NSR Query Results
Output year order : Descending NSR database version of May 2, 2024. Search: Author = W.Lin Found 77 matches. 2024LI02 Eur.Phys.J. A 60, 8 (2024) L.Li, S.Strauch, J.C.Bernauer, W.J.Briscoe, A.Ch.Ndukwe, E.Cline, D.Cohen, K.Deiters, E.J.Downie, I.P.Fernando, A.Flannery, R.Gilman, Y.Ilieva, M.Kohl, I.Lavrukhin, W.Lin, W.Lorenzon, S.Lunkenheimer, P.Mohanmurthy, J.Nazeer, M.Nicol, T.Patel, A.Prosnyakov, H.Reid, P.E.Reimer, G.Ron, T.Rostomyan, O.M.Ruimi, N.Sparveris, D.Yaari Instrumental uncertainties in radiative corrections for the MUSE experiment
doi: 10.1140/epja/s10050-023-01215-0
2023HU22 Phys.Rev. C 108, 054907 (2023) Q.Hu, G.Y.Tian, R.Wada, X.Q.Liu, W.P.Lin, H.Zheng, Y.P.Zhang, Z.Q.Chen, R.Han, M.R.Huang Semirelativistic antisymmetrized molecular dynamics for the production of energetic neutrons in intermediate-energy heavy-ion reactions
doi: 10.1103/PhysRevC.108.054907
2023LI11 Phys.Rev. C 107, 024609 (2023) G.-S.Li, J.Su, B.-H.Sun, S.Terashima, J.-W.Zhao, X.-D.Xu, J.-C.Zhang, G.Guo, L.-C.He, W.-P.Lin, W.-J.Lin, C.-Y.Liu, C.-G.Lu, B.Mei, Z.-Y.Sun, I.Tanihata, M.Wang, F.Wang, S.T.Wang, X.-L.Wei, J.Wang, J.-Y.Xu, J.-R.Liu, M.-X.Zhang, Y.Zheng, L.-H.Zhu, X.-H.Zhang New measurement of the elemental fragmentation cross sections of 218 MeV/nucleon 28Si on a carbon target NUCLEAR REACTIONS 12C(28Si, X), E=218 MeV/nucleon; measured reaction products, time-of-flight; deduced charge changing σ, elemental fragmentation σ (EFCSs) with charge changes 1-6. Comparison to the previous measurements and to the predictions from the models EPAX2, EPAX3, FRACS, ABRABLA07, NUCFRG2, and IQMD coupled with GEMINI (IQMD+GEMINI). Particle identification by means of MWPC and MUSIC detectors. Beam of 28Si produced from 9Be(40Ar, X), E=320 MeV/nucleon at Heavy Ion Research Facility (HIRFL-CSR, Lanzhou).
doi: 10.1103/PhysRevC.107.024609
2023QU03 Chin.Phys.C 47, 054002 (2023) G.Qu, Y.Huang, H.Zheng, X.Liu, R.Wada, W.Lin, M.Huang, J.Han, P.Ren, Z.Yang, X.Zhang, Q.Leng Determining the nuclear temperature dependence on source neutron-proton asymmetry in heavy-ion reactions at intermediate energy NUCLEAR REACTIONS 112Sn, 70Zn(64Zn, X), 112,124Sn, 58,64Ni, 197Au, 232Th(64Ni, X), E=40 MeV/nucleon; analyzed available data; deduced the dependence of nuclear temperature on emitting source neutron-proton N/Z asymmetry with light charged particles (LCPs) and intermediate mass fragments (IMFs) generated from intermediate-velocity sources in thirteen reaction systems with different N/Z asymmetries.
doi: 10.1088/1674-1137/acbd91
2023RU05 Phys.Rev. C 107, 065803 (2023) L.H.Ru, D.H.Xie, T.Y.Jiao, Z.An, F.Bai, J.W.Cai, X.Fang, Y.H.Fan, Y.X.Fan, B.S.Gao, Y.Z.Li, W.P.Lin, G.Liu, L.Ma, H.J.Ong, X.D.Tang, P.Wang, X.Zhang Strength of the resonance of the 13C(α, n)16O reaction at Eα = 1055.63 keV NUCLEAR REACTIONS 13C(α, n), E=960-1150 keV; measured In; deduced σ(E), resonance strengths at 1055.63 keV (used for neutron detector arrays calibration), resonance parameters for Eα= 1334.64 and 1338.27 keV. Comparison to previous experimental results and ENDF/B-VIII.0 evaluation. Low background neutron detector array consisting of 24 cylindrical 3He-filled proportional counters at 3 MV Tandetron accelerator (Sichuan University).
doi: 10.1103/PhysRevC.107.065803
2023TI02 Phys.Rev. C 107, 044602 (2023) G.Tian, Z.Chen, R.Wada, X.Liu, W.Lin, M.Huang, H.Zheng, Q.Hu, R.Han, F.Shi, X.Zhang, B.Liu, H.Sun Reaction dynamics and in-medium nucleon-nucleon cross section with 12C + 1H at 95 MeV/nucleon NUCLEAR REACTIONS 1H(12C, X)1H/2H/3H/3He/4He/6Li/7Li/7Be/9Be/10Be/8B/10B/11B/10C/11C/12C, E=95 MeV/nucleon; calculated σ(θ, E), particle and cluster emission spectra, outgoing protons velocity distribution. 1H(n, n), (p, p), 1NN(n, n), E=1-155 MeV; calculated in-medium σ(E). Calculations using 3 antisymmetrized molecular dynamics (AMD) - AMD/noD, AMD/D and AMD/DCOALS. Comparison to experimental data.
doi: 10.1103/PhysRevC.107.044602
2023ZH07 Phys.Rev. C 107, 024304 (2023) X.Zhang, W.Lin, J.M.Yao, C.F.Jiao, A.M.Romero, T.R.Rodriguez, H.Hergert Optimization of the generator coordinate method with machine-learning techniques for nuclear spectra and neutrinoless double-β decay: Ridge regression for nuclei with axial deformation RADIOACTIVITY 76Ge(2β-);calculated 0νββ-decay nuclear matrix elements (NME) for the decay between ground states of 76Ge and 76Se. Statistical machine-learning (ML) algorithms applied with generator coordinate method (GCM), orthogonality condition, polinomial ridge regression and energy-transition orthogonality procedure. NUCLEAR STRUCTURE 76Ge, 76Se; calculated low-lying levels, J, π. Subspace-reduction algorithm calculations based on generator coordinate method (GCM)+orthogonality condition(OC)+polinomial ridge regression (RR). Comparison to experimental data.
doi: 10.1103/PhysRevC.107.024304
2023ZH52 Chin.Phys.C 47, 114103 (2023) X.-Y.Zhu, S.Luo, L.-J.Qi, D.-M.Zhang, X.-H.Li, W.-B.Lin Simple model for cluster radioactivity half-lives in trans-lead nuclei RADIOACTIVITY 212,214Po, 238Pu(α), 222,224,226Ra(14C), 228Th(20O), 230U(22Ne), 230Th, 232,234U(24Ne), 234U(26Ne), 234,236U, 236,238Pu(28Mg), 236U, 238Pu(30Mg), 238Pu(32Si), 242Cm(34Si), 213Po, 215At(α), 221Fr, 221,223Ra, 225Ac(14C), 231Pa(23F), 231Pa, 233,235U(24Ne), 233,235U(25Ne), 235U(26Ne); calculated T1/2. Comparison with available data.
