NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = Y.Feng Found 26 matches. 2024HU04 Phys.Rev. C 109, 034609 (2024) Y.G.Huang, F.C.Gu, Y.J.Feng, H.Wang, E.X.Xiao, X.Lei, L.Zhu, J.Su Multimodality of 187Ir fission studied by the Langevin approach
doi: 10.1103/PhysRevC.109.034609
2024XI03 Chin.Phys.C 48, 014104 (2024) E.Xiao, X.Lei, Y.Huang, Y.Feng, L.Zhu, J.Su Uncertainties of critical temperatures based on higher-order fluctuations of the largest fragment charge NUCLEAR REACTIONS 40Ca, 56Fe, 90Zr, 120Sn, 136Xe, 197Au(124Sn, X), E=400-1000 MeV/nucleon; analyzed available data; deduced parameters from the isotope thermometer utilizing the isospin-dependent quantum molecular dynamics model in conjunction with the statistical model GEMINI; deduced new signature of liquid-gas phase transition.
doi: 10.1088/1674-1137/ad021d
2023FE02 Phys.Rev. C 107, 024909 (2023) Y.-t.Feng, Z.-y.Song, F.-l.Shao, J.Song Collision centrality and energy dependence of strange hadron production in Au + Au collisions at √ sNN = 7.7-54.4 GeV
doi: 10.1103/PhysRevC.107.024909
2023FE04 Phys.Rev. C 107, 044606 (2023) Y.Feng, Y.Huang, E.Xiao, X.Lei, L.Zhu, J.Su Contributions of quasifission and fusion-fission in the 24Mg + 178Hf reaction at 145 MeV laboratory beam energy using the Boltzmann-Uehling-Uhlenbeck model NUCLEAR REACTIONS 178Hf(24Mg, X), E=145 MV/nucleon; calculated time evolution of dinuclear systems of two fragments, mass numbers of fragment pairs, change of distance between fragments over time, σ of total capture, quasifission and fusion, contribution of quasi-inelastic, quasifission and fusion processes, mass-angular correlation of the fragments, dependence of the σ on the incompressibility parameter. Boltzmann-Uehling-Uhlenbeck model used with phase-space-density constraint (PSDC) method to describe heavy-ion collision near the Coulomb barrier. Comparison to experimental data.
doi: 10.1103/PhysRevC.107.044606
2023LE01 Chin.Phys.C 47, 014102 (2023) X.Lei, E.Xiao, Y.Feng, Y.Huang, L.Zhu, J.Su Production of neutron-deficient nuclei around N = 126 by proton-induced spallation NUCLEAR REACTIONS 237Np, 239Pu, 241Am, 243Cm, 247Bk, 252Cf(p, X), E=1 GeV; analyzed available data. 217,218,221Np, 222,223,224,225,226,227Pu, 225,226,227,228,231Am; deduced σ, yields. Comparison with the IQMD-GEMINI++ model calculations.
doi: 10.1088/1674-1137/ac9601
2022FE04 Phys.Rev. C 105, 024913 (2022) Y.Feng, J.Zhao, H.Li, H.-j.Xu, F.Wang Two- and three-particle nonflow contributions to the chiral magnetic effect measurement by spectator and participant planes in relativistic heavy ion collisions
doi: 10.1103/PhysRevC.105.024913
2022FE05 Phys.Rev. C 106, 034910 (2022) Averaged transverse momentum correlations of hadrons in relativistic heavy-ion collisions
doi: 10.1103/PhysRevC.106.034910
2022HU20 Phys.Rev. C 106, 054606 (2022) Y.Huang, Y.Feng, E.Xiao, X.Lei, L.Zhu, J.Su Influence of pre-scission neutron emission on high-energy 238U fission studied by the Langevin approach NUCLEAR REACTIONS 238U(n, F), E=110, 325, 500 MeV; calculated potential energy surfaces, Langevin trajectory, pre-scission neutron multiplicity and kinetic energy, fragment mass distributions, average fragment mass, total kinetic energy of fission fragments, fragment deformation distribution. Three-dimensional Langevin approach considering nucleus elongation, deformation, and mass asymmetry coupled with Hauser-Feshbach statistical decay model to simulate the pre-scission neutron emission. Comparison with experimental data.
