NSR Query Results
Output year order : Descending NSR database version of April 11, 2024. Search: Author = V.Zelevinsky Found 122 matches. Showing 1 to 100. [Next]2023WH01 Phys. Rev. Res. 5, 013109 (2023) C.White, A.Volya, D.Mulhall, V.Zelevinsky Structured ground states of randomly interacting bosons
doi: 10.1103/PhysRevResearch.5.013109
2022AN22 Phys.Rev. C 106, L051302 (2022) N.L.Anh, B.M.Loc, N.Auerbach, V.Zelevinsky Single-particle properties of the near-threshold proton-emitting resonance in 11B NUCLEAR STRUCTURE 11Be; calculated energy, width and J, π of near-threshold proton-emitting resonance seen in the recent experiment (2022AY04). Self-consistent Skyrme Hartree-Fock in the continuum with SkM*, SGII, SLy4 and SAMi interactions. NUCLEAR REACTIONS 10Be(p, p), E(cm)=100-350 keV; calculated σ(θ), s-wave phase shift. Self-consistent Skyrme Hartree-Fock in the continuum. Comparison to experimental data and other theoretical calculations.
doi: 10.1103/PhysRevC.106.L051302
2022AY04 Phys.Rev.Lett. 129, 012501 (2022) Y.Ayyad, W.Mittig, T.Tang, B.Olaizola, G.Potel, N.Rijal, N.Watwood, H.Alvarez-Pol, D.Bazin, M.Caamano, J.Chen, M.Cortesi, B.Fernandez-DomInguez, S.Giraud, P.Gueye, S.Heinitz, R.Jain, B.P.Kay, E.A.Maugeri, B.Monteagudo, F.Ndayisabye, S.N.Paneru, J.Pereira, E.Rubino, C.Santamaria, D.Schumann, J.Surbrook, L.Wagner, J.C.Zamora, V.Zelevinsky Evidence of a Near-Threshold Resonance in 11B Relevant to the β-Delayed Proton Emission of 11Be NUCLEAR REACTIONS 1H(10Be, X)11B, E=350 keV/nucleon; measured reaction products, Ep, Ip, Eα, Iα. 11B; deduced σ(θ), resonance parameters. R-matrix analysis. The ReA3 reaccelerator facility of the National Superconducting Cyclotron Laboratory.
doi: 10.1103/PhysRevLett.129.012501
2022KA20 Nucl.Phys. A1023, 122453 (2022) S.Karampagia, V.Zelevinsky, J.Spitler Ratio of consecutive level spacings as a signature of chaos in nuclear many-body models NUCLEAR STRUCTURE 52Ca, 52Sc, 52Ti; calculated chaotic features in the energy spectra of stationary states using the latest version of the nuclear shell model, along with the interacting boson model. Comparison with available data.
doi: 10.1016/j.nuclphysa.2022.122453
2020KA38 Int.J.Mod.Phys. E29, 2030005 (2020) Nuclear shell model and level density NUCLEAR STRUCTURE 26,27,28,29,30,31,32Si, 52Fe, 24Mg; calculated level densities.
doi: 10.1142/S0218301320300052
2019AU01 Phys.Rev. C 99, 024320 (2019) S.M.Austin, P.Paul, B.A.Brown, V.Zelevinsky Reactions leading to the first excited states of 7Li and 7Be and isospin-mixed states in 8Be NUCLEAR REACTIONS 6Li(d, p), (d, n), E=0.15-7.2 MeV; 7Li(p, p'), (p, n), E=3.0-10.0 MeV; measured Eγ and Iγ from the decays of 7Li (478-keV γ) and 7Be (429-keV γ) at the Stanford 3-MeV Van de Graaff and FN Tandem accelerator; deduced ratios of σ(d, p')/σ(d, n') and σ(p, p')/σ(p, n') as function of incident deuteron and proton energies, effects of isospin mixed states in the compound nucleus. 8Be; calculated levels, J, π using shell model with PJT interaction, and compared with experimental data.
doi: 10.1103/PhysRevC.99.024320
2019AY03 Phys.Rev.Lett. 123, 082501 (2019) Y.Ayyad, B.Olaizola, W.Mittig, G.Potel, V.Zelevinsky, M.Horoi, S.Beceiro Novo, M.Alcorta, C.Andreoiu, T.Ahn, M.Anholm, L.Atar, A.Babu, D.Bazin, N.Bernier, S.S.Bhattacharjee, M.Bowry, R.Caballero-Folch, M.Cortesi, C.Dalitz, E.Dunling, A.B.Garnsworthy, M.Holl, B.Kootte, K.G.Leach, J.S.Randhawa, Y.Saito, C.Santamaria, P.Siuryte, C.E.Svensson, R.Umashankar, N.Watwood, D.Yates Direct Observation of Proton Emission in 11Be RADIOACTIVITY 11Be(β-p) [from U(p, X), E=480 MeV]; measured decay products, Eβ, Iβ, Ep, Ip; deduced level energy, resonance parameters, J, π. Comparison with available data.
