NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = J.Peng Found 127 matches. Showing 1 to 100. [Next]2022LU01 Phys.Rev. C 105, 024305 (2022) D.W.Luo, C.Xu, Y.K.Wang, Z.H.Li, R.A.Bark, S.Q.Zhang, H.Hua, S.Y.Wang, J.Peng, X.Q.Li, H.Y.Wu, X.Wang, C.G.Wu, Q.T.Li, J.Lin, Y.Jin, W.Z.Xu, L.Mu, J.Meng, F.R.Xu, Y.L.Ye, D.X.Jiang, P.Jones, E.A.Lawrie, P.Papka, M.F.Nkalanga, T.D.Bucher, M.V.Chisapi, L.Msebi, S.Jongile, S.Ntshangase, B.R.Zikhali, S.H.Mthembu, T.Seakamela, M.A.Sithole, O.Shirihda, A.A.Aava, L.Mdletshe, K.L.Malatji, S.Mhlongo, L.Makhathini Collective structures in 62Cu NUCLEAR REACTIONS 54Cr(12C, 3np), E=67 MeV; measured Eγ, Iγ, γ(θ), γγ-coin. 62Cu; deduced levels, J, π, high-spin levels, B(M1)/B(E2), configurations, γγ(linear polarization). Comparison with calculations using the self-consistent tilted axis cranking covariant density functional theory (TAC-C DFT). Comparison with level structures in 60,64Ca. AFRODITE array at the iThemba LABS accelerator facility.
doi: 10.1103/PhysRevC.105.024305
2022PE03 Phys.Rev. C 105, 044318 (2022) Evolution of the chiral rotation mode in rhodium isotopes NUCLEAR STRUCTURE 102,103,104,105,106,107Rh; calculated total Routhian curves, orientation angles for the total angular momentum, B(M1)/B(E2), kinetic and dynamic moments of inertia, rotational bands structure, configurations. Three-dimensional tilted axis cranking calculations with constrained density functional theory (3D-TAC CDFT). Comparison to experimental data.
doi: 10.1103/PhysRevC.105.044318
2022PE16 Phys.Rev. D 106, 063018 (2022) Inverse tritium beta decay with relic neutrinos, solar neutrinos, and a 51Cr source NUCLEAR REACTIONS 3H(ν, e-)3He, E<1 meV; calculated the inverse tritium beta decay (ITBD) reaction from the Sun and 51Cr. The PTOLEMY experiment for the search of relic neutrinos.
doi: 10.1103/PhysRevD.106.063018
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
2021HU26 Phys.Rev. C 104, 064325 (2021) Possible existence of multiple wobbling modes in A ≈ 60 nuclei NUCLEAR STRUCTURE 57,58,59,60,61,62Ni; calculated single-proton and single-neutron energy levels near the Fermi surface of the ground states, potential energy curves, energies, deformation parameters β and γ and the corresponding configurations for wobbling motion in adiabatic and configuration-fixed constrained triaxial covariant density functional theory (CDFT). 62Ni; calculated energies of the lowest bands based on the configuration νg9/22, root mean square angular momentum components along the medium, short, and long axes of the rotor, valence neutrons, and total angular momentum, probability density profiles for the orientation of the angular momentum on the plane for the doublet bands using combination of the covariant density functional theory and quantum particle rotor model; suggested transverse wobbling in semimagic nucleus 62Ni. Comparison with experimental data.
doi: 10.1103/PhysRevC.104.064325
2020PE06 Phys.Lett. B 806, 135489 (2020) Coexistence of planar and aplanar rotations in 195Tl NUCLEAR STRUCTURE 195Tl; analyzed available data; calculated energy spectra as functions of spin for the bands B2 and B2a, potential-energy curves in adiabatic and configuration-fixed constrained triaxial CDFT with PC-PK1.
doi: 10.1016/j.physletb.2020.135489
2020PE12 Phys.Lett. B 810, 135795 (2020) Covariant density functional theory for nuclear chirality in 135Nd NUCLEAR STRUCTURE 135Nd; calculated total Routhian curves as functions of the azimuth angle using 3D-TAC CDFT, B(M1), B(E2). Comparison with available data.