doi: 10.1088/1674-1137/acf48a
2022CL01 Phys.Rev. C 105, 055201 (2022) E.Cline, W.Lin, P.Roy, P.E.Reimer, K.E.Mesick, A.Akmal, A.Alie, H.Atac, A.Atencio, C.Ayerbe Gayoso, N.Benmouna, F.Benmokhtar, J.C.Bernauer, W.J.Briscoe, J.Campbell, D.Cohen, E.O.Cohen, C.Collicott, K.Deiters, S.Dogra, E.Downie, I.P.Fernando, A.Flannery, T.Gautam, D.Ghosal, R.Gilman, A.Golossanov, B.F.Halter, J.Hirschman, Y.Ilieva, M.Kim, M.Kohl, B.Krusche, I.Lavrukhin, L.Li, B.Liang-Gilman, A.Liyanage, W.Lorenzon, P.Mohanmurthy, R.Mokal, P.Moran, S.J.Nazeer, P.Or, T.Patel, E.Piasetzky, T.Rauber, R.S.Raymond, D.Reggiani, H.Reid, G.Ron, E.Rooney, T.Rostomyan, M.Schwarz, A.Sneath, P.G.Solazzo, N.Sparveris, N.Steinberg, S.Strauch, V.Sulkosky, N.Wuerfel Characterization of muon and electron beams in the Paul Scherrer Institute PiM1 channel for the MUSE experiment
doi: 10.1103/PhysRevC.105.055201
2022LI11 Nucl.Phys. A1021, 122424 (2022) W.Lin, J.T.Wilkinson, K.E.Barrett, T.E.Barnhart, M.Gott, K.V.Becker, A.M.Clark, A.Miller, G.Brown, M.DeLuca, R.Bartsch, G.F.Peaslee, J.W.Engle Excitation function of 54Fe(p, α)51Mn from 9.5 MeV to 18 MeV NUCLEAR REACTIONS 54Fe(p, α), E=9.5-18 MeV; measured reaction products, Eγ, Iγ; deduced σ and uncertainties. Comparison with TALYS calculations, available data. The 11MV FN Tandem Van de Graaff accelerator at University of Notre Dame's (ND) Nuclear Science Laboratory (NSL).
doi: 10.1016/j.nuclphysa.2022.122424
2022WA36 Chin.Phys.C 46, 104001 (2022) X.Y.Wang, N.T.Zhang, Z.C.Zhang, C.G.Lu, T.L.Pu, J.L.Zhang, L.M.Duan, B.S.Gao, K.A.Li, Y.T.Li, Y.Qian, L.H.Ru, B.Wang, X.D.Xu, H.Y.Zhao, W.P.Lin, Z.W.Cai, B.F.Ji, Q.T.Li, J.Y.Xu, X.D.Tang Studies of the 2α and 3α channels of the 12C+12C reaction in the range of Ec.m.=8.9 MeV to 21 MeV using the active target Time Projection Chamber NUCLEAR REACTIONS 12C(12C, 2α), (12C, 8Be), (12C, 3α), (12C, X), E(cm)=8.9-21 MeV; measured reaction products, Eα, Iα; deduced fusion σ. Comparison with available data. 1024-channel TPC named pMATE (prototype Multi-purpose time projection chamber for nuclear Astrophysical and Exotic beam experiments), the Heavy Ion Research Facility in Lanzhou (HIRFL), China.
doi: 10.1088/1674-1137/ac7a1d
2022WU02 Nucl.Phys. A1017, 122357 (2022) D.Wu, B.Guo, C.Y.He, W.P.Lin, Z.An, T.L.Ma, F.L.Liu, W.S.Yang, J.H.Wei, Y.C.Li, Y.P.Shen, Q.W.Fan, X.G.Wu, Y.Zheng, T.X.Li, F.Bai, P.Wang, M.L.Qiu, N.Y.Wang Determination of the 74Ge(p, γ)75As reaction rates in p-process nucleosynthesis with in-beam γ spectroscopy NUCLEAR REACTIONS 74Ge(p, γ), E=2.5-4.3 MeV; measured reaction products, Eγ, Iγ; deduced σ, reaction rates. Comparison with TALYS and EMPIRE nuclear reaction codes calculations. The 3 MV tandem accelerator of the Institute of Nuclear Science and Technology, Sichuan University.
doi: 10.1016/j.nuclphysa.2021.122357
2022ZH15 Phys.Rev. C 105, 034611 (2022) X.Zhang, X.Liu, Y.Huang, W.Lin, H.Zheng, R.Wada, A.Bonasera, Z.Chen, L.Chen, J.Han, R.Han, M.Huang, Q.Hu, Q.Leng, C.W.Ma, G.Qu, P.Ren, G.Tian, Z.Xu, Z.Yang, L.Zhang Determining impact parameters of heavy-ion collisions at low-intermediate incident energies using deep learning with convolutional neural networks NUCLEAR REACTIONS 124Sn(124Sn, X), E=50, 70, 100 MeV/nucleon; calculated absolute transverse and longitudinal momentum per nucleon of all possible charged particles in exit channel with constrained molecular dynamics (CoMD) model, impact parameter values by convolutional neural network (CNN). Events generated by CoMD are used as input for CNN training. Comparison to impact parameter values obtained using the conventional methods with the impact-parameter sensitive observables.
doi: 10.1103/PhysRevC.105.034611
2021HU01 Phys.Rev. C 103, 014601 (2021) Y.Huang, H.Zheng, R.Wada, X.Liu, W.Lin, G.Qu, M.Huang, P.Ren, J.Han, A.Bonasera, K.Hagel, M.R.D.Rodrigues, S.Kowalski, T.Keutgen, M.Barbui, J.B.Natowitz Nuclear temperature and its dependence on the source neutron-proton asymmetry deduced using the Albergo thermometer NUCLEAR REACTIONS 112Sn(64Zn, X), E=40 MeV/nucleon; measured reaction products, intermediate mass fragments (IMFs), and yield distributions of secondary cold fragments and the reconstructed primary hot IMFs using ΔE-E telescope with an array of 16 single-crystal CsI(Tl) detectors, and 16 detectors of the Belgian-French neutron detector array DEMON for neutrons at K-500 superconducting cyclotron facility of Texas A and M University; deduced N/Z asymmetry dependence of nuclear temperature for nine Albergo thermometers for isotope ratios of 10Be, 11Be/10B, 11B, 12C, 13N/11Be, 12B, 10Be, 11Be/14N, 15N, 7Li, 7Be/11Be, 11B, 11B, 11C/11Be, 11B, 13C, 13N/11Be, 11B, 15N, 19O/11Be, 11B, 17O, 17F/11Be, 11B, 14C, 14N/12B, 12C. 58,64Ni, 112,124Sn, 197Au, 232Th(64Ni, X), (70Zn, X), E=40 MeV/nucleon; measured primary hot intermediate mass fragments (IMFs) for application of experimental sequential decay correction from the apparent temperatures to the real ones. Comparison with antisymmetrized molecular dynamics (AMD) calculations using GEMINI code.
doi: 10.1103/PhysRevC.103.014601
2021HU24 Phys.Rev. C 104, 044611 (2021) Y.Huang, W.Lin, H.Zheng, R.Wada, A.Bonasera, Z.Chen, J.Han, R.Han, M.Huang, K.Hagel, T.Keutgen, X.Liu, Y.G.Ma, C.W.Ma, Z.Majka, G.Qu, L.Qin, P.Ren, G.Tian, J.Wang, Z.Yang, J.B.Natowitz Experimental investigation of abnormal transverse flow enhancement of α particles in heavy-ion collisions NUCLEAR REACTIONS 27Al, 48Ti, 58Ni(40Ar, X), E=47 MeV/nucleon from Texas A and M K500 cyclotron facility; measured reaction products, σ(θ) using 4π array NIMROD-ISiS, consisting of a charged particle array and Neutron Ball; deduced normalized charged particle multiplicity distributions, reduced impact parameters, average in-plane fragment transverse momentum for Z=1-5 fragments as function of rapidity, flow as a function of atomic number, two-particle azimuthal correlation functions, relative flow magnitude as function of atomic number, monotonically increasing trend as a function of fragment charge number, evidences for the non-existence of the abnormal α flow behavior in the heavy-ion collisions. Comparison with improved antisymmetrized molecular dynamics model calculations with Fermi motion (AMD-FM).
doi: 10.1103/PhysRevC.104.044611
2021LI31 J.Phys.(London) G48, 085103 (2021) W.Lin, P.Ren, X.Liu, H.Zheng, M.Huang, G.Qu, R.Wada Investigation of the nuclear liquid-gas phase transition in the static AMD NUCLEAR STRUCTURE 100Sn, 36Ar; calculated calorimetric curves, light particle multiplicities, nuclear liquid-gas phase transitions in the framework of static antisymmetrized molecular dynamics (static AMD) model under either a constant volume or a constant pressure.
doi: 10.1088/1361-6471/abe563
2021LI46 Nucl.Instrum.Methods Phys.Res. B506, 15 (2021) L.Li, Z.An, J.Zhu, W.Lin, S.Williams Absolute measurements of bremsstrahlung double differential cross sections of C and Al atoms by 5-25 keV electron impact NUCLEAR REACTIONS C, 27Al(e-, e-'), E=5-25 keV; measured reaction products, Eγ, Iγ; deduced σ(θ, E) bremsstrahlung. Comparison with theoretical calculations.
doi: 10.1016/j.nimb.2021.09.001
2021MA60 Prog.Part.Nucl.Phys. 121, 103911 (2021) C.-W.Ma, H.-L.Wei, X.-Q.Liu, J.Su, H.Zheng, W.P.Lin, Y.-X.Zhang Nuclear fragments in projectile fragmentation reactions
doi: 10.1016/j.ppnp.2021.103911
2021QU02 Phys.Rev. C 103, 044607 (2021) G.Qu, Y.Huang, D.Peng, Z.Xu, W.Lin, H.Zheng, G.Tian, R.Han, C.Ma, M.Huang, P.Ren, J.Han, Z.Yang, X.Liu, R.Wada Abnormal flow of α-particles in heavy-ion collisions at intermediate energies NUCLEAR REACTIONS 12C(12C, X), E=50 MeV/nucleon; calculated differential σ(θ, E(α)), average in-plane momentum per nucleon as a function of the scaled rapidity, flow as a function of atomic number (Z=1-6), time evolution of flow for Z=1-6 fragments. 40Ca(40Ca, X), E=35 MeV/nucleon; Ni(Ar, X), (Ni, X), E=32-95 MeV/nucleon; calculated flow for proton, α, Z=3-5 and Z≥6 fragments as function of incident energy. Improved antisymmetrized molecular dynamics model with Fermi motion (AMD-FM) and the statistical decay code Gemini in the nucleon-nucleon collision process. Comparison with experimental data from GANIL and Texas A and M facilities. Investigated experimentally observed abnormal α transverse flow behavior in heavy-ion collisions at intermediate energies.
doi: 10.1103/PhysRevC.103.044607
2020HU09 Phys.Rev. C 101, 064603 (2020) Y.Huang, W.Lin, H.Zheng, R.Wada, X.Liu, G.Qu, M.Huang, P.Ren, J.Han, M.R.D.Rodrigues, S.Kowalski, T.Keutgen, K.Hagel, M.Barbui, A.Bonasera, J.B.Natowitz Probing the neutron-proton asymmetry dependence of the nuclear source temperature with light charged particles NUCLEAR REACTIONS 112Sn(64Zn, X), (64Ni, X), E=40 MeV/nucleon; 124Sn, 58,64Ni, 197Au, 232Th(70Zn, X), (64Ni, X), E=40 MeV/nucleon; measured differential σ(θ) for light charged particles: neutrons, protons, deuterons, tritons, 3He and α particles in coincidence with intermediate mass fragments (IMFs) at different lab angle, and apparent temperatures using silicon E-ΔE detector telescope for the detection of IMFs, CsI detectors for light charged particle, and DEMON array for neutrons at the K-500 superconducting cyclotron of Texas A and M University; deduced dependence of nuclear temperature on source neutron-to-proton asymmetry. Comparison with statistical multifragmentation model (SMM), and with antisymmetrized molecular dynamics (AMD-Gemini) calculations.
doi: 10.1103/PhysRevC.101.064603
2020ZH02 Phys.Lett. B 801, 135170 (2020), Corrigendum Phys.Lett. B 803, 135278 (2020) N.T.Zhang, X.Y.Wang, D.Tudor, B.Bucher, I.Burducea, H.Chen, Z.J.Chen, D.Chesneanu, A.I.Chilug, L.R.Gasques, D.G.Ghita, C.Gomoiu, K.Hagino, S.Kubono, Y.J.Li, C.J.Lin, W.P.Lin, R.Margineanu, A.Pantelica, I.C.Stefanescu, M.Straticiuc, X.D.Tang, L.Trache, A.S.Umar, W.Y.Xin, S.W.Xu, Y.Xu Constraining the 12C+12C astrophysical S-factors with the 12C+13C measurements at very low energies NUCLEAR REACTIONS 12C(13C, p)24Na, E=4.640-10.995 MeV; measured reaction products, Eγ, Iγ; deduced σ, branching ratio, S-factor.
doi: 10.1016/j.physletb.2019.135170
2019LI25 Phys.Rev. C 99, 054616 (2019) W.Lin, P.Ren, H.Zheng, X.Liu, M.Huang, K.Yang, G.Qu, R.Wada Solidarity of signal of measures for the liquid-gas phase transition in the statistical multifragmentation model NUCLEAR STRUCTURE 40Ar, 100Rh, 200Th; 100Zr, 100Rh, 100Sn; calculated caloric curve, multiplicity derivative, moment parameters, fluctuation of maximum fragment charge number, the Fisher exponent, Zipf's law parameter, and charge distributions of fragmenting sources at energy of 1-15 MeV/nucleon and temperature T=3-10 MeV. 36Ar, 100Sn; calculated caloric curves at an energy of 2-25 MeV/nucleon. Nuclear liquid-gas phase transition and the mechanism of phase transition treated in the framework of the statistical multifragmentation model (SMM).
doi: 10.1103/PhysRevC.99.054616
2019LI57 Phys.Rev. C 100, 064601 (2019) X.Liu, H.Zheng, R.Wada, W.Lin, M.Huang, P.Ren, G.Qu, J.Han, M.R.D.Rodrigues, S.Kowalski, T.Keutgen, K.Hagel, M.Barbui, A.Bonasera, J.B.Natowitz Neutron-proton asymmetry dependence of nuclear temperature with intermediate mass fragments NUCLEAR REACTIONS 70Zn, 112Sn(64Zn, X), 58,64Ni, 112,124Sn, 197Au, 232Th(64Ni, X), E=40 MeV/nucleon; measured reaction products, intermediate mass fragments (IMFs), light charged particles (LCPs), (LCP)(IMF)-coin, angular distributions using a Si detector telescope for IMFs and an array of 16 CsI(Tl) detectors for LCPs at the Texas A and M cyclotron facility; deduced multiplicity distributions for 14,16,18,20O, N/Z asymmetry dependence of the nuclear temperature. Comparison with previous experimental results, and with antisymmetrized molecular dynamics (AMD) and statistical multifragmentation model (SMM) simulations using the GEMINI code for AMD.
doi: 10.1103/PhysRevC.100.064601
2019WA06 Phys.Rev. C 99, 024616 (2019) R.Wada, W.Lin, P.Ren, H.Zheng, X.Liu, M.Huang, K.Yang, K.Hagel Experimental liquid-gas phase transition signals and reaction dynamics NUCLEAR REACTIONS 27Al, 48Ti, 58Ni(40Ar, X), E=47 MeV/nucleon; analyzed experimental data for charged particles (p, d, t, 3He, α) using the 4π detector NIMROD at TAMU K500 super-conducting cyclotron, quasi-projectile particle kinetic energy spectra, quasi-projectile charge and mass distribution, charged particle multiplicity, and excitation energy distributions; deduced phase transition signals by the statistical multifragmentation model (SMM), quadrupole momentum fluctuation temperatures, specific heat capacity, multiplicity derivative, and normalized variance of maximum charge in quasi-projectiles.
doi: 10.1103/PhysRevC.99.024616
2018LI03 Phys.Rev. C 97, 014613 (2018) X.Liu, H.Zheng, W.Lin, M.Huang, Y.Y.Yang, J.S.Wang, R.Wada, A.Bonasera, J.B.Natowitz Reexamination of a novel determination of density, temperature, and symmetry energy based on a modified Fisher model NUCLEAR REACTIONS 1H(Xe, X), at p=80-350 GeV/c; calculated isotopic yields using the modified Fisher model (MFM) formulation of the Purdue group; deduced density, temperature, and symmetry energy parameters. 40Ca(40Ca, X), E=35-300 MeV/nucleon; calculated density and temperature using the self-consistent method with the original MFM.
doi: 10.1103/PhysRevC.97.014613
2018LI21 Phys.Rev. C 97, 044603 (2018) W.Lin, H.Zheng, P.Ren, X.Liu, M.Huang, R.Wada, Z.Chen, J.Wang, G.Q.Xiao, G.Qu Statistical analysis of experimental multifragmentation events in 64Zn+112Sn at 40 MeV/nucleon NUCLEAR REACTIONS 112Sn(64Zn, X), E=40 MeV/nucleon; calculated average and quasi temperatures with and without the symmetry entropy, and symmetry energy coefficients as function of fragment mass, Coulomb energy coefficients, mass and isotopic distributions, and yield ratio of isobars for intermediate mass fragments (IMF) by isobaric yield ratio (IYR) method. Statistical multifragmentation model (SMM) for observed multifragmentation events intermediate heavy-ion reactions. Comparison with antisymmetrized molecular dynamics model (AMD) calculations, and with experimental data.
doi: 10.1103/PhysRevC.97.044603
2018LI26 Phys.Rev. C 97, 054615 (2018) W.Lin, P.Ren, H.Zheng, X.Liu, M.Huang, R.Wada, G.Qu Sensitivity study of experimental measures for the nuclear liquid-gas phase transition in the statistical multifragmentation model
doi: 10.1103/PhysRevC.97.054615
2017LI15 Phys.Rev. C 95, 044601 (2017) X.Liu, W.Lin, M.Huang, R.Wada, J.Wang, A.Bonasera, H.Zheng, Z.Chen, S.Kowalski, T.Keutgen, K.Hagel, L.Qin, J.B.Natowitz, T.Materna, P.K.Sahu, M.Barbui, C.Bottosso, M.R.D.Rodrigues Chemical potential and symmetry energy for intermediate-mass fragment production in heavy ion reactions near the Fermi energy NUCLEAR REACTIONS 112,124Sn, 58,64Ni, 197Au, 232Th(64Ni, X), (70Zn, X), 112Sn(64Zn, X), E=40 MeV/nucleon; measured mass fragments (IMFs), protons, deuterons, tritons, 3He, and α particles using detector telescopes, neutrons were detected using 16 detectors of the DEMON array, yields of light charged particles (LCPs) in coincidence with IMFs using an array of 16 single crystal CsI(Tl) detectors, and σ(θ) using K-500 superconducting cyclotron facility at Texas A and M; deduced ratios of neutron-proton differential chemical potential values to temperature, density dependent symmetry energy. Comparison with quantum statistical model, and with previous experimental data.
doi: 10.1103/PhysRevC.95.044601
2017TI03 Phys.Rev. C 95, 044613 (2017) G.Tian, R.Wada, Z.Chen, R.Han, W.Lin, X.Liu, P.Ren, F.Shi, F.Luo, Q.Sun, L.Song, G.Q.Xiao Nuclear stopping and light charged particle emission in 12C + 12C at 95 MeV/nucleon NUCLEAR REACTIONS 12C(12C, X)1H/2H/3H/3He/4He/6Li/7Li/7Be/9Be/10Be/8B/10B/11B/10C/11C/12C, E=95 MeV/nucleon; analyzed angular distributions and energy spectra of all the ejectiles from 12C+12C reaction using antisymmetrized molecular dynamics (AMD), a modified version of AMD (AMD-FM), and constrained molecular dynamics (CoMD). Detailed comparison with experimental data.
doi: 10.1103/PhysRevC.95.044613
2017ZH10 J.Phys.(London) G44, 035101 (2017) S.Zhang, M.Huang, R.Wada, X.Liu, W.Lin, J.Wang Shape analysis applied in heavy ion reactions near Fermi energy NUCLEAR REACTIONS 112Sn(64Zn, X), E=40 MeV/nucleon; calculated sphericity (S) and the coplanarity (C) for intermediate-energy mass fragments.
doi: 10.1088/1361-6471/44/3/aa57d7
2017ZH22 Chin.Phys.C 41, 044001 (2017) S.Y.L.Y.Zhang, M.-R.Huang, R.Wada, X-Q.Liu, W.-P.Lin, J.-S.Wang Symmetry energy and experimentally observed cold fragments in intermediate heavy-ion collisions NUCLEAR REACTIONS 9Be(64Ni, X), E=140 MeV/nucleon; analyzed available data; deduced excitation energy of the reconstructed primary isotopes as a function of isotope mass, the symmetry energy at the time of primary fragment formation. The isobaric yield ratio method.
doi: 10.1088/1674-1137/41/4/044001
2016LI52 Phys.Rev. C 94, 064609 (2016) W.Lin, X.Liu, R.Wada, M.Huang, P.Ren, G.Tian, F.Luo, Q.Sun, Z.Chen, G.Q.Xiao, R.Han, F.Shi, J.Liu, B.Gou High-energy proton emission and Fermi motion in intermediate-energy heavy-ion collisions NUCLEAR REACTIONS 51V(40Ar, X), E=44 MeV/nucleon; 181Ta(36Ar, X), E=94 MeV/nucleon; calculated high energy proton spectra, differential σ(θ, Ep), angular distribution of protons in intermediate-energy heavy-ion collisions. Antisymmetrized molecular dynamics model (AMD-FM) with explicit treatment of Fermi motion. Comparison with experimental data.
doi: 10.1103/PhysRevC.94.064609
2016TR10 Phys.Rev. C 94, 064604 (2016) D.T.Tran, H.J.Ong, T.T.Nguyen, I.Tanihata, N.Aoi, Y.Ayyad, P.Y.Chan, M.Fukuda, T.Hashimoto, T.H.Hoang, E.Ideguchi, A.Inoue, T.Kawabata, L.H.Khiem, W.P.Lin, K.Matsuta, M.Mihara, S.Momota, D.Nagae, N.D.Nguyen, D.Nishimura, A.Ozawa, P.P.Ren, H.Sakaguchi, J.Tanaka, M.Takechi, S.Terashima, R.Wada, T.Yamamoto, for the RCNP-E372 Collaboration Charge-changing cross-section measurements of 12-16C at around 45 A MeV and development of a Glauber model for incident energies 10 A-2100 A MeV NUCLEAR REACTIONS 12C(12C, X), (13C, X), (14C, X), (15C, X), (16C, X), E=45 MeV/nucleon, [secondary carbon beams from 9Be(22Ne, X), E=80 MeV/nucleon primary reaction and EN fragment separator at RCNP-Osaka]; measured outgoing particles using multisampling ionization chamber (MUSIC); deduced charge-changing σ(CC) by transmission method, proton rms radii, reaction σ; developed finite-range Glauber model with a global parameter set within the optical-limit approximation; compiled and analyzed reaction σ(E) experimental data for E(12C)=30-100 MeV/nucleon. Comparison of experimental reaction σ for reactions of 12C on 9Be and 27Al targets with present Glauber model analysis.
doi: 10.1103/PhysRevC.94.064604
2015HA09 Nucl.Phys. A936, 17 (2015) R.Han, R.Wada, Z.Chen, Y.Nie, X.Liu, S.Zhang, P.Ren, B.Jia, G.Tian, F.Luo, W.Lin, J.Liu, F.Shi, M.Huang, X.Ruan, J.Ren, Z.Zhou, H.Huang, J.Bao, K.Zhang, B.Hu Fast neutron scattering on Gallium target at 14.8 MeV NUCLEAR REACTIONS 69,71Ga(n, n), (n, n'), E≈14.8 MeV; measured En, In(θ); deduced σ, σ(θ). 69,71Ga(n, n), (n, n'), (n, 2n), (n, np), (n, nα), E=0-15 MeV; calculated σ, σ(θ), using TALYS and MCNP. Compared with experimental data and databases.
doi: 10.1016/j.nuclphysa.2015.01.004
2015LI01 Nucl.Phys. A933, 290 (2015) X.Liu, W.Lin, R.Wada, M.Huang, P.Ren, Z.Chen, J.Wang, G.Q.Xiao, S.Zhang, R.Han, J.Liu, F.Shi, M.R.D.Rodrigues, S.Kowalski, T.Keutgen, K.Hagel, M.Barbui, A.Bonasera, J.B.Natowitz, H.Zheng Reconstructed primary fragments and symmetry energy, temperature and density of the fragmenting source in 64Zn + 112Sn at 40 MeV/nucleon NUCLEAR REACTIONS 112Sn(64Zn, x), E=40 MeV/nucleon; calculated, analyzed cold fragments isotopic multiplicity distributions, yields using AMD; deduced temperature, temperature vs fragment mass, symmetry energy.
doi: 10.1016/j.nuclphysa.2014.09.077
2015LI29 Phys.Rev. C 92, 014623 (2015) X.Liu, W.Lin, M.Huang, R.Wada, J.Wang, Z.Chen, Q.Wang, P.Ren, Y.Yang, S.Jin, P.Ma, J.Ma, Z.Bai, Q.Hu Freezeout concept and dynamical transport model in intermediate-energy heavy-ion reactions NUCLEAR REACTIONS 40Ca(40Ca, X), E=35, 50, 80, 100, 140, 300 MeV/nucleon; calculated density and temperature of intermediate mass fragments (IMFs), ratio of free energy to T0 for N=Z isotopes using a self-consistent method with the modified Fisher (antisymmetrized molecular dynamics) model and Gogny interaction for three different density dependencies of the symmetry energy. Discussed direct connection between the freezeout concept and transport model simulations.
doi: 10.1103/PhysRevC.92.014623
2014LI03 Phys.Rev. C 89, 021601 (2014) W.Lin, X.Liu, M.R.D.Rodrigues, S.Kowalski, R.Wada, M.Huang, S.Zhang, Z.Chen, J.Wang, G.Q.Xiao, R.Han, Z.Jin, J.Liu, F.Shi, T.Keutgen, K.Hagel, M.Barbui, C.Bottosso, A.Bonasera, J.B.Natowitz, E.J.Kim, T.Materna, L.Qin, P.K.Sahu, K.J.Schmidt, S.Wuenschel, H.Zheng Novel determination of density, temperature, and symmetry energy for nuclear multifragmentation through primary fragment-yield reconstruction NUCLEAR REACTIONS 112Sn(64Zn, X), E=40 MeV/nucleon; measured yield distributions of intermediate mass fragments Z=3-18 at Texas A and M cyclotron facility using CsI(Tl) detectors for light-charged particles and DEMON array for neutrons; deduced density, temperature, and symmetry energy coefficient using antisymmetrized molecular dynamics (AMD) simulations.
doi: 10.1103/PhysRevC.89.021601
2014LI33 Phys.Rev. C 90, 014604 (2014) X.Liu, W.Lin, R.Wada, M.Huang, Z.Chen, G.Q.Xiao, S.Zhang, R.Han, M.H.Zhao, P.Ren, Z.Jin, J.Liu, F.Shi, J.B.Natowitz, A.Bonasera, K.Hagel, H.Zheng, M.Barbui, K.Schmidt Mass dependence of transverse flow in heavy ion collisions at intermediate energies NUCLEAR REACTIONS 40Ca(40Ca, X), E=35 MeV/nucleon; measured reaction product spectra, charged particle distributions using NIMROD-ISiS detector system at Texas A-M cyclotron facility; deduced Average in-plane momenta, transverse flow for Z=1-9 particles. Comparison with constrained molecular dynamics (CoMD) simulations.
doi: 10.1103/PhysRevC.90.014604
2014LI34 Phys.Rev. C 90, 014605 (2014) X.Liu, W.Lin, R.Wada, M.Huang, Z.Chen, G.Q.Xiao, S.Zhang, X.Jin, R.Han, J.Liu, F.Shi, H.Zheng, J.B.Natowitz, A.Bonasera Primary isotope yields and characteristic properties of the fragmenting source in heavy-ion reactions near the Fermi energy NUCLEAR REACTIONS 40Ca(40Ca, X), E=35 MeV/nucleon; calculated ratio of free energy to T0 for N=Z isotopes from antisymmetrized molecular dynamics (AMD) simulation, ratio of symmetry energy coefficient relative to temperature (asym/T), T0 values as a function of Z, temperature versus mass number, radial flow energy vs available energy. Modified Fisher model (MFM) applied to central collisions of AMD events. Comparison with experimental data.
doi: 10.1103/PhysRevC.90.014605
2014LI44 Phys.Rev. C 90, 044603 (2014) W.Lin, X.Liu, M.R.D.Rodrigues, S.Kowalski, R.Wada, M.Huang, S.Zhang, Z.Chen, J.Wang, G.Q.Xiao, R.Han, Z.Jin, J.Liu, P.Ren, F.Shi, T.Keutgen, K.Hagel, M.Barbui, C.Bottosso, A.Bonasera, J.B.Natowitz, T.Materna, L.Qin, P.K.Sahu, H.Zheng Experimental reconstruction of primary hot isotopes and characteristic properties of the fragmenting source in heavy-ion reactions near the Fermi energy NUCLEAR REACTIONS 112Sn(64Zn, X), E=40 MeV/nucleon; measured fragment spectra, E(n), I(n), double-differential σ(E, θ) for fragments at Texas A and M K-500 superconducting cyclotron facility; deduced isotopic and neutron multiplicity distributions, cold-isotope distributions, absolute multiplicities of reconstructed hot isotopes, symmetry energy coefficient. Monte Carlo simulations. Comparison with antisymmetrized molecular dynamics (AMD) transport model simulations.
doi: 10.1103/PhysRevC.90.044603
2014ZH12 Phys.Rev. C 89, 037001 (2014) M.H.Zhao, F.Fu, M.Huang, R.Wada, W.Lin, X.Liu, J.S.Wang, Y.Li, Y.Y.Yang, S.L.Jin, J.B.Ma, P.Ma, Q.Wang, Z.Chen Investigation of equation of state and in-medium NN cross sections through nuclear stopping NUCLEAR REACTIONS 129Xe(120Sn, X), E=10-100 MeV/nucleon; calculated nuclear stopping through various equations of state (EOS), and in-medium NN cross sections. Antisymmetrized molecular dynamics model (AMD). Comparison with experimental INDRA data.
doi: 10.1103/PhysRevC.89.037001
2013HA40 Chin.Phys.Lett. 30, 122501 (2013) R.Han, Z.-Q.Chen, R.wada, S.Y.L.T.Zhang, X.-Q.Liu, W.-P.Lin, Z.-X.Jin, B.-T.Hu Effects of In-Medium Nucleon-Nucleon Cross Section and Nuclear Density Distribution on the Proton-Nucleus Total Reaction Cross Section NUCLEAR REACTIONS 9Be, 12C, 16O, 27Al, 28Si, 40Ca, 112,116,120,124Sn, 208Pb(p, X), E<1000 MeV; calculated σ. Glauber model calculations, comparison with available data.
doi: 10.1088/0256-307X/30/12/122501
2013RO25 Phys.Rev. C 88, 034605 (2013) M.R.D.Rodrigues, W.Lin, X.Liu, M.Huang, S.Zhang, Z.Chen, J.Wang, R.Wada, S.Kowalski, T.Keutgen, K.Hagel, M.Barbui, C.Bottosso, A.Bonasera, J.B.Natowitz, T.Materna, L.Qin, P.K.Sahu, K.J.Schmidt Experimental reconstruction of excitation energies of primary hot isotopes in heavy ion collisions near the Fermi energy NUCLEAR REACTIONS 112Sn(64Zn, X), E=40 MeV/nucleon; measured spectra of intermediate mass fragments (IMFs), light particles, neutrons, protons, deuterons, and α in singles and coincidence, double-differential σ(θ) from n(fragment)-, p(fragment)-, α(fragment)-, d(fragment)-coin spectra using various charged-particle detector systems and DEMON neutron detector at Texas A-M facility; deduced multiplicities of the evaporated light particles from Z=3-14, excitation energies of the primary hot isotopes employing a Monte Carlo method. Comparison with antisymmetrized molecular dynamics (AMD) and statistical multifragmentation model (SMM) simulations.
doi: 10.1103/PhysRevC.88.034605
2011AL03 Phys.Rev. C 83, 024913 (2011) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, Z.Chai, V.Chetluru, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, J.Kotula, W.Kucewicz, P.Kulinich, C.M.Kuo, W.Li, W.T.Lin, C.Loizides, S.Manly, D.McLeod, J.Michalowski, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, I.Sedykh, W.Skulski, C.E.Smith, S.G.Steadman, P.Steinberg, G.S.F.Stephans, M.Stodulski, A.Sukhanov, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, B.Wadsworth, P.Walters, E.Wenger, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch Charged-particle multiplicity and pseudorapidity distributions measured with the PHOBOS detector in Au + Au, Cu + Cu, d + Au, and p + p collisions at ultrarelativistic energies
doi: 10.1103/PhysRevC.83.024913
2011LI12 Phys.Rev. C 83, 045802 (2011) W.Lin, B.Li, J.Xu, C.M.Ko, D.H.Wen Energy release from hadron-quark phase transition in neutron stars and the axial w mode of gravitational waves
doi: 10.1103/PhysRevC.83.045802
2011LI54 J.Phys.:Conf.Ser. 312, 042006 (2011) B.-A.Li, L.-W.Chen, M.Gearheart, J.Hooker, C.M.Ko, P.G.Krastev, W.-K.Lin, W.G.Newton, D.-H.Wen, C.Xu, J.Xu Imprints of Nuclear Symmetry Energy on Properties of Neutron Stars
doi: 10.1088/1742-6596/312/4/042006
2010AL01 Phys.Rev.Lett. 104, 062301 (2010) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, A.A.Bickley, R.Bindel, W.Busza, A.Carroll, Z.Chai, V.Chetluru, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, C.Halliwell, J.Hamblen, M.Hauer, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, N.Khan, P.Kulinich, C.M.Kuo, W.Li, W.T.Lin, C.Loizides, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, C.Roland, G.Roland, J.Sagerer, H.Seals, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, P.Walters, E.Wenger, F.L.H.Wolfs, B.Wosiek, K.Wozniak, B.Wyslouch High Transverse Momentum Triggered Correlations over a Large Pseudorapidity Acceptance in Au + Au Collisions at √ sNN = 200 GeV
doi: 10.1103/PhysRevLett.104.062301
2010AL04 Phys.Rev. C 81, 024904 (2010) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, R.Bindel, W.Busza, Z.Chai, V.Chetluru, E.Garcia, T.Gburek, K.Gulbrandsen, J.Hamblen, I.Harnarine, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, J.L.Kane, P.Kulinich, C.M.Kuo, W.Li, W.T.Lin, C.Loizides, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, E.Richardson, C.Roland, G.Roland, J.Sagerer, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, A.Szostak, M.B.Tonjes, A.Trzupek, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, P.Walters, E.Wenger, D.Willhelm, F.L.H.Wolfs, B.Wosiek, K.Wozniak, S.Wyngaardt, B.Wyslouch System size dependence of cluster properties from two-particle angular correlations in Cu+Cu and Au+Au collisions at √ sNN = 200 GeV
doi: 10.1103/PhysRevC.81.024904
2010AL08 Phys.Rev.Lett. 104, 142301 (2010) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, A.A.Bickley, R.Bindel, W.Busza, A.Carroll, Z.Chai, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, C.Halliwell, J.Hamblen, M.Hauer, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, N.Khan, P.Kulinich, C.M.Kuo, W.Li, W.T.Lin, C.Loizides, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, C.Roland, G.Roland, J.Sagerer, H.Seals, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, P.Walters, E.Wenger, F.L.H.Wolfs, B.Wosiek, K.Wozniak, B.Wyslouch Event-by-Event Fluctuations of Azimuthal Particle Anisotropy in Au+Au Collisions at √ sNN = 200 GeV
doi: 10.1103/PhysRevLett.104.142301
2008AL15 Phys.Rev. C 77, 061901 (2008) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, R.Bindel, W.Busza, Z.Chai, V.Chetluru, E.Garcia, T.Gburek, K.Gulbrandsen, J.Hamblen, I.Harnarine, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, J.L.Kane, P.Kulinich, C.M.Kuo, W.Li, W.T.Lin, C.Loizides, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, E.Richardson, C.Roland, G.Roland, J.Sagerer, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, A.Szostak, M.B.Tonjes, A.Trzupek, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, P.Walters, E.Wenger, D.Willhelm, F.L.H.Wolfs, B.Wosiek, K.Wozniak, S.Wyngaardt, B.Wyslouch Identified charged antiparticle to particle ratios near midrapidity in Cu+Cu collisions at √ sNN = 62.4 and 200 GeV
doi: 10.1103/PhysRevC.77.061901
2007AL31 Phys.Rev. C 75, 054913 (2007) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, R.Bindel, W.Busza, Z.Chai, V.Chetluru, E.Garcia, T.Gburek, K.Gulbrandsen, J.Hamblen, I.Harnarine, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, J.L.Kane, P.Kulinich, C.M.Kuo, W.Li, W.T.LIn, C.Lozides, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, E.Richardson, C.Roland, G.Roland, J.Sagerer, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephens, A.Sukhanov, A.Szopstak, M.B.Tonjes, A.Trzupek, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verier, G.I.Veres, P.Walters, E.Wenger, D.Willhelm, F.L.H.Wolfs, B.Wosiek, K.Wozniak, S.Wyngaardt, B.Wyslouch Cluster properties from two-particle angular correlations in p+p collisions at √ s = 200 and 410 GeV NUCLEAR REACTIONS 1H(p, X), E(cm)=200, 410 GeV; measured two particle angular correlations. Compared results to model calculations.
doi: 10.1103/PhysRevC.75.054913
2006AL11 Phys.Rev.Lett. 96, 212301 (2006) B.Alver, B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, R.Bindel, W.Busza, Z.Chai, V.Chetluru, E.Garcia, T.Gburek, K.Gulbrandsen, J.Hamblen, I.Harnarine, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, J.L.Kane, P.Kulinich, C.M.Kuo, W.Li, W.T.Lin, C.Loizides, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, E.Richardson, C.Roland, G.Roland, J.Sagerer, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, A.Szostak, M.B.Tonjes, A.Trzupek, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, P.Walters, E.Wenger, D.Willhelm, F.L.H.Wolfs, B.Wosiek, K.Wozniak, S.Wyngaardt, B.Wyslouch System Size and Centrality Dependence of Charged Hadron Transverse Momentum Spectra in Au + Au and Cu + Cu Collisions at √ sNN = 62.4 and 200 GeV NUCLEAR REACTIONS Cu(Cu, X), Au(Au, X), E(cm)=62.4, 200 GeV/nucleon; measured charged hadrons transverse momentum spectra; deduced system size and centrality dependence, nuclear modification factors.