doi: 10.1103/PhysRevLett.123.082501
2018KA12 At.Data Nucl.Data Tables 120, 1 (2018) S.Karampagia, R.A.Senkov, V.Zelevinsky Level density of the sd-nuclei-Statistical shell-model predictions NUCLEAR STRUCTURE 19,20,21,22,23,24,25,26,27F, 19,20,21,22,23,24,25,26,27,28,29Ne, 20,21,22,23,24,25,26,27,28,29,30,31Na, 22,23,24,25,26,27,28,29,30,31Mg, 22,23,24,25,26,27,28,29,30,31,32Al, 23,24,25,26,27,28,29,30,31,32,33Si, 24,25,26,27,28,29,30,31,32,33,34P, 26,27,28,29,30,31,32,33,34,35S, 28,29,30,31,32,33,34,35,36Cl, 30,31,32,33,34,35,36,37Ar, 32,33,34,35,36,37K; calculated nuclear level density using the configuration-interaction nuclear shell model; deduced the parameters of the Constant Temperature phenomenological model.
doi: 10.1016/j.adt.2017.08.001
2018ZE02 Phys.Lett. B 783, 428 (2018) V.Zelevinsky, S.Karampagia, A.Berlaga Constant temperature model for nuclear level density NUCLEAR STRUCTURE 24Mg, 28,30Si; calculated nuclear level densities. Comparison with available data.
doi: 10.1016/j.physletb.2018.07.023
2017BR18 Phys.Rev.Lett. 119, 192504 (2017) B.A.Brown, G.F.Bertsch, L.M.Robledo, M.V.Romalis, V.Zelevinsky Nuclear Matrix Elements for Tests of Local Lorentz Invariance Violation NUCLEAR STRUCTURE 21Ne, 23Na, 133Cs, 173Yb, 201Hg; calculated quadrupole matrix elements. Self-consistent mean-field model (SCMF).
doi: 10.1103/PhysRevLett.119.192504
2017KA08 Phys.Rev. C 95, 024322 (2017) S.Karampagia, B.A.Brown, V.Zelevinsky Low energy magnetic radiation enhancement in the f7/2 shell NUCLEAR STRUCTURE 49,50Cr, 48V; calculated B(M1), γ-strength functions (γSF), distribution of M1 emission and absorption in the f7/2 shell-model basis; deduced that slope of the exponential fall off is proportional to the energy of the T=1 pairing gap. Comparison with experimental M1 strength functions.
doi: 10.1103/PhysRevC.95.024322
2017KA22 Nucl.Phys. A962, 46 (2017) S.Karampagia, A.Renzaglia, V.Zelevinsky Quantum phase transitions and collective enhancement of level density in odd-A and odd-odd nuclei NUCLEAR STRUCTURE 26,27,28Al, 30P, 50Mn; calculated levels, J, π, B(E2), B(M1) between discrete levels, quadrupole moments, level density using effective mean field plus interaction Hamiltonian in specific configuration space, namely sd and pf shells. Compared with available data.
doi: 10.1016/j.nuclphysa.2017.03.008
2017ZE03 Phys.Rev. C 96, 044319 (2017) V.Zelevinsky, N.Auerbach, B.M.Loc Nuclear structure features of Gamow-Teller excitations NUCLEAR STRUCTURE 44,46Ti; calculated B(E2), B(GT), anticorrelation between B(GT) and collectivity of the first B(E2) using the nuclear shell-model.
doi: 10.1103/PhysRevC.96.044319
2016BE42 Nature(London) 532, 448 (2016) Four neutrons together momentarily NUCLEAR STRUCTURE 4NN; analyzed available data; deduced evidence for the fleeting existence of this state, implications for neutron stars.
doi: 10.1038/nature17884
2016KA28 Phys.Rev. C 94, 014321 (2016) Nuclear shape transitions, level density, and underlying interactions NUCLEAR STRUCTURE 24Mg, 28Si, 52Fe; calculated energies, B(E2), and quadrupole moments of yrast 2+, 4+ and 6+ levels, and E(4+)/E(2+) ratios as functions of Hamiltonian parameters, either k1 or k2 with one kept fixed, cumulative number of levels, amplitudes of the ground-state wave functions in terms of proton and neutron components. Moments method, and varying the interaction matrix elements.
doi: 10.1103/PhysRevC.94.014321
2016SE10 Phys.Rev. C 93, 064304 (2016) Nuclear level density: Shell-model approach NUCLEAR STRUCTURE 24Mg, 28Si, 44Ca, 52Fe, 64Ge, 64Cr; calculated nuclear level densities using statistical model for a given shell-model Hamiltonian based on the chaotization of the intrinsic dynamics by interparticle interactions. A=20-80; analyzed single-particle level density parameters using experimental data on neutron resonances and experimental low-lying levels, comparison with Fermi Gas model.
doi: 10.1103/PhysRevC.93.064304
2015VO09 Phys.Rev.Lett. 115, 052501 (2015) A.Volya, H.A.Weidenmuller, V.Zelevinsky Neutron Resonance Widths and the Porter-Thomas Distribution NUCLEAR REACTIONS 96Mo(n, n), (n, γ), E not given; analyzed available data; calculated effective Hamiltonian that violate orthogonal invariance; deduced realistic estimates for the coupling to the neutron channel and for nonstatistical γ-decays yield significant modifications of the PTD distribution. Comparison with experimental data.
doi: 10.1103/PhysRevLett.115.052501
2015ZE05 Acta Phys.Pol. A128, 1008 (2015) Atomic Nucleus as Chaotic Quantum Many-Body System NUCLEAR STRUCTURE 28Si, 52Fe, 52Cr, 12C; calculated level densities, information entropy, effective temperature of individual states. Nuclear shell model, comparison with available data.
