NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = Z.Zhu Found 62 matches. 2024SH13 Nucl.Instrum.Methods Phys.Res. A1062, 169222 (2024) X.-M.Shi, G.-L.Wang, K.-J.Luo, X.-X.Li, Zh.-Ch.Zhu, W.Luo Geant4 development for actinides photofission simulation NUCLEAR REACTIONS 232Th(γ, F), E=16 MeV; 235U(γ, F), E=13 MeV; 238U(γ, F), E=17.2 MeV; 242Pu(γ, F), E=20 MeV; calculated mass yield distri'butions (MYD), the isobaric charge distributions (ICD), and the multiplicity and spectral distributions with the Geant4 simulations. comparison with the available experimental data.
doi: 10.1016/j.nima.2024.169222
2023AN14 Sci. Rep. 13, 12657 (2023) Z.An, W.Qiu, W.Jiang, G.Yang, X.Li, Z.Liao, Z.Zhuang, X.Zhang, S.Chen, C.Guo, E.Xiao, X.Fang, X.Li, H.Wang, X.Hu, Bi.Jiang, W.Shen, J.Wang, J.Ren, X.Ruan, D.Wang, S.-Y.Zhang, W.Luo, Z.Zhu, H.Lan, Z.Cao, X.Ma, Y.Liu, P.Wang, Y.Yang, P.Su, X.Deng, W.He, Y.Ma, C.Ma, Y.Wang, P.He, R.Tang, T.Zhou, J.Wang, H.Yi, Y.Zhang, Y.Chen, R.Fan, K.Gao, Q.Li, K.Sun, Z.Tan, M.Gu, H.Jing, J.Tang Measurement of the 181Ta(n, γ) cross sections up to stellar s-process temperatures at the CSNS Back-n NUCLEAR REACTIONS 181Ta(n, γ), E=0.001-800 keV; measured reaction products, En, In, TOF; deduced σ, resonance parameters using the R-Matrix code SAMMY, Maxwellian average cross sections (MACS). Comparison with available data. The back-streaming white neutron facility (Back-n) of China spallation neutron source (CSNS).
doi: 10.1038/s41598-023-39603-7
2023ZH43 Phys.Rev. C 108, 025809 (2023) Equation of state of nuclear matter and neutron stars: Quark mean-field model versus relativistic mean-field model
doi: 10.1103/PhysRevC.108.025809
2022WA31 Chin.Phys.C 46, 084102 (2022) G.-L.Wang, H.-Y.Lan, X.-M.Shi, Z.-C.Zhu, W.Luo A general framework for describing photofission observables of actinides at an average excitation energy below 30 MeV NUCLEAR REACTIONS 232Th, 235,238U, 240Pu(γ, F), E<30 MeV; analyzed available data. 85Se, 87,88,89Br, 88,89,90,91,92Kr, 91,92,93,94,95Rb, 93,94,95,96,97Sr, 96,97,98,99,100Y, 98,99,100,101,102Zr, 101,102,103,104Nb, 104,105Mo, 130Sn, 130,131,132,133Sb, 132,133,134,135,136Te; calculated yields of photofission, neutron multiplicity and spectral distributions, nubar.
doi: 10.1088/1674-1137/ac6abc
2022ZH35 Eur.Phys.J. A 58, 104 (2022) Gravitational waves from holographic QCD phase transition with gluon condensate
doi: 10.1140/epja/s10050-022-00754-2
2022ZH52 Phys.Rev. C 106, 034604 (2022) Simulating fusion reactions from Coulomb explosions within a transport approach NUCLEAR REACTIONS 2H(d, 3He), E=2-10 keV; calculated fusion σ(E), reaction rate at different temperatures, time evolution of the Coulomb explosion of deuterium clusters induced by high intensity laser beams, neutron production rate in Coulomb explosion. EPOCH model framework - typical particle-in-cell (PIC) transport approach, to simulate the Coulomb explosion of clusters with electrons completely stripped by laser beams, modified to incorporate fusion reactions by introducing nuclear inelastic scattering channels.
doi: 10.1103/PhysRevC.106.034604
2021PA03 Appl.Radiat.Isot. 168, 109534 (2021) W.t.Pan, T.Song, H.-y.Lan, Z.-g.Ma, J.-l.Zhang, Z.-c.Zhu, W.Luo Photo-excitation production of medically interesting isomers using intense γ-ray source NUCLEAR REACTIONS 103Rh, 113,115In, 176Lu(γ, γ'), E<30 MeV; calculated isomer production σ, specific activities, yields; deduced suitable decay properties for photo-excitation approach.