doi: 10.1103/PhysRevC.106.054606
2022XI03 J.Phys.(London) G49, 065102 (2022) E.Xiao, Y.Feng, X.Lei, L.Zhu, J.Su Dissipation of energy and higher-order fluctuations of the largest fragment charge in projectile fragmentation NUCLEAR REACTIONS 120Sn(107Sn, X), E=60 MeV/nucleon; calculated density of the participant center, collective velocity, correlations between impact parameters, mean multiplicity of IMF. The isospin-dependent quantum molecular dynamics (IQMD) model is used to study the non-equilibrium thermalization and fragmentation.
doi: 10.1088/1361-6471/ac4f28
2022ZH30 Phys.Rev. C 105, 054908 (2022) X.-Y.Zhao, Y.-T.Feng, F.-L.Shao, R.-Q.Wang, J.Song Production characteristics of light (anti-)nuclei from (anti-)nucleon coalescence in heavy ion collisions at energies employed at the RHIC beam energy scan
doi: 10.1103/PhysRevC.105.054908
2021AB12 Phys.Rev. C 104, L061901 (2021) M.S.Abdallah, B.E.Aboona, J.Adam, L.Adamczyk, J.R.Adams, J.K.Adkins, G.Agakishiev, I.Aggarwal, M.M.Aggarwal, Z.Ahammed, I.Alekseev, D.M.Anderson, A.Aparin, E.C.Aschenauer, M.U.Ashraf, F.G.Atetalla, A.Attri, G.S.Averichev, V.Bairathi, W.Baker, J.G.Ball Cap, K.Barish, A.Behera, R.Bellwied, P.Bhagat, A.Bhasin, J.Bielcik, J.Bielcikova, I.G.Bordyuzhin, J.D.Brandenburg, A.V.Brandin, I.Bunzarov, J.Butterworth, X.Z.Cai, H.Caines, M.Calderon de la Barca Sanchez, D.Cebra, I.Chakaberia, P.Chaloupka, B.K.Chan, F.-H.Chang, Z.Chang, N.Chankova-Bunzarova, A.Chatterjee, S.Chattopadhyay, D.Chen, J.Chen, J.H.Chen, X.Chen, Z.Chen, J.Cheng, M.Chevalier, S.Choudhury, W.Christie, X.Chu, H.J.Crawford, M.Csanad, M.Daugherity, T.G.Dedovich, I.M.Deppner, A.A.Derevschikov, A.Dhamija, L.Di Carlo, L.Didenko, P.Dixit, X.Dong, J.L.Drachenberg, E.Duckworth, J.C.Dunlop, N.Elsey, J.Engelage, G.Eppley, S.Esumi, O.Evdokimov, A.Ewigleben, O.Eyser, R.Fatemi, F.M.Fawzi, S.Fazio, P.Federic, J.Fedorisin, C.J.Feng, Y.Feng, P.Filip, E.Finch, Y.Fisyak, A.Francisco, C.Fu, L.Fulek, C.A.Gagliardi, T.Galatyuk, F.Geurts, N.Ghimire, A.Gibson, K.Gopal, X.Gou, D.Grosnick, A.Gupta, W.Guryn, A.I.Hamad, A.Hamed, Y.Han, S.Harabasz, M.D.Harasty, J.W.Harris, H.Harrison, S.He, W.He, X.H.He, Y.He, S.Heppelmann, S.Heppelmann, N.Herrmann, E.Hoffman, L.Holub, Y.Hu, H.Huang, H.Z.Huang, S.L.Huang, T.Huang, X.Huang, Y.Huang, T.J.Humanic, G.Igo, D.Isenhower, W.W.Jacobs, C.Jena, A.Jentsch, Y.Ji, J.Jia, K.Jiang, X.Ju, E.G.Judd, S.Kabana, M.L.Kabir, S.Kagamaster, D.Kalinkin, K.Kang, D.Kapukchyan, K.Kauder, H.W.Ke, D.Keane, A.Kechechyan, M.Kelsey, Y.V.Khyzhniak, D.P.Kikola, C.Kim, B.Kimelman, D.Kincses, I.Kisel, A.Kiselev, A.G.Knospe, H.S.Ko, L.Kochenda, L.K.Kosarzewski, L.Kramarik, P.Kravtsov, L.Kumar, S.Kumar, R.Kunnawalkam