doi: 10.12693/APhysPolA.128.1008
2014AU04 Phys.Rev. C 90, 034315 (2014) Decay through a doorway state and the puzzle of 180Ta NUCLEAR STRUCTURE 180mTa; analyzed decay of mixed K excited state of an isomeric band populated in photon or Coulomb scattering with the states of other bands decaying to the ground state through a doorway state; described a mechanism contributing to the enhancement of decay rates from intermediate states to the ground state. Discussed experimental results.
doi: 10.1103/PhysRevC.90.034315
2014LE03 Phys.Rev. C 89, 011306 (2014) J.Le Bloas, N.Pillet, M.Dupuis, J.M.Daugas, L.M.Robledo, C.Robin, V.G.Zelevinsky First characterization of sd-shell nuclei with a multiconfiguration approach NUCLEAR STRUCTURE 20,22,24,26,28Ne, 22,24,26,28,30Mg, 24,26,28,30,32Si, 26,28,30,32,34S, 30,32,34,36Ar; calculated binding energies, S(2n), S(2p), energies and B(E2) of first 2+ states, magnetic dipole and electric static quadrupole moments, B(M1) for transitions between low-lying 1+, 2+ and 3+ states in spherical Hartree-Fock (HF) and multiparticle-multihole configuration mixing (CM) approximations with D1S Gogny interaction. Comparison with experimental values.
doi: 10.1103/PhysRevC.89.011306
2014VO09 Phys.Atomic Nuclei 77, 969 (2014) Continuum shell model and nuclear physics at the edge of stability NUCLEAR STRUCTURE 9C, 8B, 23,24,25,26,27,28O, 4,5,6,7,8,9,10He. calculated energy levels, J, π. Continuum Shell Model (CSM).
doi: 10.1134/S1063778814070163
2012AU04 Phys.Rev. C 86, 045501 (2012) Dipole resonances and the nuclear Schiff moment
doi: 10.1103/PhysRevC.86.045501
2012JI08 Phys.Rev. C 86, 014315 (2012) Validity of the generalized density matrix method for the microscopic calculation of a collective/bosonic Hamiltonian
doi: 10.1103/PhysRevC.86.014315
2012PI07 Phys.Rev. C 85, 044315 (2012) N.Pillet, V.G.Zelevinsky, M.Dupuis, J.-F.Berger, J.M.Daugas Low-lying spectroscopy of a few even-even silicon isotopes investigated with the multiparticle-multihole Gogny energy density functional NUCLEAR STRUCTURE 26,28,30,32Si; calculated triaxial HFB potential energy surfaces, β and γ deformation parameters, ground state collective wavefunctions, levels, J, π, proton and neutron single particle orbitals, E(4+)/E(2+) ratios, proton and neutron occupation probabilities, strength functions, Slater determinants, statistical properties of highly excited configurations. Multiconfiguration (mp-mh) microscopic method with DIS Gogny effective interaction. Comparison with calculations from five-dimensional (5DCH) approximate generator coordinate method (GCM), and with experimental data.
doi: 10.1103/PhysRevC.85.044315
2012SH32 Phys.Rev. C 86, 044602 (2012) Resonance width distribution for open quantum systems
doi: 10.1103/PhysRevC.86.044602
2011CE02 Phys.Rev.Lett. 106, 042501 (2011) G.L.Celardo, N.Auerbach, F.M.Izrailev, V.G.Zelevinsky Distribution of Resonance Widths and Dynamics of Continuum Coupling
doi: 10.1103/PhysRevLett.106.042501
2011JI12 Phys.Rev. C 84, 064311 (2011) Microscopic derivation of a collective bosonic Hamiltonian with the generalized density matrix method
doi: 10.1103/PhysRevC.84.064311
2011LE03 Phys.Lett. B 697, 454 (2011) A.Lemasson, A.Navin, M.Rejmund, N.Keeley, V.Zelevinsky, S.Bhattacharyya, A.Shrivastava, D.Bazin, D.Beaumel, Y.Blumenfeld, A.Chatterjee, D.Gupta, G.de France, B.Jacquot, M.Labiche, R.Lemmon, V.Nanal, J.Nyberg, R.G.Pillay, R.Raabe, K.Ramachandran, J.A.Scarpaci, C.Schmitt, C.Simenel, I.Stefan, C.N.Timis Pair and single neutron transfer with Borromean 8He NUCLEAR REACTIONS 197Au(8He, X)199Au, 65Cu(8He, X), E=19.9 MeV; measured reaction products, Eγ, Iγ; deduced 2n-transfer σ, model-independent ratio of 2n to 1n transfer reactions, absence of 67Cu nuclei.
doi: 10.1016/j.physletb.2011.02.038
2010HO05 Phys.Rev. C 81, 034306 (2010) Random interactions explore the nuclear landscape: Predominance of prolate nuclear deformations
doi: 10.1103/PhysRevC.81.034306
2009LE29 Phys.Rev.Lett. 103, 232701 (2009) A.Lemasson, A.Shrivastava, A.Navin, M.Rejmund, N.Keeley, V.Zelevinsky, S.Bhattacharyya, A.Chatterjee, G.de France, B.Jacquot, V.Nanal, R.G.Pillay, R.Raabe, C.Schmitt Modern Rutherford Experiment: Tunneling of the Most Neutron-Rich Nucleus NUCLEAR REACTIONS 197Au(8He, xn), (6He, xn), (α, xn)199Tl/200Tl/201Tl/202Tl, E=2.34, 2.51, 3.68 MeV/nucleon; measured x-rays, Eγ, Iγ; deduced σ for fusion, neutron transfer and evaporation residue.
doi: 10.1103/PhysRevLett.103.232701
2008SE09 Phys.Rev. C 78, 044304 (2008) R.A.Senkov, G.F.Bertsch, B.A.Brown, Y.L.Luo, V.G.Zelevinsky Many-body approximations in the sd-shell "sandbox" NUCLEAR STRUCTURE A=16-40;Z=8-20; calculated ground-state energies, pairing correlation energies, intrinsic electric quadrupole moments using Hartree-Fock variational scheme and exact binding energy differences solution.
doi: 10.1103/PhysRevC.78.044304
2008ZE04 Phys.Rev. C 78, 014310 (2008) V.Zelevinsky, A.Volya, N.Auerbach Nuclear Schiff moment and soft vibrational modes
doi: 10.1103/PhysRevC.78.014310
2007AU01 Nucl.Phys. A781, 67 (2007) Doorway states in nuclear reactions as a manifestation of the "super-radiant" mechanism
doi: 10.1016/j.nuclphysa.2006.10.078
2007AU07 Phys.Atomic Nuclei 70, 1654 (2007) N.Auerbach, V.F.Dmitriev, V.V.Flambaum, A.Lisetskiy, R.A.Senkov, V.G.Zelevinsky Is it possible to enhance the nuclear Schiff moment by nuclear collective modes? NUCLEAR MOMENTS 217,219,221Ra, 217,219,221Rn; calculated the nuclear Schiff moment using the QRPA formalism.
doi: 10.1134/S106377880709027X
2007HO10 Phys.Rev. C 75, 054303 (2007) Pairing phase transitions in nuclear wave functions NUCLEAR STRUCTURE 24Mg, 28Si; calculated pairing correlator in sd shell model.
doi: 10.1103/PhysRevC.75.054303
2007HO12 Phys.Rev.Lett. 98, 262503 (2007) Exact Removal of the Center-of-Mass Spurious States from Level Densities
doi: 10.1103/PhysRevLett.98.262503
2007MU19 Phys.Rev. C 76, 064611 (2007) D.Mulhall, Z.Huard, V.Zelevinsky Ergodicity of the Δ3 statistic and purity of neutron resonance data NUCLEAR STRUCTURE 50Cr, 54Fe, 58Ni, 152Sm, 152,154,158Gd, 182W, 234,236U, 240,242Pu; calculated Δ3(L), level densities, resonances, fluctuations of number of levels as a function of length of the spectral interval.
doi: 10.1103/PhysRevC.76.064611
2007SA14 Phys.Rev. C 75, 031001 (2007) Y.Safkan, T.Akdogan, W.A.Franklin, J.L.Matthews, W.M.Schmitt, V.V.Zelevinsky, P.A.M.Gram, T.N.Taddeucci, S.A.Wender, S.F.Pate Differential cross section for neutron-proton bremsstrahlung NUCLEAR REACTIONS 1H(n, n'γ), E=175-275 MeV; measured Ep, En, σ(θ(n), θ(p), θ(γ)). Comparison with relativistic soft-photon and nonrelativistic models.
doi: 10.1103/PhysRevC.75.031001
2007ST16 Phys.Rev.Lett. 99, 042503 (2007) K.Starosta, A.Dewald, A.Dunomes, P.Adrich, A.M.Amthor, T.Baumann, D.Bazin, M.Bowen, B.A.Brown, A.Chester, A.Gade, D.Galaviz, T.Glasmacher, T.Ginter, M.Hausmann, M.Horoi, J.Jolie, B.Melon, D.Miller, V.Moeller, R.P.Norris, T.Pissulla, M.Portillo, W.Rother, Y.Shimbara, A.Stolz, C.Vaman, P.Voss, D.Weisshaar, V.Zelevinsky Shape and Structure of N=Z 64Ge: Electromagnetic Transition Rates from the Application of the Recoil Distance Method to a Knockout Reaction NUCLEAR REACTIONS 93Nb(65Ge, n), (63Zn, n), E not given; measured Eγ, Iγ and transition rates using recoil distance method. 64Ge, 62Zn deduced B(E2) and lifetimes.
doi: 10.1103/PhysRevLett.99.042503
2007VA22 Phys.Rev.Lett. 99, 162501 (2007) C.Vaman, C.Andreoiu, D.Bazin, A.Becerril, B.A.Brown, C.M.Campbell, A.Chester, J.M.Cook, D.C.Dinca, A.Gade, D.Galaviz, T.Glasmacher, M.Hjorth-Jensen, M.Horoi, D.Miller, V.Moeller, W.F.Mueller, A.Schiller, K.Starosta, A.Stolz, J.R.Terry, A.Volya, V.Zelevinsky, H.Zwahlen Z=50 Shell Gap near 100Sn from Intermediate-Energy Coulomb Excitations in Even-Mass 106-112Sn Isotopes NUCLEAR REACTIONS 197Au(106Sn, 106Sn'), (108Sn, 108Sn'), (110Sn, 110sn'), (112Sn, 112Sn'), E=78-81 MeV; measured Eγ, Iγ, (particle)γ-coinc from projectile coulomb excitation. 106,108,110,112Sn deduced B(E2).
doi: 10.1103/PhysRevLett.99.162501
2007VO07 Nucl.Phys. A788, 251c (2007) Collective many-body dynamics in the vicinity of nuclear driplines NUCLEAR STRUCTURE O; calculated neutron scattering σ, isovector dipole strength distributions, level energy and width of un-bound neutron states with continuum shell model.