doi: 10.1016/j.apradiso.2020.109534
2020ZH07 Eur.Phys.J. A 56, 57 (2020) The effect of gluon condensate on imaginary potential and thermal width from holography
doi: 10.1140/epja/s10050-020-00072-5
2019ZH10 Phys.Rev. C 99, 025804 (2019) Z.-Y.Zhu, A.Li, J.-N.Hu, H.Shen Quark mean-field model for nuclear matter with or without bag
doi: 10.1103/PhysRevC.99.025804
2018LA14 Phys.Rev. C 98, 054601 (2018) H.Y.Lan, Y.Xu, W.Luo, D.L.Balabanski, S.Goriely, M.La Cognata, C.Matei, A.Anzalone, S.Chesnevskaya, G.L.Guardo, D.Lattuada, R.G.Pizzone, S.Romano, C.Spitaleri, A.Taffara, A.Tumino, Z.C.Zhu Determination of the photodisintegration reaction rates involving charged particles: Systematic calculations and proposed measurements based on the facility for Extreme Light Infrastructure--Nuclear Physics NUCLEAR REACTIONS 74Se, 84Sr, 92Mo, 96Ru, 102Pd, 106Cd, 112Sn, 120Te(γ, p), E(cm)=8-20 MeV; 74Se, 84Sr, 92Mo, 96Ru, 102Pd, 106Cd, 112Sn, 120Te, 132Ba, 144Sm, 148Gd, 184Os(γ, α), E(cm)=6-20 MeV; calculated σ(E), proton and α-particle spectra and yields, Gamow windows at T9=2.5 and minimum required energies of the incident γ beam satisfying the measurable criteria of the minimum detectable limit and the particle identification. Z=10-100, N=10-160; calculated ratios of the (γ, p) and (γ, α) astrophysical reaction rates at T9=2.5 for 3000 targets of stable and proton-rich nuclei. Optical potential model calculations using Woods-Saxon and microscopic folding JLMB optical model potentials. Relevance to p-process nucleosynthesis, and the measurements of six (γ, p) and eight (γ, α) reactions based on the γ-beam facility and the Extreme Light Infrastructure Silicon Strip Array (ELISSA) for the detection of charged particles at ELI-NP, Bucharest facility.
doi: 10.1103/PhysRevC.98.054601
2018ZH13 Phys.Rev. C 97, 035805 (2018) Effects of the nucleon radius on neutron stars in a quark mean field model
doi: 10.1103/PhysRevC.97.035805
2016ZH01 Ann.Nucl.Energy 89, 109 (2016) Z.i-C.Zhu, W.Luo, Z.-C.Li, Y.-M.Song, X.-D.Wang, X.-L.Wang, G.-T.Fan Photo-transmutation of long-lived nuclear waste 135Cs by intense Compton γ-ray source NUCLEAR REACTIONS 137Cs(γ, n), (γ, 2n), (γ, α), (γ, p), (γ, np), (n, γ), (E, n), (p, 2n), (γ, X), E<25 MeV; calculated σ. GEANT4 and TALYS simulations, comparison with available data.
doi: 10.1016/j.anucene.2015.11.017
2016ZH45 Phys.Rev. C 94, 045803 (2016); Erratum Phys.Rev. C 102, 019905 (2020) Z.-Y.Zhu, A.Li, J.-N.Hu, H.Sagawa Δ(1232) effects in density-dependent relativistic Hartree-Fock theory and neutron stars
doi: 10.1103/PhysRevC.94.045803
2014ZH09 Phys.Rev. C 89, 034307 (2014) Z.-L.Zhu, Z.-M.Niu, D.-P.Li, Q.Liu, J.-Y.Guo Probing single-proton resonances in nuclei by the complex-scaling method NUCLEAR STRUCTURE 114,116,118,120,122,124,132Sn, 126Ru, 128Pd, 130Cd, 134Te, 136Xe; calculated energies and width of single-proton resonant states. 40Ca, 56,78Ni, 100,132Sn, 208Pb; calculated difference of energies of single-proton resonant states for doubly magic nuclei with and without Coulomb exchange terms. Complex scaling method with relativistic mean-field theory (RMF-CMS). Comparison with other theoretical calculations.
doi: 10.1103/PhysRevC.89.034307
2013NI14 Phys.Rev. C 88, 024325 (2013) Z.M.Niu, Z.L.Zhu, Y.F.Niu, B.H.Sun, T.H.Heng, J.Y.Guo Radial basis function approach in nuclear mass predictions ATOMIC MASSES Z=8-108, N=8-160; calculated masses using radial basis function approach with eight nuclear mass models; comparison with AME-1995, AME-2003 and AME-2012 evaluated masses. Discussed potential of RBF approach in prediction of masses.
doi: 10.1103/PhysRevC.88.024325
2010JI15 Eur.Phys.J. A 44, 465 (2010) W.Z.Jiang, Z.Z.Ren, Z.Q.Sheng, Z.Y.Zhu Sensitivity of de-excitation energies of superdeformed secondary minima to the density dependence of symmetry energy with the relativistic mean-field theory NUCLEAR STRUCTURE 191,192,194Hg, 194,196,198,200Au; calculated ground state and superdeformed secondary minima properties, radii, deformation, neutron skin thickness using relativistic mean field model.
doi: 10.1140/epja/i2010-10962-6
2009HU20 Chin.Phys.C 33, Supplement 1, 193 (2009) W.-X.Huang, J.-Y.Wang, Y.Wang, Y.-L.Tian, Z.-C.Zhu, H.-S.Xu, G.-Q.Xiao Simulation of the Lanzhou Penning Trap LPT
doi: 10.1088/1674-1137/33/S1/062
2008WA13 Chin.Phys.Lett. 25, 2831 (2008) Phenomenological Study of 3He Photodisintegration up to 150 MeV NUCLEAR REACTIONS 3He(γ, p), E=9-150 MeV; analyzed cross sections.
doi: 10.1088/0256-307X/25/8/027
2005CH09 Chin.Phys.Lett. 22, 302 (2005) B.-Q.Chen, Z.Yu.Ma, Z.-Y.Zhu, H.-Q.Song, Y.-L.Zhao Deformed Potential Energy of Super Heavy Element Z = 120 in a Generalized Liquid Drop Model NUCLEAR REACTIONS 244Pu(58Fe, X), 208Pb(88Sr, X), (94Sr, X), 166Dy(136Xe, X), 252Fm(50Ca, X), E not given; calculated deformed potential energies for fusion reactions. Generalized liquid drop model.
doi: 10.1088/0256-307X/22/2/010
2005JI06 Eur.Phys.J. A 25, 29 (2005) W.Z.Jiang, Z.Z.Ren, T.T.Wang, Y.L.Zhao, Z.Y.Zhu Relativistic mean-field study for Zn isotopes NUCLEAR STRUCTURE 52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74,75Zn; calculated binding energies, radii, deformation. Relativistic mean-field approach.
doi: 10.1140/epja/i2004-10235-1
2005JI07 Phys.Rev. C 72, 024313 (2005) W.Z.Jiang, Y.L.Zhao, Z.Y.Zhu, S.F.Shen Role of ρNN tensor coupling and 2s1/2 occupation in light exotic nuclei NUCLEAR STRUCTURE 23,24O, 24,25F, 25,26Ne, 138Ba, 208Pb; calculated neutron skin thickness, radii, neutron and proton density distributions, role of tensor coupling and pairing correlations. Relativistic mean field approach.
doi: 10.1103/PhysRevC.72.024313
2004AN06 Chin.Phys.Lett. 21, 895 (2004) Nuclear Fusion Induced by Coulomb-Hydrodynamic Explosion of Deuterium Clusters in Intense Laser Pulses
doi: 10.1088/0256-307X/21/5/037
2004MA07 J.Phys.(London) G30, 13 (2004) Y.G.Ma, D.D.Han, W.Q.Shen, X.Z.Cai, J.G.Chen, Z.J.He, J.L.Long, G.L.Ma, K.Wang, Y.B.Wei, L.P.Yu, H.Y.Zhang, C.Zhong, X.F.Zhou, Z.Y.Zhu Statistical nature of cluster emission in nuclear liquid-vapour phase coexistence NUCLEAR STRUCTURE 129Xe; calculated cluster emission probability from excited nucleus. Isospin-dependent lattice gas model.
