NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = W.J.Zhao Found 18 matches. 2023DA07 J.Phys.(London) G50, 045102 (2023) X.R.Dai, Y.Y.Wang, D.Li, W.J.Zhao, Y.F.Han, X.Y.Han, K.H.Fang Cross section measurements for 9Be(d, t)8Be reaction at the low-energy region (E ≤ 100 keV) NUCLEAR REACTIONS 9Be(d, t), E=78-100 keV; measured reaction products; deduced thick-target yields, σ and uncertainties. The low-energy, high-current accelerators at Research Center for Electron Photon Science in Tohoku University.
doi: 10.1088/1361-6471/acb507
2023MU17 Int.J.Mod.Phys. E32, 2350045 (2023) The empirical coupled-channel model with the new analytical penetration formula for fusion cross-sections NUCLEAR REACTIONS 16O, 208Pb(16O, X), 120Sn(6Li, X), 119Sn(7Li, X), E(cm)<20 MeV; calculated fusion σ using the empirical coupled-channel (ECC) model with the Hill-Wheeler (HW) formula based on the parabolic approximation.
doi: 10.1142/S0218301323500453
2022YA22 Eur.Phys.J. A 58, 157 (2022) Investigation of dynamic effects on fusion cross sections for reactions 16, 18O + 112, 116, 118, 124Sn NUCLEAR REACTIONS 112,116,118,124Sn(16O, X), (18O, X), E(cm)<65 MeV; analyzed available data; calculated fusion σ using the empirical coupled-channel (ECC) model.
doi: 10.1140/epja/s10050-022-00814-7
2021LV03 Phys.Rev. C 103, 064616 (2021) X.-J.Lv, Z.-Y.Yue, W.-J.Zhao, B.Wang Theoretical study of evaporation-residue cross sections of superheavy nuclei NUCLEAR REACTIONS 208Pb, 209Bi(48Ca, xn), E(cm)=160-200 MeV; 208Pb, 209Bi(50Ti, xn), E(cm)=170-210 MeV; 208Pb, 209Bi(54Cr, xn), E(cm)=190-230 MeV; 208Pb, 209Bi(58Fe, xn), E(cm)=210-240 MeV; 208Pb, 209Bi(64Ni, xn), E(cm)=230-250 MeV; 208Pb, 209Bi(70Zn, xn), E(cm)=250-270 MeV; 238U, 237Np, 244Pu, 243Am, 245,248Cm, 249Bk, 249Cf(48Ca, xn), E(cm)=180-260 MeV; 249Cf(45Sc, xn), 249Bk(50Ti, xn), 248Cm(51V, xn), E(cm)=200-260 MeV; 243Am, 248Cm(54Cr, xn), E(cm)=220-290 MeV; 249,251Cf(50Ti, xn), E(cm)=200-270 MeV; 249Bk(51V, xn), E(cm)=220-270 MeV; calculated evaporation-residue cross sections at energies near and above the Coulomb barrier by combining an empirical coupled-channel model, an analytical formula for describing the fusion probability, and a statistical model. Comparison with experimental data.
doi: 10.1103/PhysRevC.103.064616
2021WA20 Phys.Rev. C 103, 034605 (2021) Theoretical study of evaporation-residue cross sections for fusion reactions at energies near the Coulomb barrier NUCLEAR REACTIONS 209Bi(6Li, xn), (7Li, xn), E(cm)=20-55 MeV; 169Tm, 181Ta(9Be, xn), E(cm)=25-55 MeV; 186W, 187Re(9Be, xn), E(cm)=30-60 MeV; 208Pb(9Be, xn), E(cm)=30-80 MeV; 209Bi(9Be, xn), E(cm)=30-70 MeV; 89Y(12C, xn), E(cm)=25-70 MeV; 152Sm(12C, xn), E(cm)=40-80 MeV; 159Tb(12C, xn), E(cm)=40-90 MeV; 194,198Pt(12C, xn), E(cm)=50-90 MeV; 197Au, 205Tl, 208Pb(12C, xn), E(cm)=50-100 MeV; 246Cm(12C, xn), E(cm)=40-125 MeV; 169Tm(13C, xn), E(cm)=40-100 MeV; 207Pb(13C, xn), E(cm)=50-100 MeV; 246Cm(13C, xn), E(cm)=40-125 MeV; 134Ba(16O, xn), E(cm)=50-120 MeV; 148,150Nd(16O, xn), E(cm)=50-90 MeV; 165Ho(16O, xn), E(cm)=50-120 MeV; 197Au(16O, xn), E(cm)=65-120 MeV; 208Pb(16O, xn), E(cm)=60-110 MeV; 238U(16O, xn), E(cm)=60-120 MeV; 148Nd(18O, xn), E(cm)=50-90 MeV; 197Au(18O, xn), E(cm)=60-120 MeV; 181Ta(19F, xn), E(cm)=65-120 MeV; 188,192Os(19F, xn), E(cm)=70-110 MeV; 150Nd(22Ne, xn), E(cm)=60-170 MeV; 194,196,198Pt(22Ne, xn), E(cm)=80-170 MeV; 164Dy(40Ar, xn), E(cm)=120-220 MeV; 165Ho(40Ar, xn), E(cm)=120-180 MeV; 169Tm, 174Yb(40Ar, xn), E(cm)=120-200 MeV; 170Er(30Si, xn), E(cm)=100-150 MeV; 122Sn(48Ti, xn), E(cm)=110-180 MeV; analyzed experimental data for evaporation-residue σ(E) of fission-fusion reactions at energies near the Coulomb barrier using an empirical coupled-channel model, and a statistical model.