doi: 10.1016/j.physletb.2020.135795
2019AG12 Eur.Phys.J. A 55, 190 (2019) A.C.Aguilar, Z.Ahmed, C.Aidala, S.Ali, V.Andrieux, J.Arrington, A.Bashir, V.Berdnikov, D.Binosi, L.Chang, C.Chen, M.Chen, J.P.B.C.de Melo, M.Diefenthaler, M.Ding, R.Ent, T.Frederico, F.Gao, R.W.Gothe, M.Hattawy, T.J.Hobbs, T.Horn, G.M.Huber, S.Jia, C.Keppel, G.Krein, H.-W.Lin, C.Mezrag, V.Mokeev, R.Montgomery, H.Moutarde, P.Nadolsky, J.Papavassiliou, K.Park, I.L.Pegg, J.-C.Peng, S.Platchkov, S.-X.Qin, K.Raya, P.Reimer, D.G.Richards, C.D.Roberts, J.Rodriguez-Quintero, N.Sato, S.M.Schmidt, J.Segovia, A.Tadepalli, R.Trotta, Z.Ye, R.Yoshida, S.-S.XU Pion and kaon structure at the electron-ion collider
doi: 10.1140/epja/i2019-12885-0
2018HU03 Phys.Rev. A 97, 032516 (2018) Y.-J.Huang, Y.-C.Guan, Y.-C.Huang, T.-H.Suen, J.-L.Peng, L.-B.Wang, J.-T.Shy Frequency measurement of the 2 1S0-31D2 two-photon transition in atomic 4He ATOMIC PHYSICS 4He; measured two-photon spectrum, X-rays; deduced transition frequency, Lamb shift. Comparison with available data.
doi: 10.1103/physreva.97.032516
2018PE09 Phys.Rev. C 98, 024320 (2018) Exploring nuclear multiple chirality in the A ≈ 60 mass region within covariant density functional theory NUCLEAR STRUCTURE 54,56,57,58,59,60Co; calculated single-proton and single-neutron Routhians near the Fermi surface for the ground states, potential energy curves and triaxial deformation parameter γ as functions of β deformation parameter and valence configurations, chiral or multiple chiral doublets. Adiabatic and configuration-fixed constrained triaxial covariant density functional theory (CDFT).
doi: 10.1103/PhysRevC.98.024320
2017PE15 Int.J.Mod.Phys. E26, 1750051 (2017) Interplay between antimagnetic and collective rotation in 58Fe NUCLEAR STRUCTURE 58Fe; calculated single-particle Routhians near the Fermi surface, energy spectra and rotational frequency, B(E2), dynamic moments of inertia.
doi: 10.1142/S0218301317500513
2016LI13 Phys.Rev. C 93, 034309 (2016) H.J.Li, B.Cederwall, M.Doncel, J.Peng, Q.B.Chen, S.Q.Zhang, P.W.Zhao, J.Meng, T.Back, U.Jakobsson, K.Auranen, S.Bonig, M.Drummond, T.Grahn, P.Greenlees, A.Herzan, D.T.Joss, R.Julin, S.Juutinen, J.Konki, T.Kroll, M.Leino, C.McPeake, D.O'Donnell, R.D.Page, J.Pakarinen, J.Partanen, P.Peura, P.Rahkila, P.Ruotsalainen, M.Sandzelius, J.Saren, B.Saygi, C.Scholey, J.Sorri, S.Stolze, M.J.Taylor, A.Thornthwaite, J.Uusitalo, Z.G.Xiao Lifetime measurements in 166Re: Collective versus magnetic rotation NUCLEAR REACTIONS 92Mo(78Kr, n3p), E=380 MeV; measured Eγ, Iγ, recoil-gated γγ-coin, level half-lives by recoil distance Doppler-shift (RDDS) method and differential decay-curve analysis using JUROGAM-II array for γ detection, RITU separator, and GREAT spectrometer at Jyvaskyla accelerator facility. 166Re; deduced high-spin levels, J, π, B(M1), B(E2), B(E1), B(M1)/B(E2) configurations, alignments; discussed collective versus magnetic rotation; calculated total Routhian surface plot. Tilted-axis cranking calculations based on a relativistic mean-field approach (TAC-RMF).
doi: 10.1103/PhysRevC.93.034309
2016PE01 Chin.Phys.Lett. 33, 012101 (2016) Tilted Axis Rotation of 57Mn in Covariant Density Functional Theory NUCLEAR STRUCTURE 57Mn; calculated the energy spectra, total angular momenta, B(E2), B(M1). The self-consistent tilted axis cranking covariant density functional theory.
doi: 10.1088/0256-307X/33/1/012101
2015PE06 Phys.Rev. C 91, 044329 (2015) Magnetic and antimagnetic rotation in 110Cd within tilted axis cranking relativistic mean-field theory NUCLEAR STRUCTURE 110Cd; calculated levels, J, π, B(M1), B(E2), alignments, configurations of the antimagnetic rotational and magnetic rotational (shears) bands. Self-consistent tilted axis cranking relativistic mean-field (TAC-RMF) theory based on a point-coupling interaction.