doi: 10.1088/0954-3899/30/2/002
2004MA90 Phys.Lett. B 604, 170 (2004) Z.-Y.Ma, J.Rong, B.-Q.Chen, Z.-Y.Zhu, H.-Q.Song Isospin dependence of nucleon effective mass in Dirac Brueckner-Hartree-Fock approach
doi: 10.1016/j.physletb.2004.11.004
2004SH18 Prog.Theor.Phys.(Kyoto) 111, 721 (2004) S.Shen, J.Gu, W.Shen, Z.Xing, Z.Zhu On the Mechanism of Signature Inversion in the Doubly Odd Nuclei 80, 82Rb NUCLEAR STRUCTURE 80,82Rb; calculated levels, J, π, configurations, rotational bands; deduced signature inversion mechanism. Angular momentum projected shell model.
doi: 10.1143/PTP.111.721
2004WA09 Chin.Phys.Lett. 21, 453 (2004) T.-T.Wang, W.-Z.Jiang, W.Zhang, K.Wang, Z.-Y.Zhu Properties of the Alpha Decay Chain Nuclei of 310126, 292120 and 298114 NUCLEAR STRUCTURE 314128, 310126, 306124, 302122, 298120, 294og, 290Lv, 286Fl, 282Cn, 278Ds, 274Hs; calculated binding energies, radii, deformation parameters, Qα. 296122, 292120, 288Og, 284,302Lv, 280,298Fl, 276,294Cn, 272,290Ds, 268,286Hs, 264,282Sg, 260,278Rf, 256,274No, 270Fm, 266Cf; calculated binding energies, Qα. Comparison with previous results.
doi: 10.1088/0256-307X/21/3/010
2004WA20 Chin.Phys.Lett. 21, 1479 (2004) T.-T.Wang, W.-Z.Jiang, Z.-Y.Zhu, Y.-L.Zhao, W.Zhang, J.-G.Chen Occurrence of Superdeformation in Even-Even Isotopes of Zn NUCLEAR STRUCTURE 60,62,64,66,68,70Zn; calculated potential energy surfaces, pairing effects, superdeformation.
doi: 10.1088/0256-307X/21/8/018
2003JI09 Phys.Rev. C 68, 047301 (2003) Particle stability of highly and superdeformed states of Ni, Cu, and Zn isotopes near β stability in relativistic mean-field theory NUCLEAR STRUCTURE 55,57,59,61,63,65,66,67,68,69Ni, 57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73Cu, 59,61,63,65,67,69,71,73Zn; calculated deformation, superdeformed configurations, particle stability features. Relativistic mean-field approach.
doi: 10.1103/PhysRevC.68.047301
2002CA04 Phys.Rev. C65, 024610 (2002) X.Z.Cai, H.Y.Zhang, W.Q.Shen, Z.Z.Ren, J.Feng, D.Q.Fang, Z.Y.Zhu, W.Z.Jiang, Y.G.Ma, C.Zhong, W.L.Zhan, Z.Y.Guo, G.Q.Xiao, J.S.Wang, Y.T.Zhu, J.C.Wang, J.X.Li, M.Wang, J.F.Wang, Z.J.Ning, Q.J.Wang, Z.Q.Chen Existence of a Proton Halo in 23Al and Its Significance NUCLEAR REACTIONS 12C(19F, X), (20Ne, X), (21Na, X), (22Mg, X), (23Al, X), (24Al, X), (25Al, X), (26Al, X), (27Al, X), (28Al, X), E ≈ 20-35 MeV/nucleon; measured reaction σ. 23Al deduced proton halo. Comparison with model prediction.
doi: 10.1103/PhysRevC.65.024610
2002CA38 Chin.Phys.Lett. 19, 1068 (2002) X.-Z.Cai, W.-Q.Shen, Z.-Z.Ren, W.-Z.Jiang, D.-Q.Fang, H.-Y.Zhang, C.Zhong, Y.-B.Wei, W.Guo, Y.-G.Ma, Z.-Y.Zhu One-Proton Halo in 31Cl with Relativistic Mean-Field Theory NUCLEAR STRUCTURE 31,32Cl, 30,31S; calculated binding energies, radii, density distributions. 31Cl deduced proton halo. Relativistic mean-field theory.
