskyi, V.A.Plujko, A.P.Ilyin, Val.M.Pirnak, O.A.Ponkratenko, A.A.Rudchik, V.V.Uleschenko Energy dependence of the 6Li + 16O scattering and isotopic differences between potentials of the 6, 7Li + 16O interactions NUCLEAR REACTIONS 16O(6Li, 6Li), E(cm)=3.27-36.8 MeV; analyzedσ(θ); deduced optical model parameters, reaction mechanism features. Coupled reaction channels method.
doi: 10.15407/jnpae
2012RU10 Iader.Fiz.Enerh. 13, 246 (2012) A.T.Rudchik, O.V.Gerashchenko, A.A.Rudchik, E.I.Koshchy, S.Kliczewski, K.Rusek, S.Yu.Mezhevych, V.A.Plujko, O.A.Ponkratenko, Val.M.Pirnak, A.P.Ilyin, V.V.Uleshchenko, R.Siudak, J.Choinski, B.Czech, A.Szczurek Elastic and inelastic scattering of 14N ions by 7Li at 80 MeV NUCLEAR REACTIONS 7Li(14N, 14N), (14N, X), E=80 MeV; measured reaction products; deduced σ(θ), reaction mechanism features, optical model parameters. 7Li, 14N; deduced deformation parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2012RU11 Iader.Fiz.Enerh. 13, 361 (2012) A.T.Rudchik, R.M.Zelinskyi, A.A.Rudchik, Val.M.Pirnak, S.Kliczewski, E.I.Koshchy, K.Rusek, V.A.Plujko, O.A.Ponkratenko, S.Yu.Mezhevych, A.P.Ilyin, V.V.Uleschenko, R.Siudak, J.Choinski, B.Czech, A.Szczurek Elastic and inelastic scattering of 18O ions by 6Li at 114 MeV and isotopic differences of 6, 7Li + 18O and 6Li + 16, 18O nuclei interactions NUCLEAR REACTIONS 6Li(18O, 18O), (18O, X), E=114 MeV; measured reaction products; deduced σ(θ), reaction mechanism features, optical model parameters. 6Li, 18O; deduced deformation parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2012RU12 Iader.Fiz.Enerh. 13, 371 (2012) A.T.Rudchik, K.A.Chercas, A.A.Rudchik, E.I.Koshchy, S.Kliczewski, K.Rusek, V.A.Plujko, O.A.Ponkratenko, S.Yu.Mezhevych, Val.M.Pirnak, R.Sudak, J.Choinski, B.Czech, A.Szczurek The 6Li(18O, 17O)7Li reaction mechanisms and 7Li + 17O potential NUCLEAR REACTIONS 6Li(18O, 17O), E=114 MeV; measured reaction products; deduced σ(θ), reaction mechanism features, optical model parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2011RU01 Phys.Rev. C 83, 024606 (2011) A.T.Rudchik, Yu.M.Stepanenko, K.W.Kemper, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, A.Budzanowski, S.Yu.Mezhevych, I.Skwirczynska, R.Siudak, B.Czech, A.Szczurek, J.Choinski, L.Glowacka Comparison of the 7Li(18O, 17N)8Be and 18O(d, 3He)17N reactions NUCLEAR REACTIONS 7Li(18O, 17N)8Be, E=114 MeV; measured 17N spectra by E-ΔE method, σ(θ) for transitions to ground state of 8Be and to ground and excited states of 17N. 18O(d, 3He), (d, d), E=52 MeV; analyzed σ(θ) data for elastic scattering and for transitions to the excited states in 17N; deduced optical potentials for 17N+8Be and 17N+3He systems. Optical model analysis with in the coupled-reaction channels (CRC) method and using spectroscopic amplitudes from shell model calculations.
doi: 10.1103/PhysRevC.83.024606
2011RU04 Nucl.Phys. A852, 1 (2011) A.T.Rudchik, Yu.O.Shyrma, K.W.Kemper, K.Rusek, E.I.Koshchy, S.Kliczewski, B.G.Novatsky, O.A.Ponkratenko, E.Piasecki, G.P.Romanyshyna, Yu.M.Stepanenko, I.Strojek, S.B.Sakuta, A.Budzanowski, L.Glowacka, I.Skwirczynska, R.Siudak, J.Choinski, A.Szczurek Elastic and inelastic scattering of 13C + 18O versus 12C + 18O and 13C + 16O NUCLEAR REACTIONS 13C(18O, 18O), (18O, 18O'), E=105 MeV; measured elastic and inelastic σ(θ); deduced potential parameters, scattering mechanism features. Optical model and coupled-reaction-channels analysis. Comparison with other data.
doi: 10.1016/j.nuclphysa.2011.01.004
2011RU07 Eur.Phys.J. A 47, 50 (2011) A.T.Rudchik, Yu.O.Shyrma, K.W.Kemper, K.Rusek, E.I.Koshchy, S.Kliczewski, B.G.Novatsky, O.A.Ponkratenko, E.Piasecki, G.P.Romanyshyna, Yu.M.Stepanenko, I.Strojek, S.B.Sakuta, A.Budzanowski, L.Glowacka, I.Skwirczynska, R.Siudak, J.Choinski, A.Szczurek Elastic and inelastic scattering of 14C + 18O versus 12, 13C + 18O and 14C + 16O NUCLEAR REACTIONS 12,13,14C(18O, X), (18O, 18O), (18O, 18O') E=105 MeV; 14C(16O, 16O), E=132, 281 MeV; measured reaction products; deduced σ, σ(θ), optical model parameters. Coupled-reaction-channels method.
doi: 10.1140/epja/i2011-11050-3
2011RU08 Nucl.Phys. A860, 8 (2011) A.T.Rudchik, Yu.M.Stepanenko, K.W.Kemper, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, A.Budzanowski, S.Yu.Mezhevych, Val.M.Pirnak, B.Czech, R.Siudak, I.Skwirczynska, A.Szczurek, J.Choinski, L.Glowacka The 7Li(18O, 16N)9Be reaction and optical potential of 16N + 9Be versus 16O + 9Be NUCLEAR REACTIONS 7Li(18O, 16N), E=114 MeV;9Be(16O, 16O), E=15-32.2 MeV;16O(9Be, 9Be), E=20-167.7 MeV; measured E(particle), I(particle, θ) for oxygen-induced reactions; calculated σ(θ) using coupled channels; deduced σ(θ), optical model parameters for input and output channels, spectroscopic amplitudes. Comparison with other optical model calculations and with data.
doi: 10.1016/j.nuclphysa.2011.05.003
2011RU14 Iader.Fiz.Enerh. 12, 27 (2011); Nuc.phys.atom.energ. 12, 27 (2011) A.T.Rudchik, Yu.M.Stepanenko, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, A.Budzanowski, S.Yu.Mezhevych, I.Skwirczynska, R.Siudak, B.Czech, A.Szczurek, J.Choinski, L.Glowacka 7Li(18O, 16N)9Be reaction and the 17N + 8Be-potential NUCLEAR REACTIONS 7Li(18O, 16N)9Be, E=114 MeV; measured reaction products; deduced partial σ, optical model parameters, spectroscopic factors.