Elayavalli, J.H.Kwasizur, R.Lacey, S.Lan, J.M.Landgraf, J.Lauret, A.Lebedev, R.Lednicky, J.H.Lee, Y.H.Leung, C.Li, C.Li, W.Li, X.Li, Y.Li, X.Liang, Y.Liang, R.Licenik, T.Lin, Y.Lin, M.A.Lisa, F.Liu, H.Liu, H.Liu, P.Liu, T.Liu, X.Liu, Y.Liu, Z.Liu, T.Ljubicic, W.J.Llope, R.S.Longacre, E.Loyd, N.S.Lukow, X.F.Luo, L.Ma, R.Ma, Y.G.Ma, N.Magdy, D.Mallick, S.Margetis, C.Markert, H.S.Matis, J.A.Mazer, N.G.Minaev, S.Mioduszewski, B.Mohanty, M.M.Mondal, I.Mooney, D.A.Morozov, A.Mukherjee, M.Nagy, J.D.Nam, Md.Nasim, K.Nayak, D.Neff, J.M.Nelson, D.B.Nemes, M.Nie, G.Nigmatkulov, T.Niida, R.Nishitani, L.V.Nogach, T.Nonaka, A.S.Nunes, G.Odyniec, A.Ogawa, S.Oh, V.A.Okorokov, B.S.Page, R.Pak, J.Pan, A.Pandav, A.K.Pandey, Y.Panebratsev, P.Parfenov, B.Pawlik, D.Pawlowska, H.Pei, C.Perkins, L.Pinsky, R.L.Pinter, J.Pluta, B.R.Pokhrel, G.Ponimatkin, J.Porter, M.Posik, V.Prozorova, N.K.Pruthi, M.Przybycien, J.Putschke, H.Qiu, A.Quintero, C.Racz, S.K.Radhakrishnan, N.Raha, R.L.Ray, R.Reed, H.G.Ritter, M.Robotkova, O.V.Rogachevskiy, J.L.Romero, D.Roy, L.Ruan, J.Rusnak, N.R.Sahoo, H.Sako, S.Salur, J.Sandweiss, S.Sato, W.B.Schmidke, N.Schmitz, B.R.Schweid, F.Seck, J.Seger, M.Sergeeva, R.Seto, P.Seyboth, N.Shah, E.Shahaliev, P.V.Shanmuganathan, M.Shao, T.Shao, A.I.Sheikh, D.Shen, S.S.Shi, Y.Shi, Q.Y.Shou, E.P.Sichtermann, R.Sikora, M.Simko, J.Singh, S.Singha, M.J.Skoby, N.Smirnov, Y.Sohngen, W.Solyst, P.Sorensen, H.M.Spinka, B.Srivastava, T.D.S.Stanislaus, M.Stefaniak, D.J.Stewart, M.Strikhanov, B.Stringfellow, A.A.P.Suaide, M.Sumbera, B.Summa, X.M.Sun, X.Sun, Y.Sun, Y.Sun, B.Surrow, D.N.Svirida, Z.W.Sweger, P.Szymanski, A.H.Tang, Z.Tang, A.Taranenko, T.Tarnowsky, J.H.Thomas, A.R.Timmins, D.Tlusty, T.Todoroki, M.Tokarev, C.A.Tomkiel, S.Trentalange, R.E.Tribble, P.Tribedy, S.K.Tripathy, T.Truhlar, B.A.Trzeciak, O.D.Tsai, Z.Tu, T.Ullrich, D.G.Underwood, I.Upsal, G.Van Buren, J.Vanek, A.N.Vasiliev, I.Vassiliev, V.Verkest, F.Videbaek, S.Vokal, S.A.Voloshin, F.Wang, G.Wang, J.S.Wang, P.Wang, Y.Wang, Y.Wang, Z.Wang, J.C.Webb, P.C.Weidenkaff, L.Wen, G.D.Westfall, H.Wieman, S.W.Wissink, J.Wu, Y.Wu, B.Xi, Z.G.Xiao, G.Xie, W.Xie, H.Xu, N.Xu, Q.H.Xu, Y.Xu, Z.Xu, Z.Xu, C.Yang, Q.Yang, S.Yang, Y.Yang, Z.Ye, Z.Ye, L.Yi, K.Yip, Y.Yu, H.Zbroszczyk, W.Zha, C.Zhang, D.Zhang, J.Zhang, S.Zhang, S.Zhang, X.P.Zhang, Y.Zhang, Y.Zhang, Y.Zhang, Z.J.Zhang, Z.Zhang, Z.Zhang, J.Zhao, C.Zhou, X.Zhu, M.Zurek, M.Zyzak Global Λ-hyperon polarization in Au+Au collisions at √ sNN = 3 GeV
doi: 10.1103/PhysRevC.104.L061901
2021FE03 Phys.Rev. C 103, 034912 (2021) Y.Feng, J.Zhao, H.-j.Xu, F.Wang Deciphering the RΨm correlator in search for the chiral magnetic effect in relativistic heavy ion collisions
doi: 10.1103/PhysRevC.103.034912
2021WA34 Phys.Rev. C 104, 014301 (2021) H.K.Wang, Z.Q.Chen, H.Jin, Z.H.Li, G.S.Li, Y.M.Feng, Q.Wang Ground state inversions in hole nuclei near 132Sn driven by the monopole interaction NUCLEAR STRUCTURE 125,127Pd; 126,128Ag; 127,129Cd; 128,130In; calculated ground-state inversions in each pair of nuclei. 128In; calculated low-lying levels, J, π, monopole effects in 3+ and 1- levels. 125Pd, 126Ag, 127Cd, 128In; calculated variation of configurations in the ground states of N=79 isotones with the monopole effects included, comparison of 1- and 3+ states in 126Ag and 128In with monopole effects. 126Pd, 128Cd, 129In; calculated monopole effects in negative-parity levels of the N=80 isotones. Large-scale, shell-model calculations with the extended pairing plus multipole-multipole force (EPQQM) model, and compared with experimental data and with results from jj45pna interaction.
doi: 10.1103/PhysRevC.104.014301
2021XU02 Nucl.Phys. A1005, 121770 (2021) H.-j.Xu, J.Zhao, Y.Feng, F.Wang Importance of non-flow background on the chiral magnetic wave search
doi: 10.1016/j.nuclphysa.2020.121770
2020FE02 Phys.Rev. C 101, 014915 (2020) Back-to-back relative-excess observable to identify the chiral magnetic effect
doi: 10.1103/PhysRevC.101.014915
2020XU01 Phys.Rev. C 101, 014913 (2020) H.-j.Xu, J.Zhao, Y.Feng, F.Wang Complications in the interpretation of the charge-asymmetry-dependent π flow for the chiral magnetic wave
doi: 10.1103/PhysRevC.101.014913
2020ZH11 Phys.Rev. C 101, 034912 (2020) HIJING an describe the anisotropy-scaled charge-dependent correlations at the BNL Relativistic Heavy Ion Collider
doi: 10.1103/PhysRevC.101.034912
2018FE09 Phys.Rev. C 98, 034904 (2018) Responses of the chiral-magnetic-effect-sensitive sine observable to resonance backgrounds in heavy-ion collisions
doi: 10.1103/PhysRevC.98.034904
2004FA04 Eur.Phys.J. A 19, 105 (2004) G.Fares, R.Bimbot, S.Hachem, M.Mirea, R.Anne, T.Benfoughal, C.Cabot, F.Clapier, P.Delbourgo-Salvador, T.Ethvignot, A.Lefebvre, M.Lewitowicz, P.Roussel-Chomaz, M.G.Saint-Laurent, J.E.Sauvestre, J.L.Sida, Y.Y.Feng Fragmentation of 95 MeV/u 12C and 75 MeV/u 13C. Application to secondary-beam production NUCLEAR REACTIONS 9Be, Cu, 197Au(12C, X), E=95 MeV/nucleon; 9Be, Ni, 181Ta(13C, X), E=75 MeV/nucleon; measured fragments isotopic σ(E, θ=0°), momentum distributions. Application go exotic beam production discussed.
doi: 10.1140/epja/i2002-10247-9
2003XU01 Nucl.Phys. A713, 470 (2003) X.Xu, S.Q.Shen, Y.C.Feng, D.C.Zhou Charmonium dissociation cross sections and p-A collisions NUCLEAR REACTIONS Be(p, X), E at 800 MeV/c; calculated J/ψ production σ(θ), transverse momentum. W, Au(p, X), E=high; calculated charmonium supression parameters.
doi: 10.1016/S0375-9474(02)01306-4
2002FE12 Chin.Phys.Lett. 19, 1602 (2002) Nucleon-χcJ Dissociation Cross Sections
doi: 10.1088/0256-307X/19/11/311
1999FE12 Nucl.Instrum.Methods Phys.Res. A437, 490 (1999) V.Fekou-Youmbi, J.L.Sida, N.Alamanos, X.Charlot, C.Mazur, A.Mougeot, F.Auger, D.Bazin, C.Borcea, C.Cabot, A.Cunsolo, A.Foti, A.Gillibert, N.Lecesne, A.Lepine, M.Lewitowicz, R.Liguori-Neto, F.Marie, W.Mittig, J.P.Mols, S.Ottini, E.C.Pollacco, A.Ostrowski, M.Riallot, P.Roussel-Chomaz, Y.Y.Feng First Experiments with the FUSION Detector NUCLEAR REACTIONS 238U(9Be, F), (11Be, F), E=35-68 MeV; measured fission σ, fragments angular correlations.
doi: 10.1016/S0168-9002(99)00683-X
1997FE08 J.Phys.(London) G23, 1259 (1997) V.Fekou-Youmbi, J.L.Sida, N.Alamanos, W.Mittig, F.Auger, D.Bazin, C.Borcea, C.Cabot, X.Charlot, A.Cunsolo, A.Foti, A.Gillibert, N.Lecesne, A.Lepine, M.Lewitowicz, R.Liguori-Neto, F.Marie, C.Mazur, A.Mougeot, S.Ottini, E.Pollacco, A.Ostrowski, M.Riallot, P.Roussel-Chomaz, C.Volant, Y.Y.Feng Unusual Behaviour of Fusion-Fission at Barrier Energies for a Neutron-Rich Halo Nucleus NUCLEAR REACTIONS, ICPND 238U(9Be, X), (11Be, X), E(cm)=37-64 MeV; measured fusion σ; deduced relative fission σ, no enhancement of fusion probability for halo nuclei. Coupled-channel analysis.
1995FE02 Nucl.Phys. A583, 811c (1995) V.Fekou-Youmbi, J.L.Sida, N.Alamanos, F.Auger, D.Bazin, C.Borcea, C.Cabot, A.Cunsolo, A.Foti, A.Gillibert, A.Lepine, M.Lewitowicz, R.Liguori-Neto, W.Mittig, E.Pollacco, P.Roussel-Chomaz, C.Volant, Y.Y.Feng Sub-Coulomb Fusion with Halo Nuclei NUCLEAR REACTIONS 238U(11Be, X), E=67.5 MeV; measured (fragment)(fragment) σ(relative) vs time of flight. U(11Be, F), E(cm)=34-50 MeV; calculated fusion σ(E). Other reactions included.
doi: 10.1016/0375-9474(94)00764-E
1994FE13 Nucl.Instrum.Methods Phys.Res. B86, 225 (1994) Y.Feng, Z.Zhou, Y.Zhou, G.Zhao Cross Sections for 165° Backscattering of 2.0-9.0 MeV 4He from Carbon NUCLEAR REACTIONS C(α, α), E=2-9 MeV; measured relative σ, non-Rutherford backscattering; deduced resonance. ATOMIC PHYSICS C(α, α), E=2-9 MeV; measured relative σ, non-Rutherford backscattering; deduced resonance.
doi: 10.1016/0168-583X(94)95282-5
1993FE13 Chin.J.Nucl.Phys. 15, No 4, 329 (1993) Y.Feng, Z.Zhou, G.Zhao, F.Yang Cross Sections for Backscattering of 4He Ions from Nitrogen NUCLEAR REACTIONS N(α, α), E=2-9 MeV; measured σ(θ) vs E, back scattering. Computer simulation, N implantation in steel analysis.
Back to query form Note: The following list of authors and aliases matches the search parameter Y.Feng: , Y.C.FENG, Y.J.FENG, Y.M.FENG, Y.T.FENG, Y.Y.FENG |