doi: 10.1016/j.nuclphysa.2007.01.094
2006AU02 Phys.Rev. C 74, 025502 (2006) N.Auerbach, V.F.Dmitriev, V.V.Flambaum, A.Lisetskiy, R.A.Sen'kov, V.G.Zelevinsky Nuclear Schiff moment in nuclei with soft octupole and quadrupole vibrations NUCLEAR STRUCTURE 217,219,221Ra; calculated Schiff moments, role of soft collective quadrupole and octupole vibrations. Quasiparticle RPA. NUCLEAR MOMENTS 217,219,221Ra; calculated Schiff moments, role of soft collective quadrupole and octupole vibrations. Quasiparticle RPA.
doi: 10.1103/PhysRevC.74.025502
2006MU04 Phys.Rev. C 73, 014316 (2006) W.F.Mueller, M.P.Carpenter, J.A.Church, D.C.Dinca, A.Gade, T.Glasmacher, D.T.Henderson, Z.Hu, R.V.F.Janssens, A.F.Lisetskiy, C.J.Lister, E.F.Moore, T.O.Pennington, B.C.Perry, I.Wiedenhover, K.L.Yurkewicz, V.G.Zelevinsky, H.Zwahlen Variation with mass of B(E3;0+1 → 3-1) transition rates in A = 124-134 even-mass xenon nuclei NUCLEAR REACTIONS 58Ni(124Xe, 124Xe'), (126Xe, 126Xe'), (128Xe, 128Xe'), (130Xe, 130Xe'), (132Xe, 132Xe'), (134Xe, 134Xe'), E ≈ 550-580 MeV; measured Eγ, Iγ, (particle)γ-coin following projectile Coulomb excitation. 124,126,128,130,132,134Xe deduced levels, J, π, B(E2), B(E3).
doi: 10.1103/PhysRevC.73.014316
2006VO13 Phys.Scr. T125, 224 (2006) Collective dipole excitations in the continuum shell model
doi: 10.1088/0031-8949/2006/T125/062
2006VO14 Phys.Rev.C 74, 064314 (2006) Continuum shell model NUCLEAR STRUCTURE 4,5,6,7,8,9,10He, 16,17,18,19,20,21,22,23,24,25,26,27,28O; calculated level energies, widths, neutron scattering σ. Continuum shell model.
doi: 10.1103/PhysRevC.74.064314
2006ZE04 Phys.Scr. T125, 147 (2006) Quantum chaos and nuclear physics
doi: 10.1088/0031-8949/2006/T125/034
2005FL01 J.Phys.(London) G31, 355 (2005) Quantum tunnelling of a complex system: effects of a finite size and intrinsic structure
doi: 10.1088/0954-3899/31/5/006
2005HO24 Nucl.Phys. A758, 142c (2005) M.Horoi, M.Ghita, V.Zelevinsky Comparison of approaches for spin- and parity-dependent shell model nuclear level density NUCLEAR STRUCTURE 28Si; calculated spin- and parity-dependent shell model level densities. Several approaches compared.
doi: 10.1016/j.nuclphysa.2005.05.029
2005VO01 Phys.Rev.Lett. 94, 052501 (2005) Discrete and Continuum Spectra in the Unified Shell Model Approach NUCLEAR STRUCTURE 4,5,6,7,8,9,10He, 16,17,18,19,20,21,22,23,24,25,26,27,28O; calculated levels, J, π. Continuum shell model, comparison with data.
doi: 10.1103/PhysRevLett.94.052501
2005ZE02 Nucl.Phys. A752, 325c (2005) The nuclear pairing problem: new perspectives
doi: 10.1016/j.nuclphysa.2005.02.047
2004HO10 Phys.Rev. C 69, 041307 (2004) M.Horoi, M.Ghita, V.Zelevinsky Fixed spin and parity nuclear level density for restricted shell model configurations
doi: 10.1103/PhysRevC.69.041307
2004ST19 Phys.Rev. C 70, 014302 (2004) High-lying single-particle modes, chaos, correlational entropy, and doubling phase transition NUCLEAR STRUCTURE 209Pb; calculated single-particle strength distribution, invariant correlational entropy. Quasiparticle-phonon model.
doi: 10.1103/PhysRevC.70.014302
2004ZE01 Phys.Rep. 391, 311 (2004) Nuclear structure, random interactions and mesoscopic physics
doi: 10.1016/j.physrep.2003.10.008
2004ZE03 Nucl.Phys. A731, 299 (2004) Pairing correlations in nuclei: old knowledge and new ideas
doi: 10.1016/j.nuclphysa.2003.11.041
2003BE46 J.Phys.(London) G29, 2431 (2003) Is the tetraneutron a bound dineutron-dineutron molecule? NUCLEAR STRUCTURE 4n; calculated dinuetron-dineutron molecular potential; deduced no bound state.
doi: 10.1088/0954-3899/29/10/309
2003FL03 Phys.Rev. C 68, 035502 (2003) Enhancement of nuclear Schiff moments and time-reversal violation in atoms due to soft nuclear octupole vibrations NUCLEAR MOMENTS 223Rn, 223,225Ra; calculated nuclear Schiff moments, atomic electric dipole moments, role of soft octupole vibrations. NUCLEAR STRUCTURE 223Rn, 223,225Ra; calculated nuclear Schiff moments, atomic electric dipole moments, role of soft octupole vibrations.
doi: 10.1103/PhysRevC.68.035502
2003HO04 Phys.Rev. C 67, 034303 (2003) M.Horoi, B.A.Brown, V.Zelevinsky Exponential convergence method: Nonyrast states, occupation numbers, and a shell-model description of the superdeformed band in 56Ni NUCLEAR STRUCTURE 52Cr, 56Ni; calculated single-particle configurations. 56Ni deduced superdeformed band features. Exponential convergence method.