doi: 10.1103/PhysRevLett.96.212301
2005BA17 Phys.Rev.Lett. 94, 082304 (2005) B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, A.A.Bickley, R.Bindel, W.Busza, A.Carroll, Z.Chai, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, C.Halliwell, J.Hamblen, M.Hauer, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, N.Khan, P.Kulinich, C.M.Kuo, W.T.Lin, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, C.Reed, C.Roland, G.Roland, J.Sagerer, H.Seals, I.Sedykh, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, E.Wenger, F.L.H.Wolfs, B.Wosiek, K.Wozniak, B.Wyslouch Centrality Dependence of Charged Hadron Transverse Momentum Spectra in Au + Au Collisions from √ sNN = 62.4 to 200 GeV NUCLEAR REACTIONS 197Au(197Au, X), E(cm)=62.4 GeV/nucleon; measured charged hadrons transverse momentum spectra, centrality dependence; deduced medium modification factor. Comparison with data at higher energies.
doi: 10.1103/PhysRevLett.94.082304
2005BA32 Phys.Rev.Lett. 94, 122303 (2005) B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, R.R.Betts, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, Z.Chai, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, M.Hauer, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, W.T.Lin, S.Manly, D.McLeod, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, H.Seals, I.Sedykh, W.Skulski, C.E.Smith, M.A.Stankiewicz, P.Steinberg, G.S.F.Stephans, A.Sukhanov, J.-L.Tang, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, S.S.Vaurynovich, R.Verdier, G.I.Veres, E.Wenger, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch Energy Dependence of Elliptic Flow over a Large Pseudorapidity Range in Au+Au Collisions at the BNL Relativistic Heavy Ion Collider NUCLEAR REACTIONS 197Au(197Au, X), E(cm)=19.6, 62.4, 130, 200 GeV/nucleon; measured elliptic flow; deduced energy and pseudorapidity dependence.
doi: 10.1103/PhysRevLett.94.122303
2005BA83 Phys.Rev. C 72, 031901 (2005) B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, B.Becker, R.R.Betts, A.A.Bickley, R.Bindel, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, A.S.Harrington, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, N.Khan, P.Kulinich, C.M.Kuo, J.W.Lee, W.T.Lin, S.Manly, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, C.Roland, G.Roland, J.Sagerer, P.Sarin, I.Sedykh, W.Skulski, C.E.Smith, P.Steinberg, G.S.F.Stephans, A.Sukhanov, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, G.I.Veres, F.L.H.Wolfs, B.Wosiek, K.Wozniak, B.Wyslouch, J.Zhang Scaling of charged particle production in d+Au collisions at √ sNN = 200 GeV NUCLEAR REACTIONS 197Au(d, X), E(cm)=200 GeV/nucleon; analyzed charged particle pseudorapidity distribution, integrated multiplicities vs centrality.
doi: 10.1103/PhysRevC.72.031901
2004BA01 Phys.Lett. B 578, 297 (2004) B.B.Back, M.D.Baker, D.S.Barton, R.R.Betts, M.Ballintijn, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, W.T.Lin, J.W.Lee, S.Manly, D.McLeod, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, W.Skulski, S.G.Steadman, P.Steinberg, G.S.F.Stephans, A.Sukhanov, J.-L.Tang, R.Teng, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, G.I.Veres, B.Wadsworth, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch Charged hadron transverse momentum distributions in Au + Au collisions at √ sNN = 200 GeV NUCLEAR REACTIONS 197Au(197Au, X), E(cm)=200 GeV/nucleon; measured charged hadron transverse momentum distributions vs centrality, invariant yields; deduced scaling features.
doi: 10.1016/j.physletb.2003.10.101
2004BA20 Braz.J.Phys. 34, 829 (2004) B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, B.Becker, R.R.Betts, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, A.S.Harrington, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, J.W.Lee, W.T.Lin, S.Manly, D.McLeod, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, I.Sedykh, W.Skulski, C.E.Smith, P.Steinberg, G.S.F.Stephans, A.Sukhanov, J.-L.Tang, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, G.I.Veres, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch, J.Zhang Recent Results from PHOBOS at RHIC NUCLEAR REACTIONS 197Au(d, X), (197Au, X), E(cm)=19.6, 130, 200 GeV/nucleon; measured charged particles pseudorapidity distributions, transverse momentum, yields; deduced nuclear modification factors.
doi: 10.1590/s0103-97332004000500032
2004BB20 Braz.J.Phys. 34, 829 (2004) B.B.Back, M.D.Baker, M.Ballintijn, D.S.Barton, B.Becker, R.R.Betts, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, T.Gburek, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, A.S.Harrington, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, J.W.Lee, W.T.Lin, S.Manly, D.McLeod, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, I.Sedykh, W.Skulski, C.E.Smith, P.Steinberg, G.S.F.Stephans, A.Sukhanov, J.-L.Tang, M.B.Tonjes, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, G.I.Veres, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch, J.Zhang Recent Results from PHOBOS at RHIC NUCLEAR REACTIONS 197Au(d, X), (197Au, X), E(cm)=19.6, 130, 200 GeV/nucleon; measured charged particles pseudorapidity distributions, transverse momentum, yields; deduced nuclear modification factors.
doi: 10.1590/S0103-97332004000500032
2003BA13 Phys.Rev. C 67, 021901 (2003) B.B.Back, M.D.Baker, D.S.Barton, R.R.Betts, M.Ballintijn, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, W.T.Lin, S.Manly, D.McLeod, J.Michalowski, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, W.Skulski, S.G.Steadman, P.Steinberg, G.S.F.Stephans, M.Stodulski, A.Sukhanov, J.-L.Tang, R.Teng, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, B.Wadsworth, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch Ratios of charged antiparticles to particles near midrapidity in Au+Au collisions at √sNN=200 GeV NUCLEAR REACTIONS 197Au(197Au, X), E(cm)=200 GeV/nucleon; measured charged particle/antiparticle yield ratios; deduced baryon chemical potential. Comparison with previous results, model predictions.
doi: 10.1103/PhysRevC.67.021901
2003BA61 Phys.Rev.Lett. 91, 052303 (2003) B.B.Back, M.D.Baker, D.S.Barton, R.R.Betts, M.Ballintijn, A.A.Bickley, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, G.A.Heintzelman, C.Henderson, D.J.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.L.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, W.T.Lin, S.Manly, D.McLeod, J.Michalowski, A.C.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, W.Skulski, S.G.Steadman, P.Steinberg, G.S.F.Stephans, M.Stodulski, A.Sukhanov, J.-L.Tang, R.Teng, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, B.Wadsworth, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch Significance of the Fragmentation Region in Ultrarelativistic Heavy-Ion Collisions NUCLEAR REACTIONS 197Au(197Au, X), E(cm)=19.6, 130, 200 GeV/nucleon; measured charged particle multiplicities, pseudorapidity distributions vs centrality; deduced scaling features. Limiting fragmentation hypothesis.