2010PO13 Iader.Fiz.Enerh. 11, 141 (2010) O.M.Povoroznyk, O.K.Gorpinich, G.V.Mokhnach, O.A.Ponkratenko, O.O.Jachmenjov On the structure of excited states of nuclei 4He, 6He and 6Li from the 3H(α, tt)p and 3H(α, tt)n reactions NUCLEAR REACTIONS 3H(α, X), (α, t3He), E=67.2 MeV; measured reaction products, (+3He)t-coin. 4He, 6He, 6Li; deduced resonances energies, widths.
doi: 10.15407/jnpae
2010RU03 Eur.Phys.J. A 44, 221 (2010) A.T.Rudchik, Yu.O.Shyrma, K.W.Kemper, K.Rusek, E.I.Koshchy, S.Kliczewski, B.G.Novatsky, O.A.Ponkratenko, E.Piasecki, G.P.Romanyshyna, Yu.M.Stepanenko, I.Strojek, S.B.Sakuta, A.Budzanowski, L.Glowacka, I.Skwirczynska, R.Siudak, J.Choinski, A.Szczurek Isotopic effects in elastic and inelastic 12C + 16, 18O scattering NUCLEAR REACTIONS 12C(18O, X), E=105 MeV; measured reaction products; deduced σ(θ), potential scattering, large-momentum transfer, energy dependence. NUCLEAR REACTIONS 12C(18O, X), E=105 MeV; 12C(16O, X), E=24-230 MeV; calculated transitions to the excited states using the rotational and vibrational models. Optical model and coupled-reaction channels methods.
doi: 10.1140/epja/i2010-10953-7
2010RU13 Iader.Fiz.Enerh. 11, 251 (2010); Nuc.phys.atom.energ. 11, 251 (2010) A.T.Rudchik, Yu.O.Shyrma, E.I.Koshchy, S.Kliczewski, B.G.Novatsky, O.A.Ponkratenko, E.Piasecki, G.P.Romanyshyna, K.Rusek, Yu.M.Stepanenko, I.Strojek, S.B.Sakuta, A.Budzanowski, L.Glowacka, I.Skwirczynska, R.Siudak, J.Choinski, A.Szczurek Isotopic effects in elastic and inelastic 12, 13C + 16, 18O scattering NUCLEAR REACTIONS 12,13C(18O, 18O'), (18O, 18O), 13C(16O, 16O), (16O, 16O'), E=105 MeV; measured reaction products; deduced partial σ, optical model parameters, spectroscopic factors. Data from this article have been entered in the EXFOR database. For more information, access X4 datasetD5084. 2010RU14 Iader.Fiz.Enerh. 11, 355 (2010); Nuc.phys.atom.energ. 11, 355 (2010) A.T.Rudchik, Yu.M.Stepanenko, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, A.Budzanowski, S.Yu.Mezhevych, Val.M.Pirnak, I.Skwirczynska, R.Siudak, B.Czech, A.Szczurek, J.Choinski, L.Glowacka 7Li(18O, 17N)8Be reaction and the 17N + 8Be-potential NUCLEAR REACTIONS 7Li(18O, 17N)8Be, E=114 MeV; measured reaction products; deduced σ(θ), partial σ, optical model parameters.
2010RU15 Iader.Fiz.Enerh. 11, 379 (2010); Nuc.phys.atom.energ. 11, 379 (2010) A.T.Rudchik, Yu.O.Shyrma, E.I.Koshchy, S.Kliczewski, B.G.Novatsky, O.A.Ponkratenko, E.Piasecki, G.P.Romanyshyna, K.Rusek, Yu.M.Stepanenko, I.Strojek, S.B.Sakuta, A.Budzanowski, L.Glowacka, I.Skwirczynska, R.Siudak, J.Choinski, B.Czech, A.Szczurek Elastic and inelastic scattering of the 14C + 18O nuclei NUCLEAR REACTIONS 12,13,14C(18O, 18O'), (18O, 18O), 14C(16O, 16O), (16O, 16O'), E=105 MeV; measured reaction products; deduced partial σ, optical model parameters, spectroscopic factors.
2010RU17 Iader.Fiz.Enerh. 11, 117 (2010) A.T.Rudchik, Yu.O.Shyrma, V.A.Plujko, O.A.Ponkratenko, I.V.Simenog Energy dependence of the 13C + 16O scattering and quasi-molecular absorptian potential NUCLEAR REACTIONS 13C(16O, 16O), E(cm)=6.28-59.17 MeV; analyzedσ(θ); deduced optical model parameters, reaction mechanism features. Coupled reaction channels method.
doi: 10.15407/jnpae
2009KL03 Acta Phys.Pol. B40, 893 (2009) S.Kliczewski, A.A.Rudchik, A.T.Rudchik, O.A.Ponkratenko, E.I.Koshchy, V.M.Kyryanchuk, Val.M.Pirnak, O.A.Momotyuk, A.Budzanowski, B.Czech, R.Siudak, I.Skwirczynska, A.Szczurek, S.Yu.Mezhevych, K.Rusek, S.B.Sakuta, E.Piasecki, J.Choinski, L.Glowacka Study of Light Exotic and Stable Nuclei with Heavy Ion Reactions
2009RO10 Phys.Rev. C 79, 054609 (2009) V.O.Romanyshyn, A.T.Rudchik, K.W.Kemper, S.Kliczewski, E.I.Koshchy, O.A.Ponkratenko, K.Rusek, A.Budzanowski, J.Choinski, B.Czech, L.Glowacka, S.Yu.Mezhevych, Val.M.Pirnak, V.A.Plujko, A.A.Rudchik, I.Skwirczynska, R.Siudak, A.Szczurek 8Be scattering potentials from reaction analyses NUCLEAR REACTIONS 7Li(10B, X)6Li/7Li/8Li/7Be/9Be/10Be/10B/11B, E=51 MeV; measured particle spectra. 7Li(10B, 9Be), E=51 MeV; 10Be(7Li, 9Be), E=24 MeV; measured 9Be spectra, σ(θ), analysis by coupled-reaction-channels method using optical potentials of Woods-Saxon type. 8Be; deduced levels, J, π.