doi: 10.1103/PhysRevC.67.034303
2003HO08 Phys.Rev. C 67, 054309 (2003) M.Horoi, J.Kaiser, V.Zelevinsky Spin- and parity-dependent nuclear level densities and the exponential convergence method
doi: 10.1103/PhysRevC.67.054309
2003HO18 Nucl.Phys. A718, 502c (2003) M.Horoi, R.Jora, V.Zelevinsky, A.St.J.Murphy, R.N.Boyd, T.Rauscher The 45V(p, γ) thermonuclear reaction rate relevant to 44Ti production rate in core-collapsed supernovae: a shell model analysis NUCLEAR REACTIONS 45V(p, γ), E=low; calculated astrophysical reaction rates. Shell model approach. NUCLEAR STRUCTURE 46Cr; calculated levels, J, π, spectroscopic factors. Shell model.
doi: 10.1016/S0375-9474(03)00870-4
2003VO10 Phys.Rev. C 67, 054322 (2003) Non-Hermitian effective Hamiltonian and continuum shell model
doi: 10.1103/PhysRevC.67.054322
2003VO17 Phys.Lett. B 574, 27 (2003) Invariant correlational entropy as a signature of quantum phase transitions in nuclei NUCLEAR STRUCTURE 24Mg, 48Ca; calculated invariant correlational entropy, interaction parameter dependences, phase transition features.
doi: 10.1016/j.physletb.2003.08.076
2003ZE05 Yad.Fiz. 66, 1829 (2003); Phys.Atomic Nuclei 66, 1781 (2003) Nuclear Pairing: New Perspectives
doi: 10.1134/1.1619492
2002AU02 Phys.Rev. C65, 034601 (2002) ' Super-Radiant ' States and Narrow Resonances in the Δ-Nucleus System NUCLEAR STRUCTURE 12C; calculated Δ-nucleus configurations, possible super-radiant state formation.
doi: 10.1103/PhysRevC.65.034601
2002DM01 Phys.Rev. C65, 015803 (2002) V.F.Dmitriev, V.Zelevinsky, S.M.Austin Do Hadronic Charge Exchange Reactions Measure Electroweak L = 1 Strength ? NUCLEAR REACTIONS 12C(p, n), E=135 MeV; calculated σ(E, θ); deduced relationship with β-decay strengths. Eikonal model.
doi: 10.1103/PhysRevC.65.015803
2002HO03 Phys.Rev. C65, 027303 (2002) M.Horoi, B.A.Brown, V.Zelevinsky Applying the Exponential Convergence Method: Shell-model binding energies of 0f7/2 Nuclei Relative to 40Ca NUCLEAR STRUCTURE 42,43Sc, 44,45Ti, 46,47V, 48,49Cr, 50,51Mn, 52,53Fe, 54,55Co, 56Ni; calculated ground-state energies, J, π. Exponential convergence method, comparison with data.
doi: 10.1103/PhysRevC.65.027303
2002HO14 Phys.Rev. C66, 015801 (2002) M.Horoi, R.Jora, V.Zelevinsky, A.St.J.Murphy, R.N.Boyd, T.Rauscher 45V(p, γ) Thermonuclear Reaction Rate Relevant to 44Ti Production in Core-Collapse Supernovae: General Estimates and Shell Model Analysis NUCLEAR REACTIONS 45V(p, γ), E ≈ 0.1-2 MeV; calculated astrophysical S-factors, reaction rate, resonance contributions. Shell model analysis.
doi: 10.1103/PhysRevC.66.015801
2002HO16 Phys.Rev. C66, 024319 (2002) M.Horoi, A.Volya, V.Zelevinsky Random interactions, isospin, and the ground states of odd-A and odd-odd nuclei NUCLEAR STRUCTURE 20,21Ne, 21,22,23Na, 23,24,25Mg, 25,26,27Al, 27,28Si, 30P, 34Cl, 38K, 42Sc, 46V; calculated most probable spin, isospin quantum numbers for ground states. Random interaction model.
doi: 10.1103/PhysRevC.66.024319
2002PR09 Phys.Rev. C65, 061304 (2002) B.V.Pritychenko, T.Glasmacher, P.D.Cottle, R.W.Ibbotson, K.W.Kemper, L.A.Riley, A.Sakharuk, H.Scheit, M.Steiner, V.Zelevinsky Structure of the ' Island of Inversion ' Nucleus 33Mg NUCLEAR REACTIONS 197Au(33Mg, 33Mg'), E=61.8 MeV/nucleon; measured Eγ, Iγ, (particle)γ-coin following projectile Coulomb excitation. 33Mg deduced level excitation B(E2), J, π, configuration, deformation.
doi: 10.1103/PhysRevC.65.061304
2002VO10 Phys.Rev. C65, 054312 (2002) A.Volya, V.Zelevinsky, B.A.Brown Coherent and Chaotic Properties of Nuclear Pairing NUCLEAR STRUCTURE 114,116,118Sn; calculated level energies, level densities, pairing interaction effects.
doi: 10.1103/PhysRevC.65.054312
2002VO20 Prog.Theor.Phys.(Kyoto), Suppl. 146, 636 (2002) A.Volya, B.A.Brown, V.Zelevinsky Towards a Better Understanding of Nuclear Pairing and Its Interplay with Other Residual Interactions NUCLEAR STRUCTURE Sn; calculated neutron separation energies, role of pairing interaction. Self-consistent Hartree-Fock plus exact pairing, comparison with data.