doi: 10.1088/0256-307X/19/8/312
2002JI01 Phys.Rev. C65, 015210 (2002) W.Z.Jiang, X.J.Qiu, Z.Y.Zhu, Z.J.He Gluonic Contributions in a Four-Fermion Interaction Model
doi: 10.1103/PhysRevC.65.015210
2002ZH30 Nucl.Phys. A707, 303 (2002) H.Y.Zhang, W.Q.Shen, Z.Z.Ren, Y.G.Ma, W.Z.Jiang, Z.Y.Zhu, X.Z.Cai, D.Q.Fang, C.Zhong, L.P.Yu, Y.B.Wei, W.I.Zhan, Z.Y.Guo, G.Q.Xiao, J.S.Wang, J.C.Wang, Q.J.Wang, J.X.Li, M.Wang, Z.Q.Chen Measurement of Reaction Cross Section for Proton-Rich Nuclei (A < 30) at Intermediate Energies NUCLEAR REACTIONS C(12C, X), (13C, X), (14C, X), (13N, X), (14N, X), (15N, X), (16N, X), (17N, X), (15O, X), (16O, X), (17O, X), (18O, X), (19O, X), (17F, X), (18F, X), (19F, X), (20F, X), (21F, X), (19Ne, X), (20Ne, X), (21Ne, X), (22Ne, X), (21Na, X), (22Na, X), (23Na, X), (24Na, X), (22Mg, X), (23Mg, X), (24Mg, X), (25Mg, X), (26Mg, X), (23Al, X), (24Al, X), (25Al, X), (26Al, X), (27Al, X), (28Al, X), (26Si, X), (27Si, X), (28Si, X), (29Si, X), (27P, X), (28P, X), (29S, X), E=18-33 MeV; measured reaction σ. 17F, 23Al, 27P deduced radii, halo features. Secondary beams from 36Ar fragmentation. Comparison with model predictions.
doi: 10.1016/S0375-9474(02)01007-2
2002ZH49 Prog.Theor.Phys.(Kyoto), Suppl. 146, 33 (2002) H.-Y.Zhang, W.-Q.Shen, Z.-Z.Ren, Y.-G.Ma, X.-Z.Cai, D.-Q.Fang, Z.-Y.Zhu, W.-Z.Jiang, C.Zhong, L.-P.Yu, Y.-B.Wei, W.-L.Zhan, Z.-Y.Guo, G.-Q.Xiao, J.-S.Wang, J.-C.Wang, Q.-J.Wang, J.-X.Li, M.Wang, Z.-Q.Chen Possible Proton Halo and Skin in Light Proton-Rich Nucleus NUCLEAR REACTIONS C(15N, X), (17N, X), (16O, X), (18O, X), (17F, X), (19F, X), (21F, X), (20Ne, X), (22Ne, X), (21Na, X), (23Na, X), (22Mg, X), (24Mg, X), (23Al, X), (25Al, X), (26Si, X), (27P, X), E=30 MeV/nucleon; measured reaction σ. 17F deduced proton skin features. 23Al, 27P deduced proton halo features. Transmission method, Glauber model analysis, relativistic density-dependent Hartree calculations.
doi: 10.1143/PTPS.146.33
2001CA43 Chin.Phys.Lett. 18, 1189 (2001) X.-Z.Cai, W.-Q.Shen, J.Feng, D.-Q.Fang, Z.-Y.Zhu, W.-Z.Jiang, Y.-G.Ma, H.-Y.Zhang, C.Zhong, L.-P.Yu, W.-L.Zhan, Z.-Y.Guo, G.-Q.Xiao, J.-S.Wang, Y.-T.Zhu, J.-C.Wang, J.-X.Li, M.Wang, J.-F.Wang, Z.-J.Ning, Q-J.Wang, Z.-Q.Chen Total Reaction Cross Section Measurements at Intermediate Energy for the Proton Halo Candidate 23Al and Its Neighbours NUCLEAR REACTIONS C(19F, X), (20Ne, X), (21Na, X), (22Mg, X), (23Al, X), E ≈ 25-36 MeV/nucleon; measured reaction σ. 23Al deduced possible halo features. Secondary beams from 36Ar fragmentation.
doi: 10.1088/0256-307X/18/9/311
2001FA23 Eur.Phys.J. A 12, 335 (2001) D.Q.Fang, W.Q.Shen, J.Feng, X.Z.Cai, H.Y.Zhang, Y.G.Ma, C.Zhong, Z.Y.Zhu, W.Z.Jiang, W.L.Zhan, Z.Y.Guo, G.Q.Xiao, J.S.Wang, J.Q.Wang, J.X.Li, M.Wang, J.F.Wang, Z.J.Ning, Q.J.Wang, Z.Q.Chen Evidence for a Proton Halo in 27P Through Measurements of Reaction Cross-Sections at Intermediate Energies NUCLEAR REACTIONS 12C(19O, X), (20F, X), (21F, X), (19Ne, X), (20Ne, X), (21Ne, X), (22Ne, X), (23Na, X), (24Na, X), (23Mg, X), (25Mg, X), (26Mg, X), (24Al, X), (25Al, X), (26Al, X), (27Al, X), (28Al, X), (26Si, X), (27Si, X), (28Si, X), (29Si, X), (27P, X), (28P, X), (29S, X), E=30 MeV/nucleon; measured reaction σ following fragmentation of 36Ar primary beam. 27P deduced proton-halo characteristics, neutron, proton and matter radii. Comparison with Glauber model calculations.
