NSR Query Results
Output year order : Descending NSR database version of March 21, 2024. Search: Author = L.Guo Found 40 matches. 2023GU03 Phys.Rev. C 107, 014318 (2023) L.Guo, W.L.Lv, Y.F.Niu, D.L.Fang, B.S.Gao, K.A.Li, X.D.Tang Spin-isospin excitations in the direction of β+ decay for 80Zn and 126Ru at finite temperature RADIOACTIVITY 80Zn, 126Ru(β+); calculated Gamow-Teller (GT+) strength distribution with respect to the ground state of daughter nuclei, spin-dipole (SD) transition strength distributions, sum-rule values of GT and SD transitions. Self consistent finite-temperature proton-neutron relativistic quasiparticle RPA (FT-PNRQRPA) and finite-temperature proton-neutron relativistic RPA (FT-PNRRPA) model.
doi: 10.1103/PhysRevC.107.014318
2023LU16 Phys.Rev.Lett. 131, 202502 (2023) Z.-W.Lu, L.Guo, Z.-Z.Li, M.Ababekri, F.-Q.Chen, C.Fu, C.Lv, R.Xu, X.Kong, Y.-F.Niu, J.-X.Li Manipulation of Giant Multipole Resonances via Vortex γ Photons
doi: 10.1103/PhysRevLett.131.202502
2023SU02 Phys.Rev. C 107, L011601 (2023) Microscopic study of fusion reactions with a weakly bound nucleus: Effects of deformed halo NUCLEAR REACTIONS 232Th(14C, X), (15C, X), E(cm)=50-70 MeV; calculated fusion σ(E), intranuclear potential. 232Th(15C, 14C), E=54 MeV; calculated one-neutron transfer probability for 49 different orientations. Time-dependent density functional theory (TDDFT). Comparison to experimental data. NUCLEAR STRUCTURE 14,15C; calculated two-dimensional density distribution of the ground state.
doi: 10.1103/PhysRevC.107.L011601
2023SU05 Phys.Rev. C 107, 064609 (2023) Microscopic study of the hot-fusion reaction 48Ca + 238U with the constraints from time-dependent Hartree-Fock theory NUCLEAR REACTIONS 238U(48Ca, X), E(cm)=180-215 MeV; calculated capture σ(E), fusion σ(E), orientation-averaged fusion σ(E), fusion probabilities, injection distances, separation distance of centers of mass of two fragments with zero conjugate momenta, internuclear potentials between 48Ca and 238U for different orientations, density distributions. 238U(48Ca, 3n), (48Ca, 4n), E(cm)=18-205 MeV; calculated evaporation-residue σ(E). Calculations utilizing microscopic descriptions of the ground state with static Hartree-Fock calculations and reaction dynamic using time-dependent Hartree-Fock (TDHF) theory, in combination with coupled-channel and fusion-by-diffusion models. Comparison to experimental data.
doi: 10.1103/PhysRevC.107.064609
2022SU07 Phys.Rev. C 105, 034601 (2022) Microscopic study of the fusion reactions 40, 48Ca+78Ni and the effect of the tensor force NUCLEAR REACTIONS 78Ni(40Ca, X), (48Ca, X), E(cm)=70, 80, 90 MeV; calculated internuclear potentials, fusion σ. Dynamic density-constrained time-dependent Hartree-Fock (DC-TDHF) and static Hartree-Fock theory. Discussed role of tensor force in the fusion of nuclei.
doi: 10.1103/PhysRevC.105.034601
2022SU10 Phys.Rev. C 105, 054610 (2022) Microscopic study of compound-nucleus formation in cold-fusion reactions NUCLEAR REACTIONS 208Pb(48Ca, X), E=160-220 MeV; 208Pb(50Ti, X), E=180-230 MeV; 208Pb(54Cr, X), E=190-235 MeV; calculated capture and fusion σ(E), effective fusion probabilities, injection parameters. The time-dependent Hartree-Fock (TDHF) approach. Comparison to experimental data.