doi: 10.1143/PTPS.146.636
2002ZE08 Yad.Fiz. 65, 1220 (2002); Phys.Atomic Nuclei 65, 1188 (2002) Nuclear Physics and Ideas of Quantum Chaos
doi: 10.1134/1.1495018
2001AL37 J.Phys.(London) G27, 2345 (2001) B.L.Altshuler, V.V.Flambaum, M.Yu.Kuchiev, V.G.Zelevinsky ' Colliding Beam ' Enhancement Mechanism of Deuteron-Deuteron Fusion Reactions in Matter NUCLEAR REACTIONS 2H(d, X), E=low; calculated enhancement mechanism for fusion reactions in matter.
doi: 10.1088/0954-3899/27/11/312
2001DA28 Phys.Rev. C64, 064319 (2001); Erratum Phys.Rev. C65, 069903 (2002) Improved Treatment of Ground-State Correlations: Modified random phase approximation NUCLEAR STRUCTURE 120Sn; calculated neutron pairing gap vs temperature. Modified RPA.
doi: 10.1103/PhysRevC.64.064319
2001HO27 Phys.Rev.Lett. 87, 062501 (2001) M.Horoi, B.A.Brown, V.Zelevinsky Random versus Realistic Interactions for Low-Lying Nuclear Spectra
doi: 10.1103/PhysRevLett.87.062501
2001MU09 Nucl.Phys. A682, 229c (2001) D.Mulhall, A.Volya, V.Zelevinsky Random Interactions: Shedding light on nuclear structure
doi: 10.1016/S0375-9474(00)00644-8
2001MU27 Acta Phys.Pol. B32, 2491 (2001) D.Mulhall, V.Zelevinsky, A.Volya Spin Ordering of Nuclear Spectra from Random Interactions
2001PA47 Phys.Lett. 523B, 1 (2001) E.A.Pasyuk, R.L.Boudrie, P.A.M.Gram, C.L.Morris, J.D.Zumbro, J.L.Matthews, Y.Tan, V.V.Zelevinsky, G.Glass, B.J.Kriss A Study of the Δ--Component of the Wave Function in Light Nuclei NUCLEAR REACTIONS 3H, 4He, 6,7Li(π+, π+pX), (π+, π-pX), E=500 MeV; measured pion and proton spectra, σ. 3H, 4He, 6,7Li deduced Δ resonance component of wave function.
doi: 10.1016/S0370-2693(01)01329-6
2001VO12 Phys.Lett. 509B, 37 (2001) A.Volya, B.A.Brown, V.Zelevinsky Exact Solution of the Nuclear Pairing Problem NUCLEAR STRUCTURE Ca; calculated neutron separation energies. Sn; calculated pairing correlation energy. Exact pairing method.
doi: 10.1016/S0370-2693(01)00431-2
2001ZE03 Yad.Fiz. 64, No 3, 579 (2001); Phys.Atomic Nuclei 64, 525 (2001) V.G.Zelevinsky, D.Mulhall, A.Volya Do We Understand the Role of Incoherent Interactions in Many-Body Physics ?
doi: 10.1134/1.1358477
2000BR54 Phys.Rev. C62, 044313 (2000) B.A.Brown, V.Zelevinsky, N.Auerbach Microscopic Calculation of Double-Dipole Excitations NUCLEAR STRUCTURE 16O, 40Ca; calculated single-, double-dipole strength distributions. Shell model.
doi: 10.1103/PhysRevC.62.044313
2000DM03 Nucl.Phys. A663-664, 1099c (2000) V.F.Dmitriev, G.N.Kulipanov, D.M.Nikolenko, I.A.Rachek, A.N.Skrinsky, D.K.Toporkov, N.A.Vinokurov, V.G.Zelevinsky New Possibilities for Nuclear Physics Experiments with Novosibirsk Race-Track Microtron-Recuperator
doi: 10.1016/S0375-9474(99)00786-1
2000MU19 Phys.Rev.Lett. 85, 4016 (2000) D.Mulhall, A.Volya, V.Zelevinsky Geometric Chaoticity Leads to Ordered Spectra for Randomly Interacting Fermions
doi: 10.1103/PhysRevLett.85.4016
2000SA03 Phys.Rev. C61, 014609 (2000) Particle Removal Reactions with Deformed Projectiles NUCLEAR REACTIONS 9Be(25Al, p24Mg), (28P, p27Si), E ≈ 65 MeV/nucleon; analyzed longitudinal momentum distributions; deduced projectile deformation effects, other reaction mechanism features. 9Be(30Mg, n29Mg), E not given; calculated longitudinal momentum distributions.
doi: 10.1103/PhysRevC.61.014609
2000VO07 Nucl.Phys. A671, 617 (2000) A.Volya, S.Pratt, V.Zelevinsky Multiple Pion Production from an Oriented Chiral Condensate
doi: 10.1016/S0375-9474(99)00560-6
1999BE36 Phys.Rev. C60, 031602 (1999) C.A.Bertulani, D.T.de Paula, V.G.Zelevinsky Bremsstrahlung Radiation by a Tunneling Particle: A time-dependent description
doi: 10.1103/PhysRevC.60.031602
1999HO05 Phys.Rev.Lett. 82, 2064 (1999) M.Horoi, A.Volya, V.Zelevinsky Chaotic Wave Functions and Exponential Convergence of Low-Lying Energy Eigenvalues NUCLEAR STRUCTURE 48Cr, 51Sc; calculated levels, J, π; deduced model convergence features, truncation criteria. Shell model, quantum chaotic many-body dynamics.