doi: 10.1103/PhysRevC.91.044329
2015ZH13 Phys.Rev. C 91, 045802 (2015) S.-S.Zhang, J.-P.Peng, M.S.Smith, G.Arbanas, R.L.Kozub Exploration of direct neutron capture with covariant density functional theory inputs NUCLEAR REACTIONS 16O, 36S, 48Ca, 132Sn(n, γ), E<3 MeV; calculated σ(E) using nuclear structure information obtained from a covariant density functional theory as input for the FRESCO coupled reaction channels code; investigated impact of pairing, spectroscopic factors, and optical potentials on direct capture cross sections. Comparison with experimental data. Predictions for neutron capture cross sections for unstable nuclei such as 132Sn.
doi: 10.1103/PhysRevC.91.045802
2014BA29 Int.J.Mod.Phys. E23, 1461001 (2014) R.A.Bark, E.O.Lieder, R.M.Lieder, E.A.Lawrie, J.J.Lawrie, S.P.Bvumbi, N.Y.Kheswa, S.S.Ntshangase, T.E.Madiba, P.L.Masiteng, S.M.Mullins, S.Murray, P.Papka, O.Shirinda, Q.B.Chen, S.Q.Zhang, Z.H.Zhang, P.W.Zhao, C.Xu, J.Meng, D.G.Roux, Z.P.Li, J.Peng, B.Qi, S.Y.Wang, Z.G.Xiao Studies of chirality in the mass 80, 100 and 190 regions NUCLEAR REACTIONS 96Zr(14N, 4n)106Ag, E not given; measured reaction products, Eγ, Iγ; deduced levels, J, π, T1/2, chiral bands, B(M1), B(E2). Comparison with particle-rotor calculations.
doi: 10.1142/S0218301314610011
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
2014LI19 Phys.Rev.Lett. 112, 202502 (2014) E.O.Lieder, R.M.Lieder, R.A.Bark, Q.B.Chen, S.Q.Zhang, J.Meng, E.A.Lawrie, J.J.Lawrie, S.P.Bvumbi, N.Y.Kheswa, S.S.Ntshangase, T.E.Madiba, P.L.Masiteng, S.M.Mullins, S.Murray, P.Papka, D.G.Roux, O.Shirinda, Z.H.Zhang, P.W.Zhao, Z.P.Li, J.Peng, B.Qi, S.Y.Wang, Z.G.Xiao, C.Xu Resolution of Chiral Conundrum in 106Ag: Doppler-Shift Lifetime Investigation NUCLEAR REACTIONS 96Zr(14N, 4n), E=71 MeV; measured reaction products, Eγ, Iγ, γ-γ-coin.; deduced level scheme, J, π, high spin negative parity bands, B(M1), B(E2). Particle-rotor model calculations.
doi: 10.1103/PhysRevLett.112.202502
2014SU20 Phys.Rev. C 90, 054318 (2014) B.H.Sun, Y.Lu, J.P.Peng, C.Y.Liu, Y.M.Zhao New charge radius relations for atomic nuclei NUCLEAR STRUCTURE A=20-225; analyzed rms charge radii for 296 stable isotopes; proposed simple relations for charge radii. Comparisons between predictions and experimental data, and with available theoretical calculations. Shape transition shape coexistence.
doi: 10.1103/PhysRevC.90.054318
2013ME16 Front.Phys.(Beijing) 8, 55 (2013) J.Meng, J.Peng, S.g-Q.Zhang, P.-W.Zhao Progress on tilted axis cranking covariant density functional theory for nuclear magnetic and antimagnetic rotation NUCLEAR STRUCTURE N<160; analyzed available data; deduced magnetic rotations and antimagnetic rotations within in the framework of tilted axis cranking based on the pairing plus quadrupole model.
doi: 10.1007/s11467-013-0287-y
2012ST06 Phys.Rev. C 85, 044316 (2012) D.Steppenbeck, R.V.F.Janssens, S.J.Freeman, M.P.Carpenter, P.Chowdhury, A.N.Deacon, M.Honma, H.Jin, T.Lauritsen, C.J.Lister, J.Meng, J.Peng, D.Seweryniak, J.F.Smith, Y.Sun, S.L.Tabor, B.J.Varley, Y.-C.Yang, S.Q.Zhang, P.W.Zhao, S.Zhu Magnetic rotation and quasicollective structures in 58Fe: Influence of the νγ9/2 orbital NUCLEAR REACTIONS 48Ca(13C, 3n), (14C, 4n), E=130 MeV; measured Eγ, Iγ, γγ-coin, γ(θ), DCO ratios using Gammasphere array at ATLAS, ANL facility. 58Fe; deduced high-spin levels, J, π, multipolarity, bands, magnetic rotational bands, alignment plots, quasicollective structures, configurations. Comparison with shell model calculations, and with self-consistent tilted-axis-cranking calculations within relativistic mean-field theory. NUCLEAR STRUCTURE 58Fe; calculated levels, J, π. Shell-model calculations in fp model space using GXPF1A, KB3G, and FPD6 interactions.
doi: 10.1103/PhysRevC.85.044316
2012ZH09 Eur.Phys.J. A 48, 40 (2012) S.-S.Zhang, X.-D.Xu, J.-P.Peng Hints of giant halo in Zr isotopes by resonant RMF+ACCC+BCS approach NUCLEAR STRUCTURE 82,84,86,88,90,92,94,96,98,100,102,104,106,108,110,112,114,116,118,120,122,124,126,128,130,132,134,136Zr; calculated Q-values, 2n separation energies, neutron radii using RMF + ACCC (analytic continuation in the coupling constant) + BCS approach with NLSH and NL3 effective interactions; deduced hints of halo nuclei at high neutron number.
doi: 10.1140/epja/i2012-12040-7
2012ZH18 Phys.Rev. C 85, 054310 (2012) P.W.Zhao, J.Peng, H.Z.Liang, P.Ring, J.Meng Covariant density functional theory for antimagnetic rotation NUCLEAR STRUCTURE 105Cd; calculated total Routhians, energy spectrum, total angular momenta, kinetic and dynamic moments of inertia, B(E2) values, alignments, Dirac currents, density distribution contours for antimagnetic rotational (AMR) band using tilted-axis cranking and relativistic mean field (TAC-RMF), and TAC with covariant density functional theory (CDFT). Comparison with experimental data.
doi: 10.1103/PhysRevC.85.054310
2011AN07 Eur.Phys.J. A 47, 35 (2011) M.Anselmino, H.Avakian, D.Boer, F.Bradamante, M.Burkardt, J.P.Chen, E.Cisbani, M.Contalbrigo, D.Crabb, D.Dutta, L.Gamberg, H.Gao, D.Hasch, J.Huang, M.Huang, Z.Kang, C.Keppel, G.Laskaris, Z.-T.Liang, M.X.Liu, N.Makins, R.D.Mckeown, A.Metz, Z.-E.Meziani, B.Musch, J.-C.Peng, A.Prokudin, X.Qian, Y.Qiang, J.W.Qiu, P.Rossi, P.Schweitzer, J.Soffer, V.Sulkosky, Y.Wang, B.Xiao, Q.Ye, Q.-J.Ye, F.Yuan, X.Zhan, Y.Zhang, W.Zheng, J.Zhou Transverse-momentum-dependent parton distribution/fragmentation functions at an electron-ion collider
doi: 10.1140/epja/i2011-11035-2
2011CH35 Phys.Rev. C 84, 022501 (2011) P.-H.Chu, A.M.Esler, J.C.Peng, D.H.Beck, D.E.Chandler, S.Clayton, B.-Z.Hu, S.Y.Ngan, C.H.Sham, L.H.So, S.Williamson, J.Yoder Dressed spin of polarized 3He in a cell NUCLEAR MOMENTS 3He; measured modification of effective precession frequency in magnetic field modified by a dressing-field. Zeeman splitting diagrams between dressed and undressed magnetic field. Polarized 3He atoms. Comparison with calculations based on quantum optics formalism. Relevance to neutron electric-dipole moment (EDM) measurements.
doi: 10.1103/PhysRevC.84.022501
2011DU12 Phys.Rev. C 83, 042201 (2011) D.Dutta, J.C.Peng, I.C.Cloet, D.Gaskell Pion-induced Drell-Yan processes and the flavor-dependent EMC effect
doi: 10.1103/PhysRevC.83.042201
2011ZH28 Phys.Rev.Lett. 107, 122501 (2011) P.W.Zhao, J.Peng, H.Z.Liang, P.Ring, J.Meng Antimagnetic Rotation Band in Nuclei: A Microscopic Description NUCLEAR STRUCTURE 105Cd; calculated angular momentum, energy and rotational frequency, B(E2). Covariant density functional theory.
doi: 10.1103/PhysRevLett.107.122501
2011ZH57 Phys.Lett. B 699, 181 (2011) P.W.Zhao, S.Q.Zhang, J.Peng, H.Z.Liang, P.Ring, J.Meng Novel structure for magnetic rotation bands in 60Ni NUCLEAR STRUCTURE 60Ni; calculated energy spectra, total angular momenta, evolution of deformation parameters, B(M1), B(E2), B(M1)/B(E2) ratios; deduced systematics of the newly observed shears bands. The self-consistent tilted axis cranking relativistic mean-field theory based on a point-coupling interaction.
doi: 10.1016/j.physletb.2011.03.068
2010ME09 Nucl.Phys. A834, 436c (2010) J.Meng, Z.P.Li, H.Z.Liang, Z.M.Niu, J.Peng, B.Qi, B.Sun, S.Y.Wang, J.M.Yao, S.Q.Zhang Covariant Density Functional Theory for Nuclear Structure and Application in Astrophysics NUCLEAR STRUCTURE 144,146,148,150,152,154,156Nd; calculated levels, J, π, B(E2), mass excess using covariant density functional theory. Comparison with data.
doi: 10.1016/j.nuclphysa.2010.01.058
2010PE11 Chin.Phys.Lett. 27, 122101 (2010) J.Peng, J.-M.Yao, S.-Q.Zhang, J.Meng Exotic Magnetic Rotation in 22F NUCLEAR STRUCTURE 22F; calculated total routhians and angular momentum, B(M1), B(E2); deduced the possible existence of magnetic rotation.
doi: 10.1088/0256-307X/27/12/122101
2010PE16 Nucl.Phys. A844, 196c (2010) Flavor symmetries of parton distributions
doi: 10.1016/j.nuclphysa.2010.05.035
2009PE03 Chin.Phys.Lett. 26, 032101 (2009) Nuclear Current and Magnetic Rotation NUCLEAR STRUCTURE 142Gd; calculated single particle energies, B(E2), B(M1).
doi: 10.1088/0256-307X/26/3/032101
2009PE30 Chin.Phys.C 33, Supplement 1, 15 (2009) Shears mechanism in two-dimensional cranking relativistic mean field approach NUCLEAR STRUCTURE 142Gd; calculated angular momentum of the valence nucleons; deduced shears mechanism. RMF calculations.
doi: 10.1088/1674-1137/33/S1/005
2009QI11 Chin.Phys.C 33, Supplement 1, 43 (2009) B.Qi, J.Meng, S.-Q.Zhang, S.-Y.Wang, J.Peng Chiral doublet bands and energy-level crossing NUCLEAR STRUCTURE 128Cs, 134Pr; calculated energy spectra, B(E2), B(M1); deduced chiral bands. Comparison with experimental data.
doi: 10.1088/1674-1137/33/S1/014
2009YA09 Phys.Rev. C 79, 067302 (2009) J.M.Yao, B.Qi, S.Q.Zhang, J.Peng, S.Y.Wang, J.Meng Candidate multiple chiral doublets nucleus 106Rh in a triaxial relativistic mean-field approach with time-odd fields NUCLEAR STRUCTURE 106Rh; calculated potential energy surfaces, triaxial deformation parameters, and energy contributions from time-odd fields and center of mass corrections using the configuration-fixed constrained triaxial relativistic mean-field approach. Implications and predictions for chiral doublet bands.
doi: 10.1103/PhysRevC.79.067302
2009ZH13 Chin.Phys.Lett. 26, 052101 (2009) Description of 178Hfm2 in the Constrained Relativistic Mean Field Theory NUCLEAR STRUCTURE 178Hf; calculated binding energy, deformation, level energies for ground and high-spin isomeric states. Adiabatic and diabatic constrained relativistic mean field (RMF) approaches.
doi: 10.1088/0256-307X/26/5/052101
2008PE05 Phys.Rev. C 77, 024309 (2008) J.Peng, H.Sagawa, S.Q.Zhang, J.M.Yao, Y.Zhang, J.Meng Search for multiple chiral doublets in rhodium isotopes NUCLEAR STRUCTURE 102,104,106,108,110Rh; calculated triaxial deformation parameters, energy surfaces, configurations, chiral doublets. Triaxial relativistic mean field approach.
doi: 10.1103/PhysRevC.77.024309
2008PE24 Phys.Rev. C 78, 024313 (2008) J.Peng, J.Meng, P.Ring, S.Q.Zhang Covariant density functional theory for magnetic rotation NUCLEAR STRUCTURE 142Gd; calculated deformation parameters, proton and neutron angular momenta, B(M1), B(E2), total Routhians of magnetic rotation. Relativistic mean field theory with tilted axis cranking formalism. Comparison with experimental data.
doi: 10.1103/PhysRevC.78.024313
2008WA08 Phys.Rev. C 77, 034314 (2008) S.Y.Wang, S.Q.Zhang, B.Qi, J.Peng, J.M.Yao, J.Meng Description of π g9/2 (X) νh11/2 doublet bands in 106Rh NUCLEAR STRUCTURE 106Rh; calculated excitation energies, B(M1), B(E2) for negative parity doublet bands using particle-rotor model with triaxial relativistic mean-field approach.
doi: 10.1103/PhysRevC.77.034314
2008XU08 Phys.Rev. C 78, 064301 (2008) Q.Xu, S.J.Zhu, J.H.Hamilton, A.V.Ramayya, J.K.Hwang, B.Qi, J.Meng, J.Peng, Y.X.Luo, J.O.Rasmussen, I.Y.Lee, S.H.Liu, K.Li, J.G.Wang, H.B.Ding, L.Gu, E.Y.Yeoh, W.C.Ma Identification of pseudospin partner bands in 108Tc RADIOACTIVITY 252Cf(SF); measured Eγ, Iγ, γγ-coin. 108Tc; deduced levels, J, π, bands, B(E1)/B(E2) ratios. 106,107Mo, 107Tc; deduced bands. Comparison with particle-rotor model calculations.
doi: 10.1103/PhysRevC.78.064301
2007BA82 Eur.Phys.J. Special Topics 150, 139 (2007) S.F.Ban, L.S.Geng, W.H.Long, J.Meng, J.Peng, J.M.Yao, S.Q.Zhang, S.G.Zhou Structure of nuclei far from the stability in relativistic approach
doi: 10.1140/epjst/e2007-00288-2
2007ES07 Phys.Rev. C 76, 051302 (2007) A.Esler, J.C.Peng, D.Chandler, D.Howell, S.K.Lamoreaux, C.Y.Liu, J.R.Torgerson Dressed spin of 3He NUCLEAR MOMENTS 3He; measured precessional frequency in magnetic field; deduced dressed spin effects of polarized 3He. Proposed measurement for neutron electric dipole moment.
doi: 10.1103/PhysRevC.76.051302
2007GA57 Few-Body Systems 41, 43 (2007) H.Gao, J.P.Chen, E.Cisbani, X.Jiang, J.C.Peng, X.Qian, L.Y.Zhu Neutron transversity measurement at Jefferson Lab with a polarized 3He target
doi: 10.1007/S00601-007-0186-2
2006BA71 Int.J.Mod.Phys. E15, 1447 (2006) S.F.Ban, L.S.Geng, L.Liu, W.H.Long, J.Meng, J.Peng, J.M.Yao, S.Q.Zhang, S.G.Zhou Recent progress in relativistic many-body approach
doi: 10.1142/S0218301306005010
2006ME06 Phys.Rev. C 73, 037303 (2006) J.Meng, J.Peng, S.Q.Zhang, S.-G.Zhou Possible existence of multiple chiral doublets in 106Rh NUCLEAR STRUCTURE 106Rh; calculated single-particle energies, binding energies and deformation parameters for several configurations; deduced possible chiral doublets. 100,102,104,106,108,110,112,114,116,118In, 102,104,106,108,110,112Ag, 98,100,102,104,106,108,110,112,114Rh; calculated ground-state deformation parameters. Constrained triaxial relativistic mean field.
doi: 10.1103/PhysRevC.73.037303
2005UU01 J.Phys.(London) G31, B1 (2005) Y.-N.U, S.J.Zhu, M.Sakhaee, L.M.Yang, C.Y.Gan, L.Y.Zhu, R.Q.Xu, X.L.Che, M.L.Li, Y.J.Chen, S.X.Wen, X.G.Wu, L.H.Zhu, G.S.Li, J.Peng, S.Q.Zhang, J.Meng Search for the chiral doublet bands in 122Cs NUCLEAR REACTIONS 107Ag(19F, 3np), E=85 MeV; measured Eγ, Iγ, γγ-coin. 122Cs deduced high-spin levels, J, π, configurations, B(M1)/B(E2), chiral doublet bands. Level systematics in neighboring isotopes compared.
doi: 10.1088/0954-3899/31/3/B01
2003AH09 Phys.Rev. C 68, 064004 (2003) M.W.Ahmed, X.Cui, A.Empl, E.V.Hungerford, K.J.Lan, M.Youn, R.E.Chrien, R.Gill, P.Pile, A.Rusek, R.Sutter, J.Bjoraker, D.Dehnhard, J.M.O'Donnell, J.Gerald, H.Juengst, J.H.Liu, J.C.Peng, C.L.Morris, C.M.Riedel, H.A.Thiessen, D.Androic, I.Bertovic, M.Furic, T.Petkovic, M.Planinic, L.Tang, V.Zeps Experimental study of the 12C(K-stopped, π0)12ΛB reaction NUCLEAR REACTIONS 12C(K-, π0), E at rest; measured pion spectra; deduced hypernucleus production ground and excited state branching ratios. 12B deduced hyperon binding energy.
doi: 10.1103/PhysRevC.68.064004
2003CH78 Phys.Rev.Lett. 91, 211801 (2003) T.H.Chang, M.E.Beddo, C.N.Brown, T.A.Carey, W.E.Cooper, C.A.Gagliardi, G.T.Garvey, D.F.Geesaman, E.A.Hawker, X.C.He, L.D.Isenhower, D.M.Kaplan, S.B.Kaufman, D.D.Koetke, P.L.McGaughey, W.M.Lee, M.J.Leitch, J.M.Moss, B.A.Mueller, V.Papavassiliou, J.C.Peng, P.E.Reimer, M.E.Sadler, W.E.Sondheim, P.W.Stankus, R.S.Towell, R.E.Tribble, M.A.Vasiliev, J.C.Webb, J.L.Willis, G.R.Young, and the FNAL E866/NuSea Collaboration J/ψ Polarization in 800-GeV p-Cu Interactions NUCLEAR REACTIONS Cu(p, X), E=800 GeV; measured J/ψ polarization parameter vs xF, transverse momentum.
doi: 10.1103/PhysRevLett.91.211801
2003GA05 Phys.Rev.Lett. 90, 092302 (2003) Partonic Energy Loss and the Drell-Yan Process NUCLEAR REACTIONS 2H, W(p, X), E=50, 120 GeV; calculated relative Drell-Yan yields, effect of parton energy loss.
doi: 10.1103/PhysRevLett.90.092302
2003PE16 Chin.Phys.Lett. 20, 1223 (2003) Breaking of Chiral Symmetry in 104Rh and Its Neighbouring Nuclei NUCLEAR STRUCTURE 104Rh; calculated rotational band energies, B(E2), B(M1), deformation, chiral doublet structure. 106,108Rh, 110Ag; calculated rotational band energies. Triaxial particle-rotor model, comparison with data.
doi: 10.1088/0256-307X/20/8/311
2003PE28 Phys.Rev. C 68, 044324 (2003) Description of chiral doublets in A ∼ 130 nuclei and the possible chiral doublets in A ∼ 100 nuclei NUCLEAR STRUCTURE 130Cs, 132La, 134Pr, 136Pm, 104Rh; calculated rotational band energies, B(M1), B(E2), deformation, chiral doublets. Particle-rotor model.
doi: 10.1103/PhysRevC.68.044324
2003PE32 Eur.Phys.J. A 18, 395 (2003) Flavor structure of the nucleon sea
doi: 10.1140/epja/i2002-10243-1
2002JO02 Phys.Rev. C65, 025203 (2002) M.B.Johnson, B.Z.Kopeliovich, I.K.Potashnikova, P.L.McGaughey, J.M.Moss, J.C.Peng, G.Garvey, M.Leitch, C.N.Brown, D.M.Kaplan Energy Loss versus Shadowing in the Drell-Yan Reaction on Nuclei NUCLEAR REACTIONS 2H, Be, C, Ca, Fe, W(p, X), E at 800 GeV/c; analyzed Drell-Yan production σ; deduced energy loss effects, other reaction mechanism features.
doi: 10.1103/PhysRevC.65.025203
2002RA41 Phys.Rev. D66, 034024 (2002) J.Raufeisen, J.C.Peng, G.C.Nayak Parton model versus color dipole formulation of the Drell-Yan process NUCLEAR REACTIONS 1,2H(p, μ+μ-X), E=high; calculated σ(E, θ). Color dipole approach, comparison with parton model.
doi: 10.1103/PhysRevD.66.034024
2001GA58 Prog.Part.Nucl.Phys. 47, 203 (2001) Flavor Asymmetry of Light Quarks in the Nucleon Sea
doi: 10.1016/S0146-6410(01)00155-7
2001JO09 Phys.Rev.Lett. 86, 4483 (2001) M.B.Johnson, B.Z.Kopeliovich, I.K.Potashnikova, P.L.McGaughey, J.M.Moss, J.C.Peng, G.T.Garvey, M.J.Leitch, M.R.Adams, D.M.Alde, H.W.Baer, M.L.Bartlett, C.N.Brown, W.E.Cooper, T.A.Carey, G.Danner, G.W.Hoffmann, Y.B.Hsiung, D.M.Kaplan, A.Klein, C.Lee, J.W.Lillberg, R.L.McCarthy, C.S.Mishra, M.J.Wang, and the FNAL E772 Collaboration Energy Loss of Fast Quarks in Nuclei NUCLEAR REACTIONS 2H, C, Ca, Fe, W(p, X), E at 800 GeV/c; measured dimuon Drell-Yan yields; deduced quark energy loss in nuclear environment.
doi: 10.1103/PhysRevLett.86.4483
2001PE07 Nucl.Phys. A684, 80c (2001) Flavor Asymmetry of the Nucleon Sea
doi: 10.1016/S0375-9474(01)00491-2
2001TI01 Phys.Rev. D63, 052001 (2001) W.B.Tippens, V.Abaev, M.Batinic, V.Bekrenev, W.J.Briscoe, R.E.Chrien, M.Clajus, D.Isenhower, N.Kozlenko, S.Kruglov, M.J.Leitch, A.Marusic, T.Moriwaki, T.Morrison, B.M.K.Nefkens, J.C.Peng, P.H.Pile, J.W.Price, D.Rigsby, M.E.Sadler, R.Sawafta, I.Slaus, H.Seyfarth, A.Starostin, I.Supek, R.J.Sutter, A.Svarc, D.B.White Measurement of Charge Symmetry Breaking by the Comparison of π+d → ppη with π-d → nnη NUCLEAR REACTIONS 2H(π+, 2pX), (π-, 2nX), E at 655-752 MeV/c; measured η meson production associated invariant mass spectra, σ; deduced charge symmetry breaking features.
doi: 10.1103/PhysRevD.63.052001
1999MC07 Ann.Rev.Nucl.Part.Sci. 49, 217 (1999) P.L.McGaughey, J.M.Moss, J.C.Peng High-Energy Hadron-Induced Dilepton Production from Nucleons and Nuclei
doi: 10.1146/annurev.nucl.49.1.217
1999VA12 Phys.Rev.Lett. 83, 2304 (1999) M.A.Vasiliev, M.E.Beddo, C.N.Brown, T.A.Carey, T.H.Chang, W.E.Cooper, C.A.Gagliardi, G.T.Garvey, D.F.Geesaman, E.A.Hawker, X.C.He, L.D.Isenhower, D.M.Kaplan, S.B.Kaufman, D.D.Koetke, W.M.Lee, M.J.Leitch, P.L.McGaughey, J.M.Moss, B.A.Mueller, V.Papavassiliou, J.C.Peng, G.Petitt, P.E.Reimer, M.E.Sadler, W.E.Sondheim, P.W.Stankus, R.S.Towell, R.E.Tribble, J.C.Webb, J.L.Willis, G.R.Young, and the FNAL E866/NuSea Collaboration Parton Energy Loss Limits and Shadowing in Drell-Yan Dimuon Production NUCLEAR REACTIONS Be, Fe, W(p, X), E at 800 GeV/c; measured Drell-Yan production σ per nucleon; deduced role of nuclear shadowing.
doi: 10.1103/PhysRevLett.83.2304
1996BR32 Phys.Rev. C54, 3195 (1996) C.N.Brown, W.E.Cooper, C.S.Mishra, D.M.Kaplan, R.S.Preston, V.Tanikella, L.D.Isenhower, M.E.Sadler, L.M.Lederman, M.H.Schub, G.Gidal, M.S.Kowitt, K.B.Luk, T.A.Carey, M.J.Leitch, P.L.McGaughey, J.M.Moss, J.C.Peng, R.L.Childers, C.W.Darden, P.K.Teng Nuclear Dependence of Single-Hadron and Dihadron Production in p-A Interactions at √ s = 38.8 GeV NUCLEAR REACTIONS W, 9Be(p, X), E=800 GeV; measured single hadron, dihadron production associated per nucleon σ ratio; deduced kinematic variables dependence of nuclear effects.
doi: 10.1103/PhysRevC.54.3195
1996LE14 Phys.Rev. D52, 4251 (1996) M.J.Leitch, C.N.Brown, T.A.Carey, R.Childers, W.E.Cooper, C.W.Darden, G.Gidal, K.N.Gounder, L.D.Isenhower, D.M.Jansen, R.G.Jeppesen, D.M.Kaplan, J.S.Kapustinsky, M.S.Kowitt, D.W.Lane, L.M.Lederman, J.W.Lillberg, K.B.Luk, V.M.Martin, P.L.McGaughey, C.S.Mishra, J.M.Moss, J.C.Peng, R.S.Preston, J.Sa, M.E.Sadler, R.Schnathorst, M.H.Schub, V.Tanikella, P.K.Teng Nuclear Dependence of J/ψ Production by 800 GeV/c Protons Near x(F) = 0 NUCLEAR REACTIONS 9Be, C, W(p, X), E at 800 GeV/c; measured dimuon mass spectra; deduