NSR Query Results
Output year order : Descending NSR database version of May 10, 2024. Search: Author = Tian Ye Found 39 matches. 2024SA20 Phys.Rev.Lett. 132, 162501 (2024) S.N.Santiesteban, S.Li, D.Abrams, S.Alsalmi, D.Androic, K.Aniol, J.Arrington, T.Averett, C.Ayerbe Gayoso, J.Bane, S.Barcus, J.Barrow, A.Beck, V.Bellini, H.Bhatt, D.Bhetuwal, D.Biswas, A.Camsonne, J.Castellanos, J.Chen, J.-P.Chen, D.Chrisman, M.E.Christy, C.Clarke, S.Covrig, R.Cruz-Torres, D.Day, D.Dutta, E.Fuchey, C.Gal, F.Garibaldi, T.N.Gautam, T.Gogami, J.Gomez, P.Gueye, T.J.Hague, J.O.Hansen, F.Hauenstein, W.Henry, D.W.Higinbotham, R.J.Holt, C.Hyde, K.Itabashi, M.Kaneta, A.Karki, A.T.Katramatou, C.E.Keppel, P.M.King, L.Kurbany, T.Kutz, N.Lashley-Colthirst, W.B.Li, H.Liu, N.Liyanage, E.Long, A.Lovato, J.Mammei, P.Markowitz, R.E.McClellan, F.Meddi, D.Meekins, R.Michaels, M.Mihovilovic, A.Moyer, S.Nagao, D.Nguyen, M.Nycz, M.Olson, L.Ou, V.Owen, C.Palatchi, B.Pandey, A.Papadopoulou, S.Park, T.Petkovic, S.Premathilake, V.Punjabi, R.D.Ransome, P.E.Reimer, J.Reinhold, S.Riordan, N.Rocco, V.M.Rodriguez, A.Schmidt, B.Schmookler, E.P.Segarra, A.Shahinyan, S.Sirca, K.Slifer, P.Solvignon, T.Su, R.Suleiman, L.Tang, Y.Tian, W.Tireman, F.Tortorici, Y.Toyama, K.Uehara, G.M.Urciuoli, D.Votaw, J.Williamson, B.Wojtsekhowski, S.Wood, Z.H.Ye, J.Zhang, X.Zheng Novel Measurement of the Neutron Magnetic Form Factor from A=3 Mirror Nuclei NUCLEAR REACTIONS 3H, 3He(e-, e-), E=2.222, 4.323 GeV; measured reaction products; deduced σ(θ, E), the neutron magnetic form factor using quasielastic scattering from the mirror nuclei. Comparison with available data. Hall A at Jefferson Lab (JLab).
doi: 10.1103/PhysRevLett.132.162501
2023CH23 Phys.Rev. C 107, 054306 (2023) J.Chen, M.Liu, C.Yuan, S.Chen, N.Shimizu, X.Sun, R.Xu, Y.Tian Shell-model-based investigation on level density of Xe and Ba isotopes NUCLEAR STRUCTURE 131,132,133,134Sn, 132,133,134,135Sb, 133,134,135,136Te, 134,135,136,137I, 135,136,137,138Xe, 136,137,138,139Cs, 137,138,139,140Ba; calculated one-neutron separation energy S(n). 132,133,134Sn, 132,133,134,135Sb, 134,135,136Te, 135,136,137I, 136,137,138Xe, 137,138,139Cs, 138,139,140Ba; calculated two-neutron separation energies S(2n). 134, ,136,138Xe, 134,136,138,140Ba, 128,129,130,134,135,136Sn, 131,135Sb, 132,134,136Te, 133,135,137I, 135,137,139Cs, 139La; calculated levels, J, π. 133,134,135,136,137Xe, 134,135,136,137,138,139Ba; calculated nuclear level densities (NLD), cumulative number of levels spin distributions. 134Te, 135I, 136Xe, 137Cs, 138Ba, 139La; calculated effective single particle energy for proton and neutron orbits with and without the consideration of tensor part in two-body matrix elements. 133,134,135,136,137Xe; calculated spin distribution , parity ratios, spin cut-off parameter. Configuration-interaction shell model with a unified effective nuclear force. Comparison to experimental data.
doi: 10.1103/PhysRevC.107.054306
2023TI01 Phys.Rev. C 107, 015201 (2023) Y.Tian, for the CLAS Collaboration Exclusive π- electroproduction off the neutron in deuterium in the resonance region NUCLEAR REACTIONS 2H(e, e'pπ-), E=2.039 GeV; measured reaction products; deduced σ(θ), kinematically defined final-state-interaction contribution factor, exclusive structure functions, Legendre moments of the exclusive structure functions. CEBAF Large Acceptance Spectrometer (CLAS) detector at JLAB.
doi: 10.1103/PhysRevC.107.015201
2022SU03 Prog.Theor.Exp.Phys. 2022, 013D01 (2022) K.N.Suzuki, T.Gogami, B.Pandey, K.Itabashi, S.Nagao, K.Okuyama, S.N.Nakamura, L.Tang, D.Abrams, T.Akiyama, D.Androic, K.Aniol, C.Ayerbe Gayoso, J.Bane, S.Barcus, J.Barrow, V.Bellini, H.Bhatt, D.Bhetuwal, D.Biswas, A.Camsonne, J.Castellanos, J.-P.Chen, J.Chen, S.Covrig, D.Chrisman, R.Cruz-Torres, R.Das, E.Fuchey, K.Gnanvo, F.Garibaldi, T.Gautam, J.Gomez, P.Gueye, T.J.Hague, O.Hansen, W.Henry, F.Hauenstein, D.W.Higinbotham, C.E.Hyde, M.Kaneta, C.Keppel, T.Kutz, N.Lashley-Colthirst, S.Li, H.Liu, J.Mammei, P.Markowitz, R.E.McClellan, F.Meddi, D.Meekins, R.Michaels, M.Mihovilovic, A.Moyer, D.Nguyen, M.Nycz, V.Owen, C.Palatchi, S.Park, T.Petkovic, S.Premathilake, P.E.Reimer, J.Reinhold, S.Riordan, V.Rodriguez, C.Samanta, S.N.Santiesteban, B.Sawatzky, S.Sirca, K.Slifer, T.Su, Y.Tian, Y.Toyama, K.Uehara, G.M.Urciuoli, D.Votaw, J.Williamson, B.Wojtsekhowski, S.A.Wood, B.Yale, Z.Ye, J.Zhang, X.Zheng The cross-section measurement for the 3H(e, e'K+)nnΛ reaction NUCLEAR REACTIONS 3H(e-, e-'K+), E not given; measured reaction products; deduced σ(θ), missing mass. Comparison with Monte Carlo simulations.
doi: 10.1093/ptep/ptab158
2022TI01 Nucl.Instrum.Methods Phys.Res. A1026, 166151 (2022) Yu.E.Titarenko, V.F.Batyaev, K.V.Pavlov, A.Yu.Titarenko, S.V.Malinovskiy, V.I.Rogov, V.M.Zhivun, T.V.Kulevoy, M.V.Chauzova, R.S.Khalikov, A.V.Ignatyuk, V.Yu.Blandinskiy, A.A.Kovalishin, M.I.Baznat, A.Yu.Stankovskiy, A.I.Dubrouski, H.I.Kiyavitskaya, T.Xue, Y.Tian, M.Zeng, Z.Zeng, O.Normahmedov, T.Sato 206, 207, 208, natPb(p, x)194Hg and 209Bi(p, x)194Hg excitation functions in the energy range 0.04-2.6 GeV NUCLEAR REACTIONS Pb, 209Bi(p, X)194Hg, E=0.04-2.6 GeV; measured reaction products, Eγ, Iγ; deduced production σ. Comparison with theoretical calculations.
doi: 10.1016/j.nima.2021.166151
2021HU18 Chin.Phys.C 45, 044001 (2021) W.Hua, Z.Zhang, L.Ma, Z.Gan, H.Yang, C.Yuan, M.Huang, C.Yang, M.Zhang, Y.Tian, X.Zhou Fine structure of α decay in 222Pa RADIOACTIVITY 222Pa, 218Ac, 214Fr(α) [from 186W(40Ar, X)222Pa, E=198.7 MeV]; measured decay products, Eα, Iα; deduced Q-values, T1/2. Comparison with available data.
doi: 10.1088/1674-1137/abdea8
2021HU19 Chin.Phys.C 45, 044003 (2021) W.Hua, Z.Zhang, L.Ma, Z.Gan, H.Yang, M.Huang, C.Yang, M.Zhang, Y.Tian, X.Zhou, C.Yuan, C.Shen, L.Zhu α-decay study of 218Ac and 221Th in 40Ar+186W reaction RADIOACTIVITY 218Ac, 221Th, 217Ra, 213Rn(α) [from 186W(40Ar, X)221Th/218Ac, E=198.7 MeV]; measured decay products, Eα, Iα; deduced Q-values, T1/2. Comparison with available data.
doi: 10.1088/1674-1137/abe0bd
2020KA09 Nucl.Data Sheets 163, 109 (2020) T.Kawano, Y.S.Cho, P.Dimitriou, D.Filipescu, N.Iwamoto, V.Plujko, X.Tao, H.Utsunomiya, V.Varlamov, R.Xu, R.Capote, I.Gheorghe, O.Gorbachenko, Y.L.Jin, T.Renstrom, M.Sin, K.Stopani, Y.Tian, G.M.Tveten, J.M.Wang, T.Belgya, R.Firestone, S.Goriely, J.Kopecky, M.Krticka, R.Schwengner, S.Siem, M.Wiedeking IAEA Photonuclear Data Library 2019
doi: 10.1016/j.nds.2019.12.002
2020SU07 Phys.Rev. C 101, 034302 (2020) X.Sun, R.Xu, Y.Tian, Z.Ma, Z.Zhang, Z.Ge, H.Zhang, E.N.E.van Dalen, H.Muther Relativistic mean-field approach in nuclear systems NUCLEAR STRUCTURE 16O, 40,48Ca, 90Zr, 116,132Sn, 208Pb; calculated binding energy per nucleon, charge radii, charge density distribution, single particle energies, spin-orbit splitting in 16O, scalar and vector potentials for neutrons and protons as a function of isospin asymmetry using both local density approximation (LDA) and improved LDA, based on Dirac-Brueckner-Hartree-Fock (DBHF) approach starting from a realistic nucleon-nucleon interaction. Comparison with experimental data.
doi: 10.1103/PhysRevC.101.034302
2020TI03 Nucl.Instrum.Methods Phys.Res. A984, 164635 (2020) Y.E.Titarenko, V.F.Batyaev, K.V.Pavlov, A.Y.Titarenko, S.V.Malinovskiy, V.I.Rogov, V.M.Zhivun, T.V.Kulevoy, M.V.Chauzova, S.V.Lushin, A.S.Busygin, A.V.Ignatyuk, P.N.Alekseev, V.Y.Blandinskiy, A.A.Kovalishin, S.I.Tyutyunnikov, A.A.Baldin, A.N.Sosnin, M.I.Baznat, A.Y.Stankovskiy, A.I.Dubrouski, H.I.Kiyavitskaya, T.Xue, Y.Tian, M.Zeng, Z.Zeng, T.Sato 208, 207, 206, natPb(p, x)207Bi and 209Bi (p, x)207Bi excitation functions in the energy range of 0.04 - 2.6 GeV NUCLEAR REACTIONS 206,207,208Pb, Pb, 209Bi(p, X)207Bi, E=0.04-2.6 GeV; measured reaction products, Eγ, Iγ; deduced σ and uncertainties. Comparison with MCNP-6.1, PHITS, Geant4 and TENDL-2019 calculations.
doi: 10.1016/j.nima.2020.164635
2020WU05 Phys.Lett. B 805, 135431 (2020) D.Wu, N.Y.Wang, B.Guo, C.Y.He, Y.Tian, X.Tao, T.L.Ma, F.L.Liu, W.S.Yang, J.H.Wei, Y.P.Shen, S.L.Guo, Q.W.Fan, X.G.Wu, Y.Zheng, T.X.Li, Z.Q.Wang, H.L.Luo, Y.N.Liu, M.L.Qiu New measurement of the 74Ge(p, γ)75As reaction cross sections in the p-process nucleosynthesis NUCLEAR REACTIONS 74Ge(p, γ), E(cm)=1-4.5 MeV; measured reaction products, Eγ, Iγ; deduced σ, reaction rates. Comparison with EMPIRE and TALYS nuclear model codes calculations.
doi: 10.1016/j.physletb.2020.135431
2019TI10 Chin.Phys.C 43, 114102 (2019) Y.Tian, X.Tao, J.Wang, X.Ke, R.Xu, Z.Ge Giant dipole resonance parameters from photoabsorption cross-sections NUCLEAR STRUCTURE 34S, 40Ar, 40,42,44,46,48Ca, 48Ti, 51V, 52Cr, 90,91,92,94Zr, 112,114,116,117,118,119,120,122,124Sn, 138Ba, 208Pb, 209Bi, 23Na, 24,25Mg, 27Al, 28,29Si, 63,65Cu, 80Se, 127I, 133Cs, 159Tb, 181Ta, 182,184,186W, 186,188,189,190,192Os, 235U; analyzed available data; deduced systematic GDR parameters.
doi: 10.1088/1674-1137/43/11/114102
2019ZH39 Nucl.Phys. A990, 1 (2019) Z.Zhang, R.R.Xu, Z.Y.Ma, Z.G.Ge, Y.Tian, D.Y.Pang, X.D.Sun, Y.L.Jin, X.Tao, Y.Zhang, J.M.Wang Global α-nucleus optical model based on an Dirac Brueckner Hartree Fock approach
doi: 10.1016/j.nuclphysa.2019.06.013
2018TI06 Phys.Rev. C 97, 064615 (2018) Effects of nonlocality of nuclear potentials on direct capture reactions NUCLEAR REACTIONS 48Ca(n, γ), E=0.01-0.4 MeV; 7Li(n, γ), E=0.01-2 MeV; 12C(p, γ), E=0-1.2 MeV; calculated local and non-local potential parameters, s-wave phase shifts of target nuclides as function of incident energy, and σ(E) with the Perey-Buck-type nonlocal potentials using a potential model; deduced effects of potential nonlocality in direct radiative capture reactions. Comparison with experimental values.
doi: 10.1103/PhysRevC.97.064615
2016XU07 Phys.Rev. C 94, 034606 (2016) R.Xu, Z.Ma, Y.Zhang, Y.Tian, E.N.E.van Dalen, H.Muther Global analysis of isospin dependent microscopic nucleon-nucleus optical potentials in a Dirac-Brueckner-Hartree-Fock approach NUCLEAR REACTIONS 40Ca(n, n), E=2.06-185.0 MeV; 208Pb(n, n), E=1.8-155.0 MeV; 12C(n, n), E=1.04-225.0 MeV; 56Fe(n, n), E=1.8-75.0 MeV; 98Mo(n, n), E=1.5-26.0 MeV; 103Rh(n, n), E=4.51-10.0 MeV; 28Si, 90Zr, 120Sn(n, n), E=65 MeV; 27Al(n, n), E=3.2-26.0 MeV; 40Ca, 56Fe(p, p), E=61.5, 65 MeV; 28Si(p, p), E=14.26-250.0 MeV; 58Ni(p, p), E=7.0-250.0 MeV; 90Zr(p, p), E=9.7-185.0 MeV; 208Pb(p, p), E=16.0-201.0 MeV; calculated σ(θ, E). 12C, 40Ca(polarized n, n), E=10.9 MeV; 58Ni(polarized n, n), E=9.92 MeV; 208Pb(polarized n, n), E=9.97 MeV; 56Fe(polarized p, p), E=16.0-65.0 MeV; 58Ni(polarized p, p), E=16.0-250.0 MeV; 208Pb(polarized p, p), E=80, 200 MeV; calculated analyzing powers Ay(θ, E). 12C, 56Fe, 208Pb(n, X), 40Ca, 120Sn, 208Pb(p, X), E<200 MeV; calculated reaction σ(E). Global analysis of the isospin dependent nucleon-nucleus microscopic optical potential (MOP) based on the DBHF calculation in symmetric and asymmetric nuclear matter; deduced relativistic MOP for nucleon-nucleus scattering. Comparisons with experimental data, and with results from phenomenological Koning-Delaroche global potential. Compiled bibliographic information for experimental (n, n) data for 12C, 14N, 16O, 23Na, 24Mg, 27Al, 28Si, 31P, 32S, 39K, 40Ca, 48Ti, 52Cr, 55Mn, 56Fe, 59Co, 58Ni, 63Cu, 80Se, 88Sr, 89Y, 90Zr, 93Nb, 98Mo, 103Rh, 115In, 120Sn, 197Au, 208Pb, 209Bi targets, and experimental (p, p) data for 12C, 27Al, 28Si, 40Ca, 56Fe, 58Ni, 90Zr, 120Sn, 208Pb targets.
doi: 10.1103/PhysRevC.94.034606
2016ZH33 Yuan.Wul.Ping. 33, 217 (2016); Nucl.Phys.Rev. 33, 217 (2016) Z.Zhang, Z.Gan, L.Ma, H.Yang, J.Wang, L.Yu, J.Jiang, Y.Tian, B.Ding, S.Guo, Y.Wang, T.Huang, M.Sun, K.Wang Alpha Decay of the Neutron-deficient Isotopes 215, 216U RADIOACTIVITY 215,216U(α) [from 180W(40Ar, xn), E=189.5, 204.5, 207.6 MeV]; measured decay products, Eα, Iα; deduced energy levels, J, π, T1/2. Comparison with systematics.
doi: 10.11804/NuclPhysRev.33.02.217
2013TI03 Phys.Rev. C 87, 057305 (2013) Systematics of nuclear ground-state properties of Sr isotopes by covariant density functional theory NUCLEAR STRUCTURE 82,83,84,85,86,87,88,89,90,91,92,93,94,95,96,97,98,99,100,101,102,103,104Sr; calculated rms charge radii, S(2n), three-point neutron pairing energies of ground states. Density functional theory with parameter set DD-PC1. Comparison with experimental data.
doi: 10.1103/PhysRevC.87.057305
2010MA35 Nucl.Phys. A834, 50c (2010) Density functional theory with a separable pairing force in finite nuclei NUCLEAR STRUCTURE 102,104,106,108,110,112,114,116,118,120,122,124,126,128,130,132,134,136Sn; calculated E2, B(E2), pairing gap using separable and Gogny D1S forces. 128,130,132,134,136,138,140,142,144,146,148,150,152,154,156,158,160,162,164,166,168,170,172,174,176,178,180,182,184,186,188Sm; calculated deformation using RMF+BCS, HFB, RHB (relativistic Hartree-Bogoliubov). Comparison with data.
doi: 10.1016/j.nuclphysa.2010.01.015
2010NI06 Phys.Rev. C 81, 054318 (2010) T.Niksic, P.Ring, D.Vretenar, Y.Tian, Z.-y.Ma 3D relativistic Hartree-Bogoliubov model with a separable pairing interaction: Triaxial ground-state shapes NUCLEAR STRUCTURE 134,136,138,140,142,144,146,148,150,152,154,156Sm, 190,192,194,196,198,200Pt; calculated triaxial quadrupole binding-energy contour maps, neutron and proton pairing energy maps in β-γ plane, quadrupole deformations. 192Pt; calculated proton and neutron canonical single-particle energy levels. Relativistic Hartree-Bogoliubov (RHB) model.
doi: 10.1103/PhysRevC.81.054318
2010YA20 Phys.Rev. C 82, 054305 (2010) D.Yang, L.-G.Cao, Y.Tian, Z.-Y.Ma Importance of self-consistency in relativistic continuum random-phase approximation calculations NUCLEAR STRUCTURE 40Ca, 132Sn, 208Pb; calculated inverse energy-weighted moments and strength distributions of isoscalar giant-monopole resonances (ISGMR), isovector giant-monopole resonances (IVGMR), isoscalar giant-quadrupole resonances (ISGQR), isovector giant-quadrupole resonances (IVGQR) using relativistic continuum random phase approximation (RCRPA) method.
doi: 10.1103/PhysRevC.82.054305
2010ZO02 Chin.Phys.C 34, 56 (2010) W.-H.Zou, Y.Tian, S.-F.Shen, J.-Z.Gu, B.-B.Peng, D.-D.Zhang, Z.-Y.Ma Nuclear structure around 80Zr NUCLEAR STRUCTURE 80,82,84Zr; calculated potential energy surfaces, ground state bands. Projected shell model (PSM) and relativistic Hartee-Bogoliubov (RHB) theory.
doi: 10.1088/1674-1137/34/1/010
2010ZO03 Phys.Rev. C 82, 024309 (2010) W.-h.Zou, Y.Tian, J.-z.Gu, S.-f.Shen, J.-m.Yao, B.-b.Peng, Z.-y.Ma Microscopic description of nuclear structure around 80Zr NUCLEAR STRUCTURE 80,82,84Zr; calculated ground-state total binding energies and angular momentum projected potential energy surfaces (AMPPES) using projected shell model with a quadrupole constrained relativistic Hartree-Bogoliubov (RHB) theory and NL3 effective interaction and Gogny D1S interaction for the pairing force. Shape coexistence and shape transitions, and decay out of superdeformed rotational bands.
doi: 10.1103/PhysRevC.82.024309
2009TI03 Phys.Lett. B 676, 44 (2009) A finite range pairing force for density functional theory in superfluid nuclei NUCLEAR STRUCTURE Sn, Pb; calculated pairing energy and associated matrix elements using the relativistic Hartree?Bogoliubov approach.
doi: 10.1016/j.physletb.2009.04.067
2009TI04 Phys.Rev. C 79, 064301 (2009) Separable pairing force for relativistic quasiparticle random-phase approximation NUCLEAR STRUCTURE 100,102,104,106,108,110,112,114,116,118,120,122,124,126,128,130,132,134,136Sn, 122Zr, 124Mo, 126Ru, 128Pd, 130Cd, 132Sn, 134Te, 136Xe, 138Ba, 140Ce, 142Nd, 144Sm, 146Gd, 148Dy, 150Er, 152Yb; calculated energies of first 2+, first and second 3-, B(E2), proton average gap, and isoscalar giant monopole resonance (ISGMR) using Relativistic Hartree-Bogoliubov (RHB) and relativistic quasiparticle random phase approximation (RQRPA). Comparison with experimental data.
doi: 10.1103/PhysRevC.79.064301
2009TI07 Phys.Rev. C 80, 024313 (2009) Axially deformed relativistic Hartree Bogoliubov theory with a separable pairing force NUCLEAR STRUCTURE 164Er, 128,130,132,134,136,138,140,142,144,146,148,150,152,154,156,158,160,162,164,166,168,170,172,174,176,178,180,182,184,186,188Sm, 240Pu; calculated binding energies, neutron and proton pairing energies using axially symmetric relativistic Hartree-Bogoliubov calculations. Comparison with experimental data.