doi: 10.1103/PhysRevLett.91.052303
2002BA94 Phys.Rev.Lett. 89, 222301 (2002) B.B.Back, M.D.Baker, D.S.Barton, R.R.Betts, R.Bindel, A.Budzanowski, W.Busza, A.Carroll, M.P.Decowski, E.Garcia, N.George, K.Gulbrandsen, S.Gushue, C.Halliwell, J.Hamblen, C.Henderson, D.Hofman, R.S.Hollis, R.Holynski, B.Holzman, A.Iordanova, E.Johnson, J.Kane, J.Katzy, N.Khan, W.Kucewicz, P.Kulinich, C.M.Kuo, W.T.Lin, S.Manly, D.McLeod, J.Michalowski, A.Mignerey, R.Nouicer, A.Olszewski, R.Pak, I.C.Park, H.Pernegger, C.Reed, L.P.Remsberg, M.Reuter, C.Roland, G.Roland, L.Rosenberg, J.Sagerer, P.Sarin, P.Sawicki, W.Skulski, S.G.Steadman, P.Steinberg, G.S.F.Stephans, M.Stodulski, A.Sukhanov, J.-L.Tang, R.Teng, A.Trzupek, C.Vale, G.J.van Nieuwenhuizen, R.Verdier, B.Wadsworth, F.L.H.Wolfs, B.Wosiek, K.Wozniak, A.H.Wuosmaa, B.Wyslouch Pseudorapidity and Centrality Dependence of the Collective Flow of Charged Particles in Au + Au Collisions at √ snn = 130 GeV NUCLEAR REACTIONS 197Au(197Au, X), E(cm)=130 GeV/nucleon; measured charged particle collective flow vs centrality, pseudorapidity; deduced reaction mechanism features.
doi: 10.1103/PhysRevLett.89.222301
1993KI09 Nucl.Instrum.Methods Phys.Res. A327, 427 (1993) L.L.Kiang, R.H.Tsou, W.J.Lin, S.C.Lin, G.C.Kiang, P.K.Teng, S.D.Li A Study on T-Shape Compton Suppression Spectrometer by Monte Carlo Simulation RADIOACTIVITY 137Cs(β-); 60Co(β-); 24Na(β-); measured Compton suppressed, unsuppressed γ-spectra; deduced geometrical factors effect on suppression factor. Monte Carlo simulation.
doi: 10.1016/0168-9002(93)90708-P
1992LI05 J.Radioanal.Nucl.Chem. 157, 367 (1992) Gamma-Ray Emission Intensities of the 232Th Chain in Secular Equilibrium of 235U and the Progeny of 238U RADIOACTIVITY 232Th(α); 228Ra(β-); 228Ac(β-); 228Th(α); 224Ra(α); 212Pb(β-); 212Bi(α), (β-); 208Tl(β-); 238U(α); 234Th(β-); 234Pa(β-); 234U(α); 235U(α); measured Eγ, Iγ for parent, daughters; deduced γ-ray abundances, absolute Iγ.
doi: 10.1007/BF02047451
1991LI10 J.Radioanal.Nucl.Chem. 153, 51 (1991) The Half-Life and Abundance of the Gamma-Rays of Bismuth-207 RADIOACTIVITY 207Bi; measured T1/2; calculated γ-ray abundances.
doi: 10.1007/BF02170248
1991LI11 J.Radioanal.Nucl.Chem. 153, 137 (1991) Gamma Ray Emission Intensities of 226Ra in Equilibrium with Its Daughter Products RADIOACTIVITY 226Ra, 214Pb, 214Bi [from 226Ra decay chain]; measured Eγ, Iγ; deduced absolute Iγ, γ-abundances. Intrinsic Ge counter.
doi: 10.1007/BF02164874
1988LI11 Nucl.Phys. A481, 477 (1988) W.J.Lin, O.K.Manuel, G.L.Cumming, D.Krstic, R.I.Thorpe Geochemically Measured Half-Lives of 82Se and 130Te RADIOACTIVITY 82Se, 130Te(2β); measured T1/2, upper limits. Parent, daughter ratios in mineral kitkaite.
doi: 10.1016/0375-9474(88)90340-5
1988LI12 Nucl.Phys. A481, 484 (1988) W.J.Lin, O.K.Manuel, S.Muangnoicharoen, R.I.Thorpe Double Beta-Decay of Tellurium-128 and Tellurium-130 RADIOACTIVITY 128,130Te(2β); deduced T1/2 ratio. Radiogenic 128,130Xe isotopic composition determination by stepwise heating of geologically-odd NiTe2, PbTe.
doi: 10.1016/0375-9474(88)90341-7
1986LI10 Nucl.Phys. A457, 285 (1986) W.J.Lin, O.K.Manuel, L.L.Oliver, R.I.Thorpe Double Beta-Decay of 82Se and 130Te RADIOACTIVITY 82Se, 130Te(2β); measured daughter composition ratio in NiTeSe mineral; deduced T1/2, ratio.
doi: 10.1016/0375-9474(86)90378-7
1984CH41 Chin.J.Nucl.Phys. 6, 258 (1984) Chen Xuejun, Tang Jianzhi, Lin Wei Strong Absorption Model of (α, 2α) Quasi-Free Reaction NUCLEAR REACTIONS 16O(α, 2α), E=90, 140 MeV; calculated σ(E(α1), θ(α1), θ(α2)); deduced reaction mechanism. Strong absorption model, DWIA, clusters.
1973LI04 Nucl.Phys. A199, 14 (1973) Virtual Nuclear Excitation Corrections to Elastic Electron Scattering from 40Ca NUCLEAR REACTIONS 40Ca(e, e), E=250, 500, 1000 MeV; calculated σ(θ); analyzed virtual nuclear excitation corrections. Second-order Born approximation.
doi: 10.1016/0375-9474(73)90330-8
1972AD04 Phys.Rev. C5, 664 (1972) J.C.Adloff, W.K.Lin, K.H.Souw, P.Chevallier Isospin-Forbidden Particle Decay of the First T = 3/2 States in 9Be and 9B NUCLEAR REACTIONS 7Li(3He, pn), E=7.95, 8.7, 10 MeV; measured σ(Ep, En, Eγ). 9B, 9Be analog states deduced n-width, p-width.
doi: 10.1103/PhysRevC.5.664
1972LI17 Phys.Lett. 39B, 447 (1972) Dispersion Corrections to the Electron-Nucleus Scattering NUCLEAR REACTIONS 40Ca(e, e), E=250, 500, 1000 MeV; calculated σ(θ), nonstatic second-order dispersion corrections.
doi: 10.1016/0370-2693(72)90314-0
1971LI04 Phys.Rev. C3, 20 (1971) p-3He and p-3H Angular Correlations from the Reaction D(3He, p) NUCLEAR REACTIONS 2H(3He, p), E=16.5, 6.6-7.8 MeV; measured σ(Ep, Et, E(3He), θ(pt), θ(p)(3He)).
doi: 10.1103/PhysRevC.3.20
1971LI30 Phys.Lett. 37B, 480 (1971) Isospin Mixing of the First T = 3/2 States in 9Be and 9B NUCLEAR STRUCTURE 9Be, 9B; calculated Coulomb interaction contribution to isospin mixing in T=3/2 states.
doi: 10.1016/0370-2693(71)90350-9
1970LI06 Phys.Rev. C1, 816 (1970) W.-K.Lin, F.Scheibling, R.W.Kavanagh Investigations of the First Excited State of 4He via the Reaction 7Li(p, α) NUCLEAR REACTIONS 7Li(p, α), E=9.1 MeV; measured σ(Eα, Ep, Et, θ(αp), θ(αt), θ((α)(3He))). 4He deduced resonance, J, π.
doi: 10.1103/PhysRevC.1.816
1970LI13 Phys.Rev. C2, 871 (1970) Validity of the Strutinsky Shell-Correction Theory NUCLEAR STRUCTURE 208Pb; Z=114; calculated Strutinsky shell corrections.
doi: 10.1103/PhysRevC.2.871
1969BR15 Phys.Rev. 181, 1506 (1969) K.A.Brueckner, W.-f.Lin, R.J.Lombard Isotope Shift of Nuclear Charge Distributions NUCLEAR STRUCTURE 40,48Ca, 116,124Sn, 202,208Pb; calculated isotope shift of nuclear charge distribution.
doi: 10.1103/PhysRev.181.1506
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