doi: 10.1103/PhysRevC.105.054610
2022WU05 Phys.Lett. B 825, 136886 (2022) Production of proton-rich nuclei in the vicinity of 100Sn via multinucleon transfer reactions NUCLEAR REACTIONS 112Sn(58Ni, X)Pd/Ag/Cd/In/Sn/Xe/I/Te/Sb, E(cm)=221.77 MeV; analyzed available data; calculated σ using TDHF+GEMINI approach.
doi: 10.1016/j.physletb.2022.136886
2022YA15 Phys.Rev. C 105, L051302 (2022) H.B.Yang, Z.G.Gan, Z.Y.Zhang, M.H.Huang, L.Ma, M.M.Zhang, C.X.Yuan, Y.F.Niu, C.L.Yang, Y.L.Tian, L.Guo, Y.S.Wang, J.G.Wang, H.B.Zhou, X.J.Wen, H.R.Yang, X.H.Zhou, Y.H.Zhang, W.X.Huang, Z.Liu, S.G.Zhou, Z.Z.Ren, H.S.Xu, V.K.Utyonkov, A.A.Voinov, Yu.S.Tsyganov, A.N.Polyakov, D.I.Solovyev New isotope 207Th and odd-even staggering in α-decay energies for nuclei with Z > 82 and N < 126 RADIOACTIVITY 207Th(α)[from 176Hf(36Ar, 5n), E=197-199 MeV]; 208Th(α)[from 176Hf(36Ar, 4n), E=197-199 MeV]; 203Ra, 199Rn, 195Po(α)[from 207Th α-decay chain]; 204Ra, 200Rn, 196Po(α)[from 208Th α-decay chain]; measured evaporation residues (ERs), Eα, and ER-α1-α2-α3-α4 correlated α-decay chain from the decays of 207Th and208Th. 207,208Th; deduced α-decay T1/2, production σ. Z=84-92, N=102-126; discussed systematics of experimental and theoretically calculated (by relativistic Hartree-Fock-Bogoliubov and large-scale shell-model approaches) odd-even staggering (OES) of Q(α), Q(proton) and Q(neutron). Position-sensitive silicon strip detectors (PSSDs), non-position sensitive Si detectors, and SHANS gas-filled recoil separator at the sector focusing cyclotron facility of HIRFL, Lanzhou.
doi: 10.1103/PhysRevC.105.L051302
2022ZH45 Phys.Rev. C 106, 024305 (2022) M.M.Zhang, Y.L.Tian, Y.S.Wang, Z.Y.Zhang, Z.G.Gan, H.B.Yang, M.H.Huang, L.Ma, C.L.Yang, J.G.Wang, C.X.Yuan, C.Qi, A.N.Andreyev, X.Y.Huang, S.Y.Xu, Z.Zhao, L.X.Chen, J.Y.Wang, M.L.Liu, Y.H.Qiang, G.S.Li, W.Q.Yang, R.F.Chen, H.B.Zhang, Z.W.Lu, X.X.Xu, L.M.Duan, H.R.Yang, W.X.Huang, Z.Liu, X.H.Zhou, Y.H.Zhang, H.S.Xu, N.Wang, H.B.Zhou, X.J.Wen, S.Huang, W.Hua, L.Zhu, X.Wang, Y.C.Mao, X.T.He, S.Y.Wang, W.Z.Xu, H.W.Li, Y.F.Niu, L.Guo, Z.Z.Ren, S.G.Zhou Fine structure in the α decay of the 8+ isomer in 216, 218U RADIOACTIVITY 216,216m,218,218mU(α)[218U from 182W(40Ar, 4n), E=190 MeV, 184W(40Ca, 2nα), E=206 MeV, 216U from 180W(40Ar, 4n), E=191 MeV]; measured evaporation residues (EVRs), Eα, Iα, (EVR)α1-α2-correlations, T1/2 using position-sensitive strip detectors (PSSDs) for α detection, and SHANS separator at HIRFL-Lanzhou. 216,216m,218,218mU; deduced T1/2, Q-values, α-branching ratio, α-decay hindrance factors. 204Rn, 208,210Ra, 212,214Th(α)[from 216,218U α-decay chains]; measured Eα, T1/2. 212Th; deduced level, J, π, identification of the first 2+ state. 215Ra, 212,213,216Ac, 211,212,213,214,216,216m,217Th, 216,217,217m,218Pa, 217,218,219U; observed Eα from their decays from (EVR)α-correlations. Comparison with previous experimental data.
doi: 10.1103/PhysRevC.106.024305
2022ZH49 Chin.Phys.C 46, 085001 (2022) L.Zhao, W.Luo, L.Bathe-Peters, S.Chen, M.Chouaki, W.Dou, L.Guo, Z.Guo, G.Hussain, J.Li Measurement of muon-induced neutron yield at the China Jinping Underground Laboratory
doi: 10.1088/1674-1137/ac66cc
2021DO09 Nature(London) 590, 561 (2021), Pub.Correction Nature(London) 604, E26 (2022) J.Dove, B.Kerns, R.E.McClellan, S.Miyasaka, D.H.Morton, K.Nagai, S.Prasad, F.Sanftl, M.B.C.Scott, A.S.Tadepalli, C.A.Aidala, J.Arrington, C.Ayuso, C.L.Barker, C.N.Brown, W.C.Chang, A.Chen, D.C.Christian, B.P.Dannowitz, M.Daugherity, M.Diefenthaler, L.El Fassi, D.F.Geesaman, R.Gilman, Y.Goto, L.Guo, R.Guo, T.J.Hague, R.J.Holt, D.Isenhower, E.R.Kinney, N.Kitts, A.Klein, D.W.Kleinjan, Y.Kudo, C.Leung, P.-J.Lin, K.Liu, M.X.Liu, W.Lorenzon, N.C.R.Makins, M.Mesquita de Medeiros, P.L.McGaughey, Y.Miyachi, I.Mooney, K.Nakahara, K.Nakano, S.Nara, J.-C.Peng, A.J.Puckett, B.J.Ramson, P.E.Reimer, J.G.Rubin, S.Sawada, T.Sawada, T.-A.Shibata, D.Su, M.Teo, B.G.Tice, R.S.Towell, S.Uemura, S.Watson, S.G.Wang, A.B.Wickes, J.Wu, Z.Xi, Z.Ye The asymmetry of antimatter in the proton NUCLEAR REACTIONS 1,2H(p, μ+), (p, μ-), E=120 GeV; measured reaction products. 1H; deduced antimatter asymmetry in the proton.
doi: 10.1038/s41586-021-03282-z
2021RE08 Phys.Rev. C 103, 065203 (2021) T.Reed, C.Leon, F.Vera, L.Guo, B.Raue Constituent counting rule and ω photoproduction
doi: 10.1103/PhysRevC.103.065203
2020ME11 Phys.Rev. C 102, 064322 (2020) X.Meng, S.Zhang, L.Guo, L.Geng, L.Cao Isospin-density-dependent pairing from infinite nuclear matter to finite nuclei ATOMIC MASSES Z=20, A=34-58; Z=28, A=48-80; Z=40, A=76-112; Z=50, A=98-140; calculated odd-even mass (OEM) staggering as a function of mass number using Skyrme Hartree-Fock plus BCS method (SHF+BCS) with the SkP force, and compared with other types of isovector and isoscalar effective pairing interactions. Comparison with and experimental data.
doi: 10.1103/PhysRevC.102.064322
2019GO28 Phys.Rev. C 100, 054612 (2019) Influence of the tensor interaction on heavy-ion fusion cross sections NUCLEAR REACTIONS 12C(12C, X), (13C, X), E(cm)=1-7 MeV; 40Ca(40Ca, X), (48Ca, X), 48Ca(48Ca, X), E(cm)=46-59 MeV; 48Ca(48Ca, X), E(cm)=45-63 MeV; 48Ca(110Sn, X), (116Sn, X), (120Sn, X), E(cm)=106-130 MeV; 208Pb(16O, X), E(cm)=69-84 MeV; calculated fusion σ(E), and S factors for 12C reactions using the fully microscopic density constrained time-dependent Hartree-Fock (DC-TDHF) method with the Skyrme SLy5 and SLy5t tensor interactions; deduced that inclusion of tensor interaction has measurable effect on the fusion cross sections.
doi: 10.1103/PhysRevC.100.054612
2019WU09 Phys.Rev. C 100, 014612 (2019) Microscopic studies of production cross sections in multinucleon transfer reaction 58Ni 124Sn NUCLEAR REACTIONS 124Sn(58Ni, X), E(cm)=150, 153, 157, 160.6 MeV; calculated multinucleon transfer and production σ(E) for secondary fragments as function of number of transferred neutrons, energy dependence of the total cross sections integrated over all the neutron transfer channels, total kinetic energy loss, neutron to proton ratio of projectile-like and target-like fragments, transferred nucleon number, and neutron pickup and proton removal transfer probabilities using combined microscopic time-dependent Hartree-Fock (TDHF) and GEMINI++ statistical model approach. Comparison with experimental data.
doi: 10.1103/PhysRevC.100.014612
2018GU20 Phys.Rev. C 98, 064607 (2018) Influence of the tensor force on the microscopic heavy-ion interaction potential NUCLEAR REACTIONS 12C(12C, X), E(cm)=8 MeV; 16O(16O, X), E(cm)=12 MeV; 40Ca(40Ca, X), E(cm)=55 MeV; 40,48Ca(48Ca, X), E(cm)=55 MeV; 56Ni(56Ni, X), E(cm)=105 MeV; 56Ni(48Ca, X), E(cm)=75; 100,116,120Sn(48Ca, X), E(cm)=125 MeV; calculated internuclear potentials with and without Skyrme tensor force using static Hartree-Fock and dynamic density-constrained time-dependent Hartree-Fock (DC-TDHF) theory. Discussed role of tensor force in the fusion of nuclei.
doi: 10.1103/PhysRevC.98.064607
2018GU21 Phys.Rev. C 98, 064609 (2018) Isotopic trends of quasifission and fusion-fission in the reactions 48Ca + 239, 244Pu NUCLEAR REACTIONS 239,244Pu(48Ca, X), E=204.02, 216.76 MeV; calculated time evolution of the mass density of 48Ca+239Pu, contact time, mass and charge of heavy fragments as a function of impact parameter for the tip and side collisions, mass-angle and total kinetic energy-mass distributions of quasi-fission (QF) fragments. Microscopic time-dependent Hartree-Fock (TDHF) method for the fusion and quasifission dynamics with the statistical evaporation model HIVAP for fusion-fission dynamics.
doi: 10.1103/PhysRevC.98.064609
2017CU01 Phys.Rev. C 95, 024323 (2017) J.-W.Cui, X.-R.Zhou, L.-X.Guo, H.-J.Schulze Investigation of single- and double-Λ hypernuclei using a beyond-mean-field approach NUCLEAR STRUCTURE 13,14C, 21,22Ne; calculated levels, J, π of single- and double-hypernuclei with 12C and 20Ne as core nuclei, potential-energy surfaces as functions of deformation parameter β, core B(E2), rms charge radii. Beyond-mean-field approach with angular momentum projection (AMP) techniques and generator coordinate method (GCM) based on Skyrme-Hartree-Fock (SHF). Comparison with experimental data.
doi: 10.1103/PhysRevC.95.024323
2017FR07 Phys.Rev. C 96, 044601 (2017) A.Freese, D.Puentes, S.Adhikari, R.Badui, L.Guo, B.Raue Extraction of t slopes from experimental γp → K+Λ and γp → K+Σ0 cross section data NUCLEAR REACTIONS 1H(γ, K+Λ), (γ, K+Σ0), E=0.91-3.83 GeV; analyzed meson photoproduction data from the CLAS collaboration; deduced Regge trajectories, differential cross sections, and t-slope factor.
doi: 10.1103/PhysRevC.96.044601
2014DA13 Phys.Rev. C 90, 044609 (2014) G.-F.Dai, L.Guo, E.-G.Zhao, S.-G.Zhou Dissipation dynamics and spin-orbit force in time-dependent Hartree-Fock theory NUCLEAR REACTIONS 16O(16O, X), E(cm)=40-220 MeV; calculated relative scattering kinetic energy, energy dissipation, separation density profiles, fusion σ. Time-dependent Hartree-Fock (TDHF) theory. Comparison with experimental data and other calculations.
doi: 10.1103/PhysRevC.90.044609
2014KA30 Phys.Rev.Lett. 113, 022502 (2014) J.Katich, X.Qian, Y.X.Zhao, K.Allada, K.Aniol, J.R.M.Annand, T.Averett, F.Benmokhtar, W.Bertozzi, P.C.Bradshaw, P.Bosted, A.Camsonne, M.Canan, G.D.Cates, C.Chen, J.-P.Chen, W.Chen, K.Chirapatpimol, E.Chudakov, E.Cisbani, J.C.Cornejo, F.Cusanno, M.M.Dalton, W.Deconinck, C.W.de Jager, R.De Leo, X.Deng, A.Deur, H.Ding, P.A.M.Dolph, C.Dutta, D.Dutta, L.El Fassi, S.Frullani, H.Gao, F.Garibaldi, D.Gaskell, S.Gilad, R.Gilman, O.Glamazdin, S.Golge, L.Guo, D.Hamilton, O.Hansen, D.W.Higinbotham, T.Holmstrom, J.Huang, M.Huang, H.F.Ibrahim, M.Iodice, X.Jiang, G.Jin, M.K.Jones, A.Kelleher, W.Kim, A.Kolarkar, W.Korsch, J.J.LeRose, X.Li, Y.Li, R.Lindgren, N.Liyanage, E.Long, H.-J.Lu, D.J.Margaziotis, P.Markowitz, S.Marrone, D.McNulty, Z.-E.Meziani, R.Michaels, B.Moffit, C.Munoz Camacho, S.Nanda, A.Narayan, V.Nelyubin, B.Norum, Y.Oh, M.Osipenko, D.Parno, J.C.Peng, S.K.Phillips, M.Posik, A.J.R.Puckett, Y.Qiang, A.Rakhman, R.D.Ransome, S.Riordan, A.Saha, B.Sawatzky, E.Schulte, A.Shahinyan, M.H.Shabestari, S.Sirca, S.Stepanyan, R.Subedi, V.Sulkosky, L.-G.Tang, A.Tobias, G.M.Urciuoli, I.Vilardi, K.Wang, Y.Wang, B.Wojtsekhowski, X.Yan, H.Yao, Y.Ye, Z.Ye, L.Yuan, X.Zhan, Y.Zhang, Y.-W.Zhang, B.Zhao, X.Zheng, L.Zhu, X.Zhu, X.Zong Measurement of the Target-Normal Single-Spin Asymmetry in Deep-Inelastic Scattering from the Reaction 3He ↑ (e, e')X
doi: 10.1103/PhysRevLett.113.022502
2012AN16 Phys.Rev. C 86, 069801 (2012) M.Anghinolfi, J.Ball, N.A.Baltzell, M.Battaglieri, I.Bedlinskiy, M.Bellis, A.S.Biselli, C.Bookwalter, S.Boiarinov, P.Bosted, V.D.Burkert, D.S.Carman, A.Celentano, S.Chandavar, P.L.Cole, V.Crede, R.De Vita, E.De Sanctis, B.Dey, R.Dickson, D.Doughty, M.Dugger, R.Dupre, H.Egiyan, A.El Alaoui, L.El Fassi, L.Elouadrhiri, P.Eugenio, G.Fedotov, M.Y.Gabrielyan, M.Garcon, G.P.Gilfoyle, K.L.Giovanetti, F.X.Girod, J.T.Goetz, E.Golovatch, M.Guidal, L.Guo, K.Hafidi, H.Hakobyan, D.Heddle, K.Hicks, M.Holtrop, D.G.Ireland, B.S.Ishkhanov, E.L.Isupov, H.S.Jo, P.Khetarpal, A.Kim, W.Kim, V.Kubarovsky, S.V.Kuleshov, H.Y.Lu, I.J.D.MacGregor, N.Markov, M.E.McCracken, B.McKinnon, M.D.Mestayer, C.A.Meyer, M.Mirazita, V.Mokeev, K.Moriya, B.Morrison, A.Ni, S.Niccolai, G.Niculescu, I.Niculescu, M.Osipenko, A.I.Ostrovidov, K.Park, S.Park, S.Anefalos Pereira, S.Pisano, O.Pogorelko, S.Pozdniakov, J.W.Price, G.Ricco, M.Ripani, B.G.Ritchie, P.Rossi, D.Schott, R.A.Schumacher, E.Seder, Y.G.Sharabian, E.S.Smith, D.I.Sober, S.S.Stepanyan, P.Stoler, W.Tang, M.Ungaro, B.Vernarsky, M.F.Vineyard, D.P.Weygand, M.H.Wood, N.Zachariou, B.Zhao Comment on "Observation of a narrow structure in 1H(γ, K0s)X $via interference with φ-meson production"
doi: 10.1103/PhysRevC.86.069801
2012KO17 Phys.Rev. C 85, 054309 (2012) J.Kotila, K.Nomura, L.Guo, N.Shimizu, T.Otsuka Shape phase transitions in the interacting boson model: Phenomenological versus microscopic descriptions NUCLEAR STRUCTURE 148,150,152,154,156,158,160Gd, 150,152,154,156,158,160,162Dy; calculated levels, J, π, B(E2), quadrupole moments for 2+ states, S(2n), potential energy surfaces in β-γ plane, R(first 4+/first 2+) and R(first 6+/second 0+) ratios. Shape phase transitions, X(5) critical-point nuclei. Phenomenological and microscopic proton-neutron interacting boson model (IBM) calculations. Comparison with experimental data.
doi: 10.1103/PhysRevC.85.054309
2012NA28 J.Phys.:Conf.Ser. 387, 012015 (2012) T.Nakatsukasa, S.Ebata, P.Avogadro, L.Guo, T.Inakura, K.Yoshida Density functional approaches to nuclear dynamics NUCLEAR STRUCTURE 120Sn; calculated isoscalar monopole γ strength function. 132,134,136,138,140Xe; calculated B(E1) strength distribution. Density functional approach.
doi: 10.1088/1742-6596/387/1/012015
2011NO04 Phys.Rev. C 83, 041302 (2011); Pub.Note Phys.Rev. C 83, 059901 (2011) K.Nomura, T.Otsuka, N.Shimizu, L.Guo Microscopic formulation of the interacting boson model for rotational nuclei NUCLEAR STRUCTURE 146,148,150,152,154Sm, 230,232,234,236,238U; calculated overlap between the intrinsic state and its rotation angle, and moments of inertia. 146,148,150,152,154Sm, 148,150,152,154,156,158,160Gd, 230Th, 232U; calculated yrast spectra of ground state rotational bands, J, π. Interacting boson model for rotational nuclei with axially symmetric strong deformation. Comparison with experimental data.
doi: 10.1103/PhysRevC.83.041302
2009ZH01 Appl.Radiat.Isot. 67, 46 (2009) G.Zhang, J.Zhang, L.Guo, H.Wu, J.Chen, G.Tang, Yu.M.Gledenov, M.V.Sedysheva, G.Khuukhenkhuu, P.J.Szalanski Measurement of cross sections for the 147Sm(n, α)144Nd reaction at 5.0 and 6.0 MeV NUCLEAR REACTIONS 147Sm(n, α), E=5.0, 6.0 MeV; measured Eα, Iα, cross sections. Compared results to existing data.
doi: 10.1016/j.apradiso.2008.07.005
2008BU02 J.Phys.(London) G35, 025103 (2008) T.J.Burvenich, L.Guo, P.Klupfel, P.-G.Reinhard, W.Greiner Proton-neutron deformations in 16C and their consequences NUCLEAR STRUCTURE 16C; calculated deformation parameters and rms radii mean field models.
doi: 10.1088/0954-3899/35/2/025103
2008GU06 Phys.Rev. C 77, 041301 (2008) L.Guo, J.A.Maruhn, P.-G.Reinhard, Y.Hashimoto Conservation properties in the time-dependent Hartree Fock theory NUCLEAR REACTIONS 16O(16O, X), E(cm)=25, 125 MeV; calculated angular momentum. Hartree-Fock calculations.
doi: 10.1103/PhysRevC.77.041301
2008ZH15 Nucl.Sci.Eng. 160, 123 (2008) G.Zhang, J.Zhang, R.Cao, L.Guo, J.Chen, Yu.M.Gledenov, M.V.Sedysheva, G.Khuukhenkhuu, P.J.Szalanski Measurement of Differential Cross Section for the 64Zn(n, α)61Ni Reaction at 2.54, 4.00, and 5.50 MeV NUCLEAR REACTIONS 64Zn(n, α), E=2.54, 4.00, 5.50 MeV; measured Eα, Iα, σ(θ).