doi: 10.1103/PhysRevC.80.024313
2008ZO03 Phys.Rev. C 78, 064613 (2008) Microscopic optical potential for α-nucleus elastic scattering in a Dirac-Brueckner-Hartree-Fock approach NUCLEAR REACTIONS 12C(α, α), E=104, 120, 145, 166, 172.5 MeV; 16O(α, α), E=48.7, 54.1, 69.5, 80.7, 104 MeV; 28Si(α, α), E=104, 166, 240 MeV; 40Ca(α, α), E=40.05, 47, 53.9, 80, 104, 141.7 MeV; calculated density dependence of optical model potentials, normalization factors, σ(θ). DBHF calculations. Comparison with experimental data.
doi: 10.1103/PhysRevC.78.064613
2007MA02 Chin.Phys.Lett. 24, 69 (2007) Influence of D-state in 4He on S Factor for the 2H(d, γ)4He Reaction NUCLEAR REACTIONS 2H(d, γ), E(cm)=10-1000 keV; calculated astrophysical S-factors; deduced sensitivity to 4He D-state.
doi: 10.1088/0256-307X/24/1/019
2006TI10 Chin.Phys.Lett. 23, 3226 (2006) A Separable Pairing Force in Nuclear Matter
doi: 10.1088/0256-307X/23/12/029
1991CA26 Chin.J.Nucl.Phys. 13, No 1, 45 (1991) C.Cai, D.Liu, Q.Shen, Y.Tian, Y.Zhuo Comparison between Phenomenological and Microscopic Optical Potential in Nuclear Data Evaluations NUCLEAR REACTIONS 27Al, 31P, S, Cl, K, Ca, Fe, 59Co, Cu, Ag, In, Sb, W, Pb(n, n), E ≈ 0.083-24 MeV; calculated σ. Comparison with data. Different models chi square fits, phenomenological optimal, global and microscopic optical potentials.
1988TI04 Chin.J.Nucl.Phys. 10, 183 (1988) Tian Ye, Han Yinlu, Shen Qingbiao, Cai Chonghai Calculation and Analysis of Fast Neutron Cross Sections on Mo with Microscopic Optical Potential NUCLEAR REACTIONS 98Mo(n, p), (n, γ), (n, α), (n, np), 100Mo(n, 2n), E=threshold-20 MeV; calculated σ(E). 98Mo(n, n), E=0.5-26 MeV; calculated σ(θ). Hauser-Feshbach, preequilibrium exciton (with evaporation) models, microscopic optical potential.
1986SH37 Chin.J.Nucl.Phys. 8, 376 (1986) Empirical Formula of Nuclear Density fitting Experimental Data of Charge Radii and Charge Distributions NUCLEAR STRUCTURE A ≤ 208; calculated charge radii, distributions; deduced model parameters. Fermi type empirical formula.
1986TI05 Chin.J.Nucl.Phys. 8, 28 (1986) Tian Ye, Wang Chang, Han Yinlu, Shen Qingbiao, Zhuo Yizhong An Application of the Microscopic Optical Potential (S-MOP) to Non Even-Even Nuclei in Calculations of Cross Sections NUCLEAR REACTIONS 6,7Li, 9Be, 10,11B, 14N, 23Na, 27Al, 51V, 53Cr, 55Mn, 59Co, 63,65Cu, 93Nb, 181Ta, 197Au, 235U, 239Pu(n, n), E ≈ 1-200 MeV; calculated total σ, σ(θ). Microscopic optical potential.