doi: 10.1007/s100500170011
2001MB04 Chin.Phys.Lett. 18, 897 (2001) Y.-G.Ma, W.-Q.Shen, Z.-Y.Zhu, H.-Y.Zhang, L.-P.Yu, X.-Z.Cai, D.-Q.Fang, C.Zhong Poissonian Reducibility and Thermal Scaling in Nuclear Dissociation NUCLEAR STRUCTURE 129Xe; calculated fragments isotopic distributions vs temperature for dissociation of excited nucleus. Lattice gas model, Poissonian reducibility.
2001SH07 Acta Phys.Pol. B32, 183 (2001) S.Shen, Z.Wang, S.Shi, J.Gu, J.Liu, Z.Zhu Study of One-Quasiproton Bands of 129La using the Projected Shell Model NUCLEAR STRUCTURE 129La; calculated levels, J, π, rotational bands. Projected shell model, comparison with data.
2001WA38 Nucl.Phys. A691, 618 (2001) J.S.Wang, W.Q.Shen, Z.Y.Zhu, J.Feng, Z.Y.Guo, W.L.Zhan, G.Q.Xiao, X.Z.Cai, D.Q.Fang, H.Y.Zhang, Y.G.Ma RMF Calculation and Phenomenological Formulas for the rms Radii of Light Nuclei NUCLEAR STRUCTURE Z=3-16; A=6-40; calculated radii, binding energies. Relativistic mean field approach, comparisons with data.
doi: 10.1016/S0375-9474(01)00591-7
2000CH19 Phys.Rev. C61, 067601 (2000) L.-W.Chen, F.-S.Zhang, Z.-Y.Zhu Isospin Effects on Rotational Flow in Intermediate Energy Heavy Ion Collisions NUCLEAR REACTIONS 58Fe(58Fe, X), 58Ni(58Ni, X), E=40 MeV/nucleon; calculated in-plane rotational flow features; deduced isospin dependence. Quantum molecular dynamics model.
doi: 10.1103/PhysRevC.61.067601
2000SH49 Eur.Phys.J. A 9, 463 (2000) S.Shen, X.Yu, S.Shi, J.Gu, J.Liu, Y.Li, Z.Zhu Decay of 83Sr and Level Structure of 83Rb RADIOACTIVITY 83Sr(β+), (EC) [from 85Rb(p, 3n)]; measured Eγ, Iγ, γγ-coin. 83Rb deduced levels, J, π, branching ratios, log ft. Comparison with shell model calculations.
doi: 10.1007/s100500070004
2000ZH26 Prog.Theor.Phys.(Kyoto), Suppl. 138, 32 (2000) F.-S.Zhang, L.-W.Chen, Z.-Y.Ming, Z.-Y.Zhu A Novel Algorithm to the Transient State of Nuclear Matter with Isospin Asymmetry, Thermal Excitation, and Compression
doi: 10.1143/PTPS.138.32
2000ZH48 Eur.Phys.J. A 9, 149 (2000) F.-S.Zhang, L.-W.Chen, W.-F.Li, Z.-Y.Zhu Isospin Effects on Squeeze-Out Flow in Heavy-Ion Collisions NUCLEAR REACTIONS 124Sn(124Sn, X), 124Ba(124Ba, X), E=150-550 MeV/nucleon; calculated fragments squeeze-out flow angular distributions, related features; deduced isospin dependence. Isospin-dependent quantum molecular dynamics.
doi: 10.1007/s100500070029
1999CH22 Phys.Lett. 459B, 21 (1999) L.-W.Chen, F.-S.Zhang, G.-M.Jin, Z.-Y.Zhu Isospin Dependence of Radial Flow in Heavy-Ion Collisions at Intermediate Energies NUCLEAR REACTIONS 124Sn(124Sn, X), 124Ba(124Ba, X), E=100, 150, 200, 600 MeV/nucleon; calculated fragments mean kinetic energy vs charge, radial flow features; deduced isospin effects. Isospin-dependent QMD.