doi: 10.1103/PhysRevC.79.054609
2009RO33 Iader.Fiz.Enerh. 10, 26 (2009) V.O.Romanyshyn, A.T.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, V.M.Kyryanchuk, S.Yu.Mezhevych, Val.M.Pirnak, A.A.Rudchik, A.Budzanowski, I.Skwirczynska, R.Siudak, B.Czech, A.Szczurek, J.Choinski, L.Glowacka Mechanism of charge-exchange in the 7Li(10B, 10Be)7Be reaction and potential of interaction of the 7Be + 10Be nuclei NUCLEAR REACTIONS 7Li(10B, 10Be), E=51 MeV; measured reaction products; deduced σ(θ). 10B(7Li, 7Be), E=39 MeV; analyzed σ(θ); deduced reaction mechanism features, optical model parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2009RU11 Eur.Phys.J. A 41, 31 (2009) A.T.Rudchik, K.W.Kemper, V.O.Romanyshyn, O.A.Ponkratenko, V.M.Kyryanchuk, V.V.Uleshchenko Comparison of 7Li , 7Be + 9Be elastic scattering in the coupled-reaction-channels approach NUCLEAR REACTIONS 9Be(7Li, 7Li), E=15.75, 24, 30, 34, 63, 130 MeV; 9Be(7Be, 7Be), E=17, 19, 21 MeV; analyzed σ, σ(θ), reaction mechanism features using coupled-reaction-channels method and Woods-Saxon optical potentials. Comparison with 9Be(8Be, 8Be) optical potential parameters.
doi: 10.1140/epja/i2009-10765-x
2009RU13 Nucl.Phys. A831, 139 (2009) A.T.Rudchik, Yu.M.Stepanenko, K.W.Kemper, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, A.Budzanowski, S.Yu.Mezhevych, Val.M.Pirnak, I.Skwirczynska, R.Siudak, B.Czech, A.Szczurek, V.V.Uleshchenko, J.Choinski, L.Glowacka 8Li optical potential from 7Li(18O, 17O)8Li reaction analysis NUCLEAR REACTIONS 7Li(18O, 17O), E=114 MeV; measured particle spectra, σ(θ); deduced reaction mechanism features and Woods-Saxon potential parameters using coupled-reaction-channels analysis.
doi: 10.1016/j.nuclphysa.2009.10.084
2009RU14 Iader.Fiz.Enerh. 10, 138 (2009) A.T.Rudchik, Yu.M.Stepanenko, A.A.Rudchik, O.A.Ponkratenko, E.I.Koshchy, S.Kliczewski, K.Rusek, A.Budzanowski, V.M.Kyryanchuk, S.Yu.Mezhevych, I.Skwirczynska, R.Siudak, B.Czech, A.Szczurek, V.V.Uleshchenko, J.Choinski, L.Glowacka The 7Li(18O, 17O)8Li reaction and the 17O + 8Li potential NUCLEAR REACTIONS 7Li(18O, 17O), E=114 MeV; measured reaction products; deduced σ(θ), reaction mechanism features, optical model parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2009RU15 Iader.Fiz.Enerh. 10, 249 (2009) A.T.Rudchik, Yu.O.Shyrma, O.A.Ponkratenko Energy dependence of the potential for interaction of 16O ions with 12C nuclei NUCLEAR REACTIONS 12C(16O, 16O), E(cm)=20-315 MeV; analyzed σ(θ); deduced optical model parameters, reaction mechanism features. Coupled reaction channels method.
doi: 10.15407/jnpae
2009RU16 Iader.Fiz.Enerh. 10. 376 (2009) A.T.Rudchik, Yu.O.Shyrma, E.I.Koshchy, S.Kliczewski, B.G.Novatsky, O.A.Ponkratenko, E.Piasecki, G.P.Romanyshyna, K.Rusek, Yu.M.Stepanenko, I.Strojek, S.B.Sakuta, A.Budzanowski, L.Glowacka, I.Skwirczynska, R.Siudak, J.Choinski, A.Szczurek Elastic and inelastic scattering of 18O ions on 12C nuclei NUCLEAR REACTIONS 12C(18O, 18O), (18O, X), E=105 MeV; measured reaction products; deduced σ(θ). 12C(18O, 18O), E=32.2-140 MeV; analyzed σ(θ); deduced reaction mechanism features, optical model parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2008RO32 Iader.Fiz.Enerh. 9 no.2, 24 (2008) V.O.Romanyshyn, A.T.Rudchik, E.I.Koshchy, O.A.Ponkratenko, S.Kliczewski, A.Budzanowski, K.Rusek, L.Glowacka, S.Yu.Mezhevych, Val.M.Pirnak, A.A.Rudchik, I.Skwirczynska, R.Siudak, J.Choinski, B.Czech, A.Szczurek Mechanism of 7Li(10B, 9Be)8Be, 10B(7Li, 9Be)8Be reactions and 8Be + 9Be-potential NUCLEAR REACTIONS 7Li(10B, 9Be), E=51 MeV; measured reaction products; deduced σ(θ). 10B(7Li, 9Be), E=24 MeV; analyzed σ(θ); deduced reaction mechanism features, optical model parameters. Coupled channels analyssis.
doi: 10.15407/jnpae
2008RU11 Iader.Fiz.Enerh. 9 no.3, 45 (2008) A.T.Rudchik, V.O.Romanyshyn, V.M.Kyryanchuk, O.A.Ponkratenko, V.V.Uleshchenko Mechanism of elastic scattering of 7Li, 7Be + 9Be nuclei and optical potentials of their interaction NUCLEAR REACTIONS 9Be(7Li, 7Li), E=15.75, 24, 30, 34; 9Be(7Be, 7Be), E=17, 19, 21 MeV; analyzedσ(θ); deduced optical model parameters, reaction mechanism features. Coupled reaction channels method.
doi: 10.15407/jnpae
2007RU01 Phys.Rev. C 75, 024612 (2007) A.T.Rudchik, K.W.Kemper, A.A.Rudchik, A.M.Crisp, V.D.Chesnokova, V.M.Kyryanchuk, F.Marechal, O.A.Momotyuk, O.A.Ponkratenko, B.T.Roeder, K.Rusek Tensor analyzing powers and energy dependence of the 7Li+16O interaction NUCLEAR REACTIONS 16O(polarized 7Li, 7Li), E=42 MeV; measured σ(θ), tensor analyzing powers. 16O(7Li, 7Li), (7Li, 7Li'), E(cm)=6.26-34.78 MeV; analyzed data; deduced parameters. 16O(7Li, t), E=15-38 MeV; calculated σ(θ). Coupled reaction channels method.