doi: 10.1103/PhysRevC.103.034605
2021YA27 Phys.Rev. C 104, 034607 (2021) J.-M.Yang, Z.-W.Song, W.-J.Zhao, B.Wang Theoretical study of dynamic effects on fusion cross sections for reactions 32, 34, 36S + 204, 206, 208Pb NUCLEAR REACTIONS 204,206,208Pb(32S, X), (34S, X), (36S, X), E(cm)=130-190 MeV; calculated fusion σ(E), universal fusion functions (UFF) using an empirical coupled-channel (ECC) model to analyze the dynamic effects. Comparison with experimental data.
doi: 10.1103/PhysRevC.104.034607
2018CH21 Chin.Phys.C 42, 054101 (2018) Q.-Z.Chai, W.-J.Zhao, M.-L.Liu, H.-L.Wang Calculation of multidimensional potential energy surfaces for even-even transuranium nuclei: systematic investigation of the triaxiality effect on the fission barrier NUCLEAR STRUCTURE 236,238,240,242,244,246Pu, 242,244,246,248,250Cm, 250,252Cf, 254Rf; calculated proton and neutron single-particle levels, two-dimensional potential energy surfaces, microscopic energy, deformation parameters. Comparison with available data.
doi: 10.1088/1674-1137/42/5/054101
2018CH39 Int.J.Mod.Phys. E27, 1850050 (2018) Similar alignment based on total-Routhian-surface approach in an α-decay chain from 216Po to 272Cn NUCLEAR STRUCTURE 272Cn, 268Ds, 264Hs, 260Sg, 256Rf, 252No, 248Fm, 244Cf, 240Cm, 236Pu, 232U, 228Th, 224Ra, 220Rn, 216Po; calculated angular momentum as a function of the rotational frequency for α-decay chain nuclei, single-particle energies using total Routhian surface approach in multidimensional deformation space.
doi: 10.1142/S0218301318500507
2018WA16 Phys.Rev. C 98, 014615 (2018) B.Wang, W.-J.Zhao, E.-G.Zhao, S.-G.Zhou Theoretical study of the capture of stable 39K and neutron-rich radioactive 46K by 181Ta NUCLEAR REACTIONS 181Ta(39K, X), E=180-210 MeV; 181Ta(46K, X), E=190-215 MeV; calculated capture σ(E) using empirical coupled-channel (ECC) model and the universal fusion function (UFF) prescription; deduced barrier parameters, and fusion functions. Comparison with experimental data.
doi: 10.1103/PhysRevC.98.014615
2017WA02 At.Data Nucl.Data Tables 114, 281 (2017) B.Wang, K.Wen, W.-J.Zhao, E.-G.Zhao, S.-G.Zhou Systematics of capture and fusion dynamics in heavy-ion collisions NUCLEAR REACTIONS 89Y(12C, X), 59Co(14N, X), E(cm)<100 MeV; calculated capture excitation functions by using an empirical coupled-channel (ECC) model for 182<ZpZt<1640. Comparison with available data.
doi: 10.1016/j.adt.2016.06.003
2016WA04 Phys.Rev. C 93, 014615 (2016) B.Wang, W.-J.Zhao, A.Diaz-Torres, E.-G.Zhao, S.-G.Zhou Systematic study of suppression of complete fusion in reactions involving weakly bound nuclei at energies above the Coulomb barrier NUCLEAR REACTIONS 89Y, 124Sn, 144Sm, 169Tm, 181Ta, 187Re, 208Pb, 209Bi(9Be, X), E(cm)=10-55 MeV; 90,96Zr, 154Sm, 159Tb, 197Au, 198Pt, 208Pb, 209Bi(6Li, X), E=10-55 MeV; 159Tb, 165Ho, 197Au, 198Pt, 209Bi(7Li, X), E=10-60 MeV; 159Tb, 209Bi(10B, X), (11B, X), E(cm)=30-80 MeV; calculated complete fusion σ(E). Empirical coupled-channel model with and without breakup effects. Comparison with experimental data.
doi: 10.1103/PhysRevC.93.014615
2014WA36 Phys.Rev. C 90, 034612 (2014) B.Wang, W.-J.Zhao, P.R.S.Gomes, E.-G.Zhao, S.-G.Zhou Systematic study of breakup effects on complete fusion at energies above the Coulomb barrier NUCLEAR REACTIONS 90Zr(6Li, X), E not given; 165Ho, 208Pb(7Li, X), E not given; 144,152Sm, 159Tb, 197Au, 198Pt, 209Bi(6Li, X), (7Li, X), E not given; 89Y, 144Sm, 124Sn, 186W, 208Pb, 209Bi(9Be, X), E not given; 159Tb, 209Bi(10B, X), E not given; 159Tb, 209Bi(11B, X), E not given; 89Y, 152Sm, 159Tb, 181Ta, 208Pb(12C, X), E not given; 159Tb, 181Ta, 207Pb(13C, X), E not given; 103Rh, 148,150Nd, 159Tb, 169Tm(16O, X), E not given; calculated dimensionless complete fusion (CF) functions. Discussed systematics of suppression factors. Comparison with universal fusion functions, and available experimental values. Proposed an analytical formula between the CF suppression factor and the breakup threshold energy.
doi: 10.1103/PhysRevC.90.034612
2011LI18 Chin.Phys.Lett. 28, 052102 (2011) E.-T.Li, Z.-H.Li, J.Su, B.Guo, Y.-J.Li, S.-Q.Yan, X.-X.Bai, Y.-B.Wang, B.-X.Wang, G.Lian, S.Zeng, X.Fang, W.-J.Zhao, W.-P.Liu Astrophysical Rates for the 6He(p, γ)7Li Reaction NUCLEAR REACTIONS 1H(6He, γ), 2H(6He, n), E(cm)=9.1 MeV; measured reaction products; deduced σ(θ), S-factors, temperature-dependent reaction rates. Comparison with DWBA analysis, REACLIB library.
doi: 10.1088/0256-307X/
2010WA02 Chin.Phys.Lett. 27, 022301 (2010) H.-L.Wang, L.-T.Song, W.-J.Zhao, Z.-X.Liu, Y.-H.Zhang, X.-H.Zhou, Y.-X.Guo, X.-G.Lei Observation of a Possible New Isomer in 175Ir RADIOACTIVITY 175,176Ir(EC) [from 146Nd(35Cl, X), E=210 MeV/nucleon]; measured reaction products, x-rays, Eγ, Iγ; deduced decay constants, T1/2, long-lived isomeric state in 175Ir.
doi: 10.1088/0256-307X/27/2/022301
2010ZH41 Chin.Phys.C 34, 1609 (2010) W.-J.Zhao, Y.-Q.Zhang, H.-L.Wang, L.-T.Song, L.-L.Li Production cross sections of the superheavy nucleus 117 based on the dinuclear system model NUCLEAR REACTIONS 248Cm(45Sc, X2n), (45Sc, X3n), (45Sc, X4n), 244Pu(51V, X2n), (51V, X3n), (51V, X4n), 238U(55Mn, X2n), (55Mn, X3n), (55Mn, X4n), 232Th(59Co, X2n), (59Co, X3n), (59Co, X4n), E<60 MeV/nucleon; 209Bi(82Se, X2n), (82Se, X3n), (82Se, X4n)289Ts/290Ts, 247Bk(48Ca, X2n), (48Ca, X3n), (48Ca, X4n)291Ts/292Ts/293Ts, E<60 MeV/nucleon; calculated production σ for 2n-4n evaporation channels for superheavy nuclei. Dinuclear system model.
doi: 10.1088/1674-1137/34/10/011
2009LI27 Chin.Phys.Lett. 26, 072401 (2009) E.-T.Li, Z.-H.Li, Y.-J.Li, S.-Q.Yan, X.-X.Bai, B.Guo, J.Su, Y.-B.Wang, B.-X.Wang, G.Lian, S.Zeng, X.Fang, W.-J.Zhao, W.-P.Liu Angular Distribution of the 12C(6He, 7Li)11B Reaction NUCLEAR REACTIONS 12C(6He, 7Li), E = 34.6 MeV; measured σ(θ). comparison with DWBA calculation.
doi: 10.1088/0256-307X/26/7/072401
2008LI03 Chin.Phys.Lett. 25, 455 (2008) Y.-J.Li, Z.-H.Li, B.Guo, Y.-B.Wang, X.-X.Bai, J.Su, G.Lian, S.Zeng, B.-X.Wang, X.Qin, C.Jiang, W.-P.Liu, W.-J.Zhao Measurement of Angular Distribution for the 8Li(p, d)7Li Reaction NUCLEAR REACTIONS 1H(8Li, 7Li), E=39.8 MeV; measured particle energies and yields. 8Li(p, d), E(cm)=4.0 MeV; deduced cross sections and backward anglular distributions.
doi: 10.1088/0256-307X/25/2/028
1993HO06 Phys.Rev. C47, 1672 (1993) Interference Effect of Doorway States in a Radiative Capture Reaction NUCLEAR REACTIONS 12C(p, γ), E ≈ 8-38 MeV; 12C(n, γ), E ≈ 8-20 MeV; analyzed σ(θ) vs E; deduced parameters. 13C, 13N deduced GDR, resonance parameters. Unified formalism.
doi: 10.1103/PhysRevC.47.1672
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