doi: 10.1103/PhysRevLett.82.2064
1999PR09 Phys.Lett. 461B, 322 (1999); Erratum Phys.Lett. 467B, 309 (1999) B.V.Pritychenko, T.Glasmacher, P.D.Cottle, M.Fauerbach, R.W.Ibbotson, K.W.Kemper, V.Maddalena, A.Navin, R.Ronningen, A.Sakharuk, H.Scheit, V.G.Zelevinsky Role of Intruder Configurations in 26, 28Ne and 30, 32Mg NUCLEAR REACTIONS 197Au(26Ne, 26Ne'), (28Ne, 28Ne'), (30Mg, 30Mg'), (32Mg, 32Mg'), (34Mg, 34Mg'), (36Ar, 36Ar'), E ≈ 50 MeV/nucleon; measured Eγ, Iγ, (particle)γ-coin following projectile Coulomb excitation. 26,28Ne, 30,32Mg deduced levels energies, excitation B(E2), configurations. Secondary beams from 48Ca, 40Ar fragmentation. NUCLEAR STRUCTURE 26,28Ne, 30,32,34Mg calculated quadrupole moments, deformation. Nilsson model.
doi: 10.1016/S0370-2693(99)00850-3
1999SA27 Phys.Rev. C60, 014605 (1999) A.Sakharuk, V.Zelevinsky, V.G.Neudatchin Quasielastic Knock-Out of Clusters by Electrons and Nuclear Restructuring Effects NUCLEAR REACTIONS 12C(e, e'α), E=637 MeV; calculated σ(E, θ(e), θ(α)); deduced structure effects.
doi: 10.1103/PhysRevC.60.014605
1999VO01 Phys.Rev. C59, 305 (1999) A.Volya, S.Pratt, V.Zelevinsky Modeling Pionic Fusion NUCLEAR REACTIONS 1H(p, π+), 3He(3He, π+), 12C(12C, π0), E ≈ threshold; calculated reaction σ vs pion energy. Harmonic oscillator wave functions, sudden overlap approximation. Comparisons with data.
doi: 10.1103/PhysRevC.59.305
1999ZE03 Nucl.Phys. A649, 403c (1999) Chaotic Dynamics and Collective Modes
doi: 10.1016/S0375-9474(99)00090-1
1997FR22 Phys.Lett. 414B, 7 (1997) N.Frazier, B.A.Brown, D.J.Millener, V.Zelevinsky Gamow-Teller Strength as a Function of Excitation Energy NUCLEAR STRUCTURE 24Mg; calculated total Gamow-Teller strength vs excitation energy; deduced spatial symmetry energy dependence. Shell model.
doi: 10.1016/S0370-2693(97)01144-1
1997SA04 Phys.Rev. C55, 302 (1997) Quasielastic Knockout of Alpha Clusters by Intermediate Energy Protons: Signatures of virtually excited states NUCLEAR REACTIONS 12C(p, p'α), E=300 MeV; calculated σ(θp, θα, Ep); deduced virtually excited target cluster configurations role. Quasielastic α-knockout, Glauber approximation.
doi: 10.1103/PhysRevC.55.302
1997SO10 Phys.Rev. C56, 311 (1997) Simple Mode on a Highly Excited Background: Collective strength and damping in the continuum
doi: 10.1103/PhysRevC.56.311
1996FR14 Phys.Rev. C54, 1665 (1996) N.Frazier, B.A.Brown, V.Zelevinsky Strength Functions and Spreading Widths of Simple Shell Model Configurations
doi: 10.1103/PhysRevC.54.1665
1996KU24 Phys.Lett. 385B, 5 (1996) D.Kusnezov, B.A.Brown, V.Zelevinsky Statistical Correlations in Nuclear Many-Body States
doi: 10.1016/0370-2693(96)00853-2
1996ZE05 Phys.Rep. 276, 85 (1996) V.Zelevinsky, B.A.Brown, N.Frazier, M.Horoi The Nuclear Shell Model as a Testing Ground for Many-Body Quantum Chaos
doi: 10.1016/S0370-1573(96)00007-5
1995BA09 Nucl.Phys. A583, 93c (1995) W.Bauer, D.McGrew, V.Zelevinsky, P.Schuck Regular and Chaotic Dynamics in Giant Nuclear Oscillations
doi: 10.1016/0375-9474(94)00637-3
1995FL07 Phys.Lett. 350B, 8 (1995) Possible Doublet Mechanism for a Regular Component of Parity Violation in Neutron Scattering NUCLEAR REACTIONS 232Th(polarized n, n), E not given; calculated parity nonconserving asymmetry; deduced possible doublet mechanism role in observed sign correlations.
doi: 10.1016/0370-2693(95)00325-F
1995HO16 Phys.Rev.Lett. 74, 5194 (1995) M.Horoi, V.Zelevinsky, B.A.Brown Chaos vs Thermalization in the Nuclear Shell Model
doi: 10.1103/PhysRevLett.74.5194
1995LA19 Phys.Rev.Lett. 74, 5190 (1995) B.Lauritzen, P.F.Bortignon, R.A.Broglia, V.G.Zelevinsky Limiting Value for the Width Controlling the Coupling of Collective Vibrations to the Compound Nucleus
doi: 10.1103/PhysRevLett.74.5190
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