doi: 10.1016/S0370-2693(99)00628-0
1999JI07 Chin.Phys.Lett. 16, 879 (1999) W.-Z.Jiang, Z.-J.He, Z.-Y.Zhu, J-J.Zhang Dilepton Production in an Expanding Hot Baryon-Rich Quark-Gluon Matter NUCLEAR REACTIONS 197Au(197Au, X), E=0.7-200 GeV/nucleon; calculated initial values and time evolution of temperature and quark chemical potential, dilepton yield.
doi: 10.1088/0256-307X/16/12/008
1999ZH37 Phys.Rev. C60, 064604 (1999) F.-S.Zhang, L.-W.Chen, Z.-Y.Ming, Z.-Y.Zhu Isospin Dependence of Nuclear Multifragmentation in 112Sn + 112Sn and 124Sn + 124Sn Collisions at 40 MeV/nucleon NUCLEAR REACTIONS 112Sn(112Sn, X), 124Sn(124Sn, X), E=40 MeV/nucleon; calculated intermediate mass fragment, light charged particle yields, multiplicities; deduced isospin effect. Isospin-dependent quantum molecular dynamics. Comparisons with data.
doi: 10.1103/PhysRevC.60.064604
1997RE11 Chin.Phys.Lett. 14, 259 (1997) Z.-Z.Ren, Z.-Y.Zhu, Y.-H.Cai, Y.-S.Shen, W.-L.Zhan, G.-O.Xu Ground State Properties of Z = 114 Isotopes in the Relativistic Mean-Field Theory NUCLEAR STRUCTURE 298,296,294,292,290,288,286,284,282,280,278,276,274,272,270Fl; calculated binding energies, nucleon, matter radii, βp, βn ground-state deformations, two-neutron separation energies. 298Fl; calculated single-particle energies; deduced spherical shell at N=184. Shell model, relativistic mean-field theory.
1996JI08 Chin.Phys.Lett. 13, 416 (1996) W.-Z.Jiang, Z.-Y.Zhu, X.-J.Qiu Relativistic Density-Dependent Hartree Approach for Nuclear Matter in the Chiral-Symmetry-Breaking Model
doi: 10.1088/0256-307X/13/6/005
1996RE10 Phys.Lett. 380B, 241 (1996) Relativistic Mean-Field Study of Mg Isotopes NUCLEAR STRUCTURE 20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40Mg; calculated binding energy, nucleon matter radii, deformation, quadrupole moments.
doi: 10.1016/0370-2693(96)00462-5
1996RE13 J.Phys.(London) G22, 523 (1996) Z.Ren, B.Chen, Z.Ma, Z.Zhu, G.Xu One-Neutron Halos in 22N, 23O and 24F and Three-Neutron Halo in 26F NUCLEAR STRUCTURE 22N, 23O, 24,26F; calculated binding energy, neutron, proton, matter radii, density distributions, single particle energies. 22Ne, 23O, 26,24F deduced neutron halo characteristics. Nonlinear relativistic mean-field theory.
doi: 10.1088/0954-3899/22/4/013
1996RE19 Nucl.Phys. A605, 75 (1996) Relativistic Mean-Field Study of Exotic Carbon Nuclei NUCLEAR STRUCTURE 9,10,11,12,13,14,15,16,17,18,19,20,21,22C; calculated levels, J, π, binding energy, nucleon, charge, matter radii, nucleon deformation, isotope shifts, nucleon, matter density distributions in some cases. Relativistic mean-field approach.
doi: 10.1016/0375-9474(96)00186-8
1996RE24 J.Phys.(London) G22, 1793 (1996) Relativistic Mean-Field Study of Even-Even Nuclei Near Z = 108 and N = 162 RADIOACTIVITY Z=108-114; N=162-170; calculated α-decay energies. Z=106; Z=108; Z=110; Z=112; Z=114; calculated binding energy, nucleon radii, β2. Relativistic mean-field theory.
doi: 10.1088/0954-3899/22/12/010
1995MA05 Phys.Rev. C51, 1029 (1995) Collective Motion of Reverse-Reaction System in the Intermediate-Energy Domain Via the Quantum-Molecular-Dynamics Approach NUCLEAR REACTIONS 27Al(40Ar, X), E=36 MeV/nucleon; calculated target-like, mid-central, projectile-like rapidities azimuthal distributions, other aspects. Quantum molecular dynamics approach, collective rotation in collisions.