doi: 10.13182/NSE160-123
2008ZH20 Appl.Radiat.Isot. 66, 1427 (2008) G.Zhang, L.Guo, R.Cao, J.Zhang, J.Chen Cross-section measurement for the 10B(n, α)7Li reaction at 4.0 and 5.0 MeV NUCLEAR REACTIONS 10B(n, α), E=4.0, 5.0; 238U(n, F), E=4.0 MeV; measured σ; gridded ionization chamber; comparison with previous results and JENDL-3.3, ENDF/B-VII evaluations.
doi: 10.1016/j.apradiso.2008.07.035
2007GU17 Phys.Rev. C 76, 014601 (2007) L.Guo, J.A.Maruhn, P.-G.Reinhard Boost-invariant mean field approximation and the nuclear Landau-Zener effect
doi: 10.1103/PhysRevC.76.014601
2007GU19 Phys.Rev. C 76, 025208 (2007) L.Guo, for the CLAS Collaboration Cascade production in the reactions γ p → K+K+(X) and γp → K+K+π-(X)
doi: 10.1103/PhysRevC.76.025208
2007GU22 Phys.Rev. C 76, 034317 (2007) L.Guo, J.A.Maruhn, P.-G.Reinhard Triaxiality and shape coexistence in germanium isotopes NUCLEAR STRUCTURE Ge; calculated binding energies, quadrupole and triaxial deformation parameters for ground and coexistent isomeric states using Gogny-HFB and Skyrme-HF plus BCS approximation.
doi: 10.1103/PhysRevC.76.034317
2007GU28 Phys.Rev. C 76, 065801 (2007) L.Guo, M.Hempel, J.Schaffner-Bielich, J.A.Maruhn Triaxial nuclear models and the outer crust of nonaccreting cold neutron stars NUCLEAR STRUCTURE Z=20-48, N=24-110; calculated masses, binding energies, deformations. Comparison with experimental values.
doi: 10.1103/PhysRevC.76.065801
2007RE23 Eur.Phys.J. A 32, 19 (2007) P.-G.Reinhard, L.Guo, J.A.Maruhn Nuclear giant resonances and linear response NUCLEAR STRUCTURE 16O, 40Ca, 100,120,132Sn, 208Pb; calculated isovector dipole and isoscalar quadrupole GR strength distributions using time dependent HF dynamics using Skyrme forces.
doi: 10.1140/epja/i2007-10366-9
2007WE08 Chin.Phys.Lett. 24, 1541 (2007) D.Wei, D.-Z.Xiong, H.-X.Chen, P.-J.Wang, L.Guo, J.Zhang Simultaneous Magneto-Optical Trapping of Fermionic 40K and Bosonic 87Rb Atoms
doi: 10.1088/0256-307X/24/6/030
2006GU16 Int.J.Mod.Phys. E15, 1141 (2006) L.Guo, F.Sakata, E.-G.Zhao, J.A.Maruhn To what extent does the self-consistent mean-field exist?
doi: 10.1142/S0218301306004739
2005GU04 Phys.Rev. C 71, 024315 (2005) Applicability of self-consistent mean-field theory NUCLEAR STRUCTURE 66Se; calculated binding energy, deformation, related features. Analytic condition for applicability of self-consistent mean-field theory derived.
doi: 10.1103/PhysRevC.71.024315
2005GU14 Nucl.Phys. A753, 136 (2005) L.Guo, J.Meng, E.-G.Zhao, F.Sakata Rotational damping in a multi-j shell particles-rotor model
doi: 10.1016/j.nuclphysa.2005.02.106
2004GU13 Nucl.Phys. A740, 59 (2004) Characteristic feature of self-consistent mean-field in level crossing region NUCLEAR STRUCTURE 70,72,74,76Ge; calculated potential energy surfaces, binding energies, deformation parameters, level energies. Constrained Hartree-Fock-Bogoliubov approach, adiabatic assumption.
doi: 10.1016/j.nuclphysa.2004.04.117
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