1986YE02 Chin.J.Nucl.Phys. 8, 214 (1986) Ye Weilei, Yuan Haiji, Gao Qin, Zheng Chunkai, Tian Ye, Shen Qingbiao Calculations of Neutron Skin for Spherical Nuclei using the Hartree-Fock Method with Skyrme Forces NUCLEAR STRUCTURE 16O, 28Si, 32S, 40,48Ca, 60Ni, 90Zr, 120Sn; calculated proton, neutron density distributions, rms radii. Hartree-Fock method, Skyrme force.
1985TA26 Chin.J.Nucl.Phys. 7, 263 (1985) Tang Xuetian, Gao Liangjun, Tian Ye Generalization of the Goldhaber Theory NUCLEAR STRUCTURE 11C, 19O; calculated momentum distribution widths. Generalized Goldhaber theory.
1985TI06 Chin.J.Nucl.Phys. 7, 207 (1985) Tian Ye, Han Yinlu, Shen Qingbiao, Zhuo Yizhong, Liu Wei, Guo Dongmin Lifei A Global Analysis of Proton Differential Elastic Cross Section Calculations with the Microscopic Optical Potential S-MOP NUCLEAR REACTIONS 184W, 120Sn, 90Zr, 58,60,62,64Ni(p, p), E=16 MeV; 120Sn, 60Ni, 56Fe(p, p), E=30.3 MeV; 90Zr, 58Ni, 40Ca(p, p), E=40 MeV; 68Zn, 58Ni, 40Ca, 12C(p, p), E=61.4 MeV; 208Pb(p, p), E=16-61.4 MeV; analyzed σ(θ). Microscopic optical potential, extended Skyrme force.
1985TI07 Chin.J.Nucl.Phys. 7, 154 (1985) Tian Ye, Han Yinlu, Shen Qingbiao, Zhuo Yizhong, Liu Wei, Guo Dongmin, Li Fei A Global Analysis of Integral Cross Section Calculations with the Microscopic Optical Potential NUCLEAR REACTIONS 12C(n, n), E ≤ 100 MeV; 44,40Ca(n, n), E ≤ 15 MeV; 60Ni(n, n), E ≤ 30 MeV; 242Pu, 98Mo(n, n), E ≤ 100 MeV; 140Ce(n, n), E ≤ 60 MeV; 238U, 232Th(n, n), E ≤ 15 MeV; calculated elastic, nonelastic, total σ(E). Effective Skyrme force, microscopic optical potential.
1985TI08 Chin.J.Nucl.Phys. 7, 344 (1985) Tian Ye, Han Yinlu, Shen Qingbiao, Zhuo Yizhong, Liu Wei, Guo Dongmin, Li Fei A Global Analysis of Neutron Differential Elastic Cross Section Calculations with the Microscopic Optical Potential NUCLEAR REACTIONS 4He, 12C, 16O, 24Mg, 28Si, 32S, 40Ca, 50,52,54Cr, 54,56Fe, 58,60,62,64Ni, 64,66,68Zn, 90,92,94Zr, 92,94,96,98,100Mo, 118,120,122,124Sn, 182,184,186W, 208Pb, 232Th, 238U, 240Pu(n, n), E=1-26 MeV; calculated σ(θ). Microscopic optical potential.
1984SH38 Chin.J.Nucl.Phys. 6, 245 (1984) Shen Qingbiao, Tian Ye, Wang Shunuan, Gao Liangjun, Zhuo Yizhong, Zhao Fujian Exciton Transition Rate Calculations Based on the Optical Model Potentials NUCLEAR STRUCTURE 40Ca, 120Sn, 238U; calculated exciton transition rates. Optical potential, Skyrme interaction.
1980YU01 Chin.J.Nucl.Phys. 2, 19 (1980) Yu Jusheng, Wang Sufang, Tian Yuhong, Hou Mingdong, Miao Degui, Zeng Wenbing, Li Guangwei Study of the Fission of the Excited Nuclei near Radium NUCLEAR REACTIONS, Fission 197Au, Pb, 209Bi(12C, F), E=72.5 MeV; measured (fragment)(fragment)-coin; deduced symmetric fission dominance, fragment shape at scission.
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