doi: 10.1103/PhysRevC.51.1029
1995ZH16 Z.Phys. A352, 119 (1995) Description of Isovector Giant Dipole Resonances in Relativistic Vlasov Equation at Small Amplitude Limit NUCLEAR STRUCTURE 16O, 40Ca, 90Zr, 208Pb; calculated isovector GDR centroid energies, nucleon correlated strenmgth distribution. Relativistic Vlasov equation, small amplitude limit.
doi: 10.1007/BF01298896
1995ZH24 Chin.Phys.Lett. 12, 144 (1995) Isovector Dipole Giant Resonances: A relativistic Vlasov equation approach NUCLEAR STRUCTURE 16O, 40Ca, 90Zr, 208Pb; calculated correlated, uncorrelated GDR centroid energies. Relativistic Vlasov equation approach.
1994CH32 J.Phys.(London) G20, 891 (1994) Equivalence between Stochastic Quantization of a Two-Dimensional BF-Type Topological Field Theory and Three-Dimensional Topological Quantum Field Theory for a Magnetic Monopole
doi: 10.1088/0954-3899/20/6/004
1994ZH12 Phys.Lett. 328B, 1 (1994) Z.Y.Zhu, W.Q.Shen, Y.H.Cai, Y.G.Ma Study of Halo Nuclei with Phenomenological Relativistic Mean Field Approach NUCLEAR STRUCTURE 11Li, 11Be; calculated rms radii, one-, two-neutron separation energies, density distribution. Halo nuclei, relativistic mean field approach.
doi: 10.1016/0370-2693(94)90418-9
1993FE02 Phys.Lett. 305B, 9 (1993) J.Feng, W.Q.Shen, Y.G.Ma, Z.Y.Zhu The Separation Energy Dependence of the Nuclear Reaction Cross Section NUCLEAR REACTIONS 12C(6He, X), (8He, X), (11Be, X), E not given; 12C(11Li, X), E ≤ 1 GeV/nucleon; 12C(12C, X), E ≤ 2 GeV/nucleon; 27Al(12C, X), E ≤ 400 MeV/nucleon; 64Cu(14N, X), E ≤ 1 GeV/nucleon; 40Ca(16O, X), E ≤ 10 MeV/nucleon; calculated reaction σ(E); deduced neutron separation energy role. Coulomb-modified Glauber model.
doi: 10.1016/0370-2693(93)91097-7
1993FU11 Chin.Phys.Lett. 10, 267 (1993) Nuclide 202Pt Properties Extrapolated from the Systematic Studies in Pt Chain NUCLEAR STRUCTURE 194,196,198,200,202Pt; calculated levels, deformation parameters. 184,186,188,190,192Pt; calculated deformation parameters. Interacting boson model.
doi: 10.1088/0256-307X/10/5/004
1993ZH18 Chin.J.Nucl.Phys. 15, No 1, 1 (1993) Effects of the Dirac Sea on Deformed Nuclei NUCLEAR STRUCTURE 20Ne, 24Mg; calculated binding energy per nucleon, charge radius, deformation parameters; deduced Dirac sea role. Relativistic quantum field theory, nuclear many-body problem, mean field approximation.
1992ZH36 Chin.J.Nucl.Phys. 14, No 4, 293 (1992) On the First 2+ State of New Nuclide 202Pt NUCLEAR STRUCTURE 184,186,188,190,192,194,196,198,200,202,204Pt; calculated 2+ level energy. Angular momentum projection, Nilsson model.
1991ZH05 Phys.Lett. 254B, 325 (1991) Vacuum Polarization in a Relativistic Description of Open Shell Nuclei NUCLEAR STRUCTURE 16O, 56Ni, 90Zr, 208Pb; calculated binding energy per particle, mass distribution, charge rms radii. 20Ne, 168Er; calculated binding energy per particle, n, p quadrupole moments, deformation. Shell model, relativistic description.
doi: 10.1016/0370-2693(91)91163-P
1987ZH13 Chin.J.Nucl.Phys. 9, 333 (1987) Analysis of n + 19F(t + 16O) Elastic Scattering with Three Cluster QRGM and CGCN NUCLEAR REACTIONS 19F(n, n), E=1.45, 14.1 MeV; calculated σ(θ). Quasi-resonance group method.
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