doi: 10.1103/PhysRevC.75.024612
2007RU04 Nucl.Phys. A785, 293 (2007) A.A.Rudchik, A.T.Rudchik, S.Kliczewski, E.I.Koshchy, O.A.Ponkratenko, K.W.Kemper, K.Rusek, A.Budzanowski, J.Choinski, B.Czech, T.Czosnyka, V.D.Chesnokova, L.Glowacka, E.Kozik, V.M.Kyryanchuk, S.Yu.Mezhevych, A.V.Mokhnach, O.A.Momotyuk, I.Skwirczynska, R.Siudak, A.Szczurek Elastic and inelastic scattering of 7Li + 18O versus 7Li + 16O NUCLEAR REACTIONS 7Li(18O, 18O), (18O, 18O'), E=114 MeV; measured elastic and inelastic σ(θ); deduced potential parameters, scattering mechanism features. 18O deduced deformation parameters. Optical model and coupled-reaction-channels analysis.
doi: 10.1016/j.nuclphysa.2007.01.001
2007RU13 Eur.Phys.J. A 33, 317 (2007) A.T.Rudchik, V.O.Romanyshyn, E.I.Koshchy, A.Budzanowski, K.W.Kemper, K.Rusek, V.D.Chesnokova, J.Choinski, B.Czech, L.Glowacka, S.Kliczewski, V.M.Kyryanchuk, S.Yu.Mezhevych, A.V.Mokhnach, O.A.Momotyuk, O.A.Ponkratenko, R.Siudak, I.Skwirczynska, A.Szczurek Isotopic effects in the 7Li + 10, 11B elastic and inelastic scattering NUCLEAR REACTIONS 7Li(10B, 10B), E=51 MeV; measured elastic scattering σ and angular distributions. 10B(7Li, 7Li), E=24, 39 MeV; 11B(7Li, 7Li), E=34 MeV; analyzed elastic scattering σ using optical model and coupled channel method.
doi: 10.1140/epja/i2007-10483-5
2007RU22 Iader.Fiz.Enerh. 8 no.1, 72 (2007) A.T.Rudchik, V.O.Romanyshyn, E.I.Koshchy, A.Budzanowski, K.W.Kemper, K.Rusek, V.D.Glowacka, V.M.Kyryanchuk, L.S.Kliczewski, S.Yu.Mezhevych, A.V.Mokhnach, O.A.Momotyuk, O.A.Ponkratenko, I.Skwirczynska, R.Siudak, T.Choinski, V.D.Chesnokova, B.Czech, T.Czosnyka, A.Szczurek 7Li + 10B elastic and inelastic scattering NUCLEAR REACTIONS 7Li(10B, 10B), E=51 MeV; measured reaction products; deduced elastic scattering σ(θ) and angular distributions. 10B(7Li, 7Li), E=24, 39 MeV; 11B(7Li, 7Li), E=34 MeV; analyzed σ(θ); deduced reaction mechanism features, optical model parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2006RU17 Iader.Fiz.Enerh. 7 no.1, 9 (2006) A.A.Rudchik, A.T.Rudchik, K.W.Kemper, V.M.Kyryanchuk, O.A.Ponkratenko Energy dependence of the 7Li + 16O interaction NUCLEAR REACTIONS 16O(7Li, 7Li), (7Li, 7Li'), E(cm)=6.26-34.78 MeV; analyzed σ(θ); deduced optical model parameters. Coupled reaction channels method.
doi: 10.15407/jnpae
2005RU17 Ukr.J.Phys. 50, 907 (2005) A.A.Rudchik, A.T.Rudchik, O.A.Ponkratenko, K.W.Kemper The approach of coupled reaction channels to 7Li + 11B Scattering NUCLEAR REACTIONS 11B(7Li, 7Li), (7Li, 7Li'), E=34 MeV; analyzed elastic and inelastic σ(θ); deduced optical model parameters. 7Li, 11B deduced deformation parameters. Coupled reaction channels method.
2005RU18 Phys.Rev. C 72, 034608 (2005) A.A.Rudchik, A.T.Rudchik, G.M.Kozeratska, O.A.Ponkratenko, E.I.Koshchy, A.Budzanowski, B.Czech, S.Kliczewski, R.Siudak, I.Skwirczynska, A.Szczurek, S.Yu.Mezhevych, K.W.Kemper, J.Choinski, T.Czosnyka, L.Glowacka 7Li + 11B elastic and inelastic scattering in a coupled-reaction-channels approach NUCLEAR REACTIONS 7Li(11B, X), E=44 MeV; measured particle spectra, charge distributions. 7Li(11B, 11B), (11B, 11B'), E=44 MeV; measured σ(E, θ); 11B(7Li, 7Li), (7Li, 7Li'), E=34 MeV; analyzed σ(E, θ); deduced optical model parameters, transfer channel contributions, reorientation effects. 7Li, 11B deduced deformation parameters. Optical model and coupled-reaction-channels analysis.
doi: 10.1103/PhysRevC.72.034608
2005RU22 Iader.Fiz.Enerh. 6 no.3, 9 (2005) A.A.Rudchik, A.T.Rudchik, A.T.Rudchik A.Budzanowski, L.Glowacka, K.W.Kemper, S.Kliczewski, E.I.Koshchy, G.M.Kozeratska, S.Yu.Mezhevych, O.A.Ponkratenko, K.Rusek, R.Siudak, I.Skwirszynska, J.Choinski, B.Czech, T.Czosnyka, A.Szczurek Elastic and inelastic scattering of 7Li + 11B NUCLEAR REACTIONS 7Li(11B, X), (11B, 11B), E=44 MeV; measured reaction products; deduced σ(θ). 11B(7Li, 7Li), E=34 MeV; analyzed σ(θ);deduced optical model parameters, reorientation effects. Optical model and coupled-reaction-channels analysis.
doi: 10.15407/jnpae
2003BA42 Phys.Lett. B 563, 23 (2003) H.O.Back, M.Balata, A.de Bari, T.Beau, A.de Bellefon, G.Bellini, J.Benziger, S.Bonetti, C.Buck, B.Caccianiga, L.Cadonati, F.Calaprice, G.Cecchet, M.Chen, A.Di Credico, O.Dadoun, D.D'Angelo, V.Yu.Denisov, A.Derbin, M.Deutsch, F.Elisei, A.Etenko, F.von Feilitzsch, R.Fernholz, R.Ford, D.Franco, B.Freudiger, C.Galbiati, F.Gatti, S.Gazzana, M.G.Giammarchi, D.Giugni, M.Goeger-Neff, A.Goretti, C.Grieb, C.Hagner, G.Heusser, A.Ianni, A.M.Ianni, H.de Kerret, J.Kiko, T.Kirsten, V.Kobychev, G.Korga, G.Korschinek, Y.Kozlov, D.Kryn, M.Laubenstein, E.Litvinovich, C.Lendvai, P.Lombardi, I.Machulin, S.Malvezzi, J.Maneira, I.Manno, D.Manuzio, G.Manuzio, F.Masetti, A.Martemianov, U.Mazzucato, K.McCarty, E.Meroni, L.Miramonti, M.E.Monzani, P.Musico, L.Niedermeier, L.Oberauer, M.Obolensky, F.Ortica, M.Pallavicini, L.Papp, L.Perasso, A.Pocar, O.A.Ponkratenko, R.S.Raghavan, G.Ranucci, A.Razeto, A.Sabelnikov, C.Salvo, R.Scardaoni, D.Schimizzi, S.Schoenert, H.Simgen, T.Shutt, M.Skorokhvatov, O.Smirnov, A.Sonnenschein, A.Sotnikov, S.Sukhotin, V.Tarasenkov, R.Tartaglia, G.Testera, V.I.Tretyak, D.Vignaud, R.B.Vogelaar, V.Vyrodov, M.Wojcik, O.Zaimidoroga, Yu.G.Zdesenko, G.Zuzel New limits on nucleon decays into invisible channels with the BOREXINO counting test facility RADIOACTIVITY 12C(n); 13C(p); measured T1/2 lower limits for bound nucleon decay to invisible channels.
doi: 10.1016/S0370-2693(03)00636-1
2003BI12 Bull.Rus.Acad.Sci.Phys. 67, 694 (2003) P.G.Bizzeti, A.Sh.Georgadze, F.A.Danevich, S.Yu.Zdesenko, Yu.G.Zdesenko, V.V.Kobychev, P.R.Maurenzig, S.S.Nagorny, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, T.F.Fazzini Double β-decay of 116Cd nucleus RADIOACTIVITY 116Cd(2β-); measured 2ν-accompanied 2β-decay T1/2, 0ν-accompanied 2β-decay T1/2 lower limit; deduced neutrino mass limit, related features.
2003BI13 Bull.Rus.Acad.Sci.Phys. 67, 700 (2003) P.G.Bizzeti, A.Sh.Georgadze, F.A.Danevich, S.Yu.Zdesenko, Yu.G.Zdesenko, V.V.Kobychev, P.R.Maurenzig, S.S.Nagorny, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, T.F.Fazzini α-decay of natural tungsten isotopes RADIOACTIVITY 180W(α); measured T1/2. 182,183,184,186W(α); measured T1/2 lower limits. 224Ra, 220Rn, 216Po(α); measured Eα, T1/2.
2003DA05 Phys.Rev. C 67, 014310 (2003) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, S.S.Nagorny, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko, P.G.Bizzeti, T.F.Fazzini, P.R.Maurenzig α activity of natural tungsten isotopes RADIOACTIVITY 180W(α); measured T1/2. 182,183,184,186W(α); measured T1/2 lower limits. Low-background CdWO4 crystal scintillators. Comparisons with previous results and model predictions.
doi: 10.1103/PhysRevC.67.014310
2003DA09 Nucl.Phys. A717, 129 (2003) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko, P.G.Bizzeti, T.F.Fazzini, P.R.Maurenzig Two-neutrino 2β decay of 116Cd and new half-life limits on 2β decay of 180W and 186W RADIOACTIVITY 116Cd(2β-); measured 2ν-accompanied 2β decay T1/2. 180W(2EC); 186W(2β-); measured 2β-decay T1/2 lower limits. CdWO4 crystal scintillators.
doi: 10.1016/S0375-9474(03)00613-4
2003DA24 Phys.Rev. C 68, 035501 (2003) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko, P.G.Bizzeti, T.F.Fazzini, P.R.Maurenzig Search for 2β decay of cadmium and tungsten isotopes: Final results of the Solotvina experiment RADIOACTIVITY 116Cd(2β-); measured 2ν-accompanied 2β decay T1/2, 0ν-accompanied 2β decay T1/2 lower limit. 106Cd(2EC), (β+EC), (2β+); 108Cd, 180W(2EC); 114Cd, 186W(2β-); measured 0ν- and 2ν-accompanied 2β decay T1/2 lower limits. 212Bi(β-); measured Eβ, T1/2. 212,216Po, 220Rn(α); measured Eα, T1/2.
doi: 10.1103/PhysRevC.68.035501
2003RU11 Iader.Fiz.Enerh. 4 no.3, 32 (2003) A.A.Rudchik, V.K.Chernievsky, A.T.Rudchik, A.Budzanowski, L.Glovacka, L.Zemlo, S.Kliczewski, E.I.Koshchy, O.A.Ponkratenko, O.A.Momotyuk, A.V.Mokhnach, V.M.Pirnak, K.Rusek, I.Skwirszynska, R.Siudak, B.Czech, A.Szczurek Mechanisms of the 12C(11B, 15N)8Be reaction NUCLEAR REACTIONS 12C(11B, 15N), E=49 MeV; measured reaction products; deduced σ(θ); 12C(11B, 8Be), E(cm)=10-17 MeV; analyzed σ(θ);deduced reaction mechanism features, optical model parameters. Coupled channels analysis.
doi: 10.15407/jnpae
2002BE36 Nucl.Phys. A705, 29 (2002) R.Bernabei, P.Belli, F.Cappella, R.Cerulli, F.Montecchia, F.Nozzoli, A.Incicchitti, D.Prosperi, C.J.Dai, V.I.Tretyak, Yu.G.Zdesenko, O.A.Ponkratenko Search for β and ββ Decays in 48Ca RADIOACTIVITY 48Ca(2β-); measured 0ν- and 2ν-accompanied 2β-decay T1/2 lower limits. 48Ca(β-); measured β-decay T1/2 lower limit. Coincidence technique.
doi: 10.1016/S0375-9474(02)00622-X
2002BI06 Nucl.Phys. B(Proc.Supp.) S110, 389 (2002) P.G.Bizzeti, F.A.Danevich, T.F.Fazzini, A.Sh.Georgadze, V.V.Kobychev, P.R.Maurenzig, S.S.Nagorny, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko New Results of 116Cd ββ Decay Experiment RADIOACTIVITY 116Cd(2β-); measured β-spectra, 0ν-accompanied 2β-decay T1/2 lower limit.
doi: 10.1016/S0920-5632(02)01518-9
2002BI16 Bull.Rus.Acad.Sci.Phys. 66, 689 (2002) P.G.Bizzeti, A.Sh.Georgadze, F.A.Danevich, S.Yu.Zdesenko, Yu.G.Zdesenko, V.V.Kobychev, B.N.Kropivyansky, P.R.Maurenzig, S.S.Nagorny, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, T.F.Fazzini 180W Alpha-Decay RADIOACTIVITY 180W(α); measured T1/2. CdWO4 scintillator.
2001BE19 Eur.Phys.J. C 19, 43 (2001) G.Bellini, B.Caccianiga, M.Chen, F.A.Danevich, M.G.Giammarchi, V.V.Kobychev, B.N.Kropivyansky, E.Meroni, L.Miramonti, A.S.Nikolayko, L.Oberauer, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko High Sensitivity 2β Decay Study of 116Cd and 100Mo with the BOREXINO Counting Test Facility (CAMEO Project) RADIOACTIVITY 100Mo, 116Cd(2β-); measured 0ν-accompanied 2β-decay T1/2 lower limits; deduced neutrino mass limits.
doi: 10.1007/s100520100594
2001BE79 Part. and Nucl., Lett. 109, 18 (2001) P.Belli, R.Bernabei, C.J.Dai, F.Grianti, H.L.He, G.Ignesti, A.Incicchitti, H.H.Kuang, J.M.Ma, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko New Limits on 2β Processes in 40Ca and 46Ca by using Low Radioactive CaF2(Eu) Crystal Scintillators RADIOACTIVITY 40Ca(2EC); 46Ca(2β-); measured 2β-decay T1/2 lower limits. CaF2(Eu) detectors.
2001BE80 Part. and Nucl., Lett. 109, 58 (2001) P.Belli, R.Bernabei, C.J.Dai, H.L.He, G.Ignesti, A.Incicchitti, H.H.Kuang, J.M.Ma, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko New Experimental Limits on the Electron Stability and Excitation of Nuclear Levels in 23Na, 127I and 129Xe Induced by the Electron Decay on the Atomic Shell RADIOACTIVITY 23Na, 127I, 129Xe(EC); measured charge-nonconserving electron capture T1/2 lower limit. Implications for electron stability discussed.
2001BI22 Part. and Nucl., Lett. 109, 7 (2001) P.G.Bizzeti, F.A.Danevich, T.F.Fazzini, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, P.R.Maurenzig, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko Status of 116Cd Double β Decay Study with 116CdWO4 Scintillators RADIOACTIVITY 116Cd(2β-); measured 2ν-accompanied 2β-decay T1/2, Q-value, 0ν-accompanied decay T1/2 lower limits. CdWO4 detectors.
2001DA22 Nucl.Phys. A694, 375 (2001) F.A.Danevich, V.V.Kobychev, O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko Quest for Double Beta Decay of 160Gd and Ce Isotopes RADIOACTIVITY 136,138,142Ce, 160Gd(2β-); measured 0ν- and 2ν-accompanied 2β-decay T1/2 lower limits. GSO crystal scintillator.
doi: 10.1016/S0375-9474(01)00983-6
2001RU16 Iader.Fiz.Enerh. 2 no.1, 80 (2001) A.T.Rudchik, V.M.Kyryanchuk, V.A.Ziman, O.A.Momotyuk, A.V.Mokhnach, O.A.Ponkratenko, V.K.Chernievsky Elastic and inelastic scattering of the 12C ions by the 12C nucleus at energy 61 MeV NUCLEAR REACTIONS 12C(12C, 12C'), E=61 MeV; measured reaction products; deduced elastic and non-elastic σ(θ), optical model parameters. Optical model and coupled reactions channels model analysis.
doi: 10.15407/jnpae
2001ZD01 J.Phys.(London) G27, 2129 (2001) Yu.G.Zdesenko, O.A.Ponkratenko, V.I.Tretyak High Sensitivity GEM Experiment on 2β Decay of 76Ge RADIOACTIVITY 76Ge(2β-); calculated γ spectra associated with 0ν- and 2ν-accompanied 2β-decay. Experimental sensitivity discussed.
doi: 10.1088/0954-3899/27/10/312
2000BE56 Phys.Lett. 493B, 12 (2000) R.Bernabei, M.Amato, P.Belli, R.Cerulli, C.J.Dai, V.Yu.Denisov, H.L.He, A.Incicchitti, H.H.Kuang, J.M.Ma, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko Search for the Nucleon and Di-Nucleon Decay into Invisible Channels RADIOACTIVITY 129Xe(p), (n); measured T1/2 limits for nucleon and dinucleon decays that do not conserve baryonic number. Gran Sasso underground detector.
doi: 10.1016/S0370-2693(00)01112-6
2000BE57 Phys.Lett. 493B, 216 (2000) G.Bellini, B.Caccianiga, M.Chen, F.A.Danevich, M.G.Giammarchi, V.V.Kobychev, B.N.Kropivyansky, E.Meroni, L.Miramonti, A.S.Nikolayko, L.Oberauer, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko High Sensitivity Quest for Majorana Neutrino Mass with the BOREXINO Counting Test Facility RADIOACTIVITY 100Mo, 116Cd(2β-); calculated spectra, detector efficiency, related features.
doi: 10.1016/S0370-2693(00)01137-0
2000BE68 Iader.Fiz.Enerh. 1, no.1, 64 (2000); Nuc.phys.atom.energ. 1, no.1, 64 (2000) P.Belli, R.Bernabei, C.J.Dai, H.L.He, G.Ignesti, A.Incicchitti, H.H.Kuang, J.M.Ma, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko Improved experimental limit on the electron stability and non-paulian transitions in I atom
doi: 10.15407/jnpae
2000DA21 Yad.Fiz. 63, No 7, 1303 (2000); Phys.Atomic Nuclei 63, 1229 (2000) F.A.Danevich, V.V.Kobychev, B.N.Kropivyansky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko, P.G.Bizzeti, T.F.Fazzini, P.R.Maurenzig New Phase of the 116Cd 2β-Decay Experiment with 116CdWO4 Scintillators RADIOACTIVITY 116Cd(2β-); measured 0ν accompanied 2β-decay T1/2 lower limit; deduced neutrino mass limit. CdWO4 scintillators.
doi: 10.1134/1.855775
2000DA27 Phys.Rev. C62, 045501 (2000) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, S.Yu.Zdesenko, Yu.G.Zdesenko, P.G.Bizzeti, T.F.Fazzini, P.R.Maurenzig New Results of 116Cd Double β Decay Study with 116CdWO4 Scintillators RADIOACTIVITY 116Cd(2β-); measured 2ν-accompanied 2β decay T1/2, 0ν-accompanied 2β decay T1/2 lower limit; deduced neutrino mass limits. CdWO detectors.
doi: 10.1103/PhysRevC.62.045501
2000PO15 Yad.Fiz. 63, No 7, 1355 (2000); Phys.Atomic Nuclei 63, 1282 (2000) O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko Event Generator DECAY4 for Simulating Double-Beta Processes and Decays of Radioactive Nuclei
doi: 10.1134/1.855784
1999BE55 Phys.Lett. 465B, 315 (1999) P.Belli, R.Bernabei, C.J.Dai, G.Ignesti, A.Incicchitti, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko Charge Non-Conservatioon Restrictions from the Nuclear Levels Excitation of 129Xe Induced by the Electron's Decay on the Atomic Shell NUCLEAR REACTIONS 129Xe(e, γ), E at rest; measured charge non-conserving electron capture T1/2 lower limit.
doi: 10.1016/S0370-2693(99)01091-6
1999BE61 Phys.Rev. C60, 065501 (1999) P.Belli, R.Bernabei, C.J.Dai, H.L.He, G.Ignesti, A.Incicchitti, H.H.Kuang, J.M.Ma, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko New Limits on the Nuclear Levels Excitation of 127I and 23Na During Charge Nonconservation NUCLEAR REACTIONS 23Na, 127I(e, γ), E at rest; measured charge-nonconserving electron capture T1/2 lower limits.
doi: 10.1103/PhysRevC.60.065501
1999BE64 Nucl.Phys. B563, 97 (1999) P.Belli, R.Bernabei, C.J.Dai, H.L.He, G.Ignesti, A.Incicchitti, H.H.Kuang, J.M.Ma, F.Montecchia, O.A.Ponkratenko, D.Prosperi, V.I.Tretyak, Yu.G.Zdesenko New Limits on Spin-Dependent Coupled WIMPs and 2β Processes in 40Ca and 46Ca by using Low Radioactive CaF2(Eu) Crystal Scintillators RADIOACTIVITY 46Ca(2β-); 40Ca(2EC); measured T1/2 lower limits. Implications for dark-matter search discussed.
doi: 10.1016/S0550-3213(99)00618-5
1999BE81 Astropart.Phys. 10, 115 (1999) P.Belli, R.Bernabei, A.Incicchitti, C.Arpesella, V.V.Kobychev, O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko New limits on 2β+ decay processes in 106Cd RADIOACTIVITY 106Cd(2β+), (β+EC), (2EC); measured T1/2 lower limits.
doi: 10.1016/S0927-6505(98)00034-6
1999DA04 Nucl.Phys. B(Proc.Supp.) S70, 246 (1999) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko Status of the INR Experiment on 2β Decay of 116Cd RADIOACTIVITY 116Cd(2β-); measured 0ν accompanied 2β decay T1/2 lower limit. CdWO4 scintillator.
doi: 10.1016/S0920-5632(98)00429-0
1998DA23 Nucl.Phys. A643, 317 (1998) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko Limits on Majoron Modes of 116Cd Neutrinoless 2β Decay RADIOACTIVITY 116Cd(2β); measured ν-accompanied 2β decay T1/2 lower limits; deduced Majoron-neutrino coupling constant upper limit. CdWO4 scintillator.
doi: 10.1016/S0375-9474(98)00567-3
1997GE14 Bull.Rus.Acad.Sci.Phys. 61, 600 (1997) A.Sh.Georgadze, F.A.Danevich, Yu.G.Zdesenko, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, V.V.Muzalevsky, A.S.Nikolaiko, O.A.Ponkratenko, A.G.Prokopets, V.I.Tretyak Double β Decay of 116Cd and 160Gd RADIOACTIVITY 116Cd, 160Gd(2β); measured 0ν accompanied decay T1/2 lower limit. CWO, GSO scintillation crystals.
1997GE15 Bull.Rus.Acad.Sci.Phys. 61, 1719 (1997) A.Sh.Georgadze, F.A.Danevich, Yu.G.Zdesenko, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, V.V.Muzalevsky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak Investigation of Rare Alpha and Beta Decays by Means of Cadmium and Zinc Tungstate Crystals RADIOACTIVITY 113Cd(β-); measured β spectrum, T1/2. 180,182,183,184,186W(α); measured T1/2 lower limits. CdWO4, ZnWO4 low-background detectors.
1997ZI05 Nucl.Phys. A624, 459 (1997) V.A.Ziman, A.T.Rudchik, A.Budzanowski, V.K.Chernievsky, L.Glowacka, E.I.Koshchy, S.Kliczewski, M.Makowska-Rzeszutko, A.V.Mokhnach, O.A.Momotyuk, O.A.Ponkratenko, R.Siudak, I.Skwirczynska, A.Szczurek, J.Turkiewicz Channel Couplings in the 12C(14N, X) Reactions at E(14N) = 116 MeV NUCLEAR REACTIONS 12C(14N, 14N), (14N, 14N'), (14N, 12C), (14N, 13C), (14N, 13N), E=116 MeV; measured σ(θ); deduced reaction mechanism. 12C, 14N deduced deformation parameters. Coupled reaction channels analysis.
doi: 10.1016/S0375-9474(97)00328-X
1996BU48 Nucl.Instrum.Methods Phys.Res. A369, 164 (1996) S.Ph.Burachas, F.A.Danevich, A.Sh.Georgadze, H.V.Klapdor-Kleingrothaus, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, A.Muller, V.V.Muzalevsky, A.S.Nikolaiko, O.A.Ponkratenko, V.D.Ryzhikov, A.S.Sai, I.M.Solsky, V.I.Tretyak, Yu.G.Zdesenko Large Volume CdWO4 Crystal Scintillators RADIOACTIVITY 137Cs(β-); 207Bi(EC), (β+); measured calibration Eγ, Iγ; deduced energy resolution, other characteristics. Low background scintillation spectrometer, large volume CdWO4 crystals.
doi: 10.1016/0168-9002(95)00675-3
1996DA11 Yad.Fiz. 59, No 1, 5 (1996); Phys.Atomic Nuclei 59, 1 (1996) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak, Yu.G.Zdesenko Beta Decay of 113Cd RADIOACTIVITY 113Cd(β-); measured β spectrum, shape; deduced T1/2. Nonunique fourth-forbidden β-decay, low-background CdWO4 crystal based scintillation setup.
1996DA25 Z.Phys. A355, 433 (1996) F.A.Danevich, A.Sh.Georgadze, J.Hellmig, M.Hirsch, H.V.Klapdor-Kleingrothaus, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, A.Muller, A.S.Nikolaiko, F.Petry, O.A.Ponkratenko, H.Strecker, V.I.Tretyak, M.Vollinger, Yu.Zdesenko Investigation of β+β+ and β+/EC Decay of 106Cd RADIOACTIVITY 106Cd(2β+), (β+EC); measured 0ν-accompanied, 2ν-accompanied decay T1/2 lower limits. Low background scintillation detector with CdWO4 crystal.
doi: 10.1007/s002180050134
1996DA38 Nucl.Phys.(Proc.Suppl.) S48, 235 (1996) F.A.Danevich, A.Sh.Georgadze, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, V.V.Muzalevsky, A.S.Nikolaiko, O.A.Ponkratenko, A.G.Prokopets, V.I.Tretyak, Yu.G.Zdesenko Quest for Neutrinoless Double Beta Decay of 160Gd RADIOACTIVITY 160Gd(2β); measured 0ν-accompanied 2β-decay T1/2 lower limits.
doi: 10.1016/0920-5632(96)00248-4
1995GE17 Pisma Zh.Eksp.Teor.Fiz. 61, 869 (1995); JETP Lett. 61, 882 (1995) A.Sh.Georgadze, F.A.Danevich, Yu.G.Zdesenko, V.V.Kobychev, B.N.Kropivyansky, V.N.Kuts, V.V.Muzalevsky, A.S.Nikolaiko, O.A.Ponkratenko, V.I.Tretyak Search for α Decay of Naturally Occuring Tungsten Isotopes RADIOACTIVITY 180,182,183,184,186W(α); measured α-decay T1/2 lower limit. Solotvin underground laboratory, Cd-, Zn-tungstenate scintillation crystals.
1995RU06 Nucl.Phys. A589, 535 (1995) A.T.Rudchik, V.A.Ziman, V.K.Chernievsky, V.V.Lutsenko, A.V.Mokhnach, O.A.Ponkratenko, E.N.Dovzhenko, V.N.Pirnak, E.I.Koshchy, Yu.G.Mashkarov, L.Glowacka, J.Turkiewicz, A.Budzanowski, M.Makowska-Rzeszutko, R.Siudak, S.B.Sakuta Scattering, One-Nucleon Transfers and Charge-Exchange Reactions in the 14C + 14N Interaction at E(14N) = 116 MeV NUCLEAR REACTIONS 14C(14N, 14N), (14N, 14C), (14N, 13C), (14N, 13N), E=116 MeV; measured σ(θ). Coupled-reaction-channels analysis.
doi: 10.1016/0375-9474(95)00038-3
1993PE08 Z.Phys. A345, 395 (1993) M.Petrascu, A.Isbasescu, I.Lazar, I.Mihai, H.Petrascu, A.T.Rudchik, V.A.Chernievsky, O.A.Ponkratenko, V.A.Ziman Three-Body Final State Breakup in the 27Al(14N, X) Reaction at 116 MeV Bombarding Energy NUCLEAR REACTIONS 27Al(14N, X), E=116 MeV; measured σ(fragment θ, E) for X=C, B, Be; deduced three-body final state breakup evidence, reaction σ. Optical, Glas models analyses.
doi: 10.1007/BF01282900
1991GL03 Nucl.Phys. A534, 349 (1991) L.Glowacka, J.Turkiewicz, O.Yu.Goryunov, A.V.Mokhnach, O.A.Ponkratenko, A.T.Rudchik, V.K.Chernievsky, A.A.Shvedov, E.I.Koshchy, Yu.G.Mashkarov Mechanism of the 12C(α, HI) Reactions at E(α) = 90 MeV NUCLEAR REACTIONS 12C(α, 6Li), (α, 7Li), (α, 7Be), E=90 MeV; measured σ(θ). Finite range DWBA analysis.
doi: 10.1016/0375-9474(91)90504-Y
1991GO25 Yad.Fiz. 54, 911 (1991); Sov.J.Nucl.Phys. 54, 552 (1992) S.A.Goncharov, A.S.Demyanova, I.Yu.Zayats, A.P.Ilin, A.V.Kuznichenko, L.V.Mikhailov, A.V.Mokhnach, A.A.Ogloblin, G.M.Onishchenko, O.A.Ponkratenko, A.G.Prokopets, A.T.Rudchik, V.K.Chernievsky, A.A.Shvedov Nuclear Rainbow in 12C + 3He and 12C + 4He Scattering NUCLEAR REACTIONS 12C(3He, 3He), E=98 MeV; 12C(α, α), E=90, 139 MeV; measured σ(θ); deduced model parameters. Optical, DWA models.
1989GO26 Ukr.Fiz.Zh. 34, 1144 (1989) O.Yu.Goryunov, I.I.Zalyubovsky, E.I.Koshchy, S.B.Kumshaev, Yu.G.Mashkarov, O.F.Nemets, A.T.Rudchik, V.K.Chernievsky, O.A.Ponkratenko, A.V.Shustov Study of (d, 6Li) Reaction on 12C Nuclei with 50 MeV Deuterons NUCLEAR REACTIONS 12C(d, 6Li), E=50 MeV; measured σ(E(6Li), θ), σ(θ). DWBA.
1989PL11 Ukr.Fiz.Zh. 34, 1619 (1989) A.V.Plavko, M.S.Onegin, O.A.Ponkratenko Empirical Shell Model in the (e, e')-, (p, p')- and (p(pol), p')-Scattering Processes NUCLEAR REACTIONS 40Ca(polarized p, p'), E=20.3 MeV; calculated σ(θ), A(θ). 90,92Zr(p, p'), E=20 MeV; calculated σ(θ). 90,92Zr(polarized p, p'), E=160 MeV; calculated A(θ). DWBA, (e, e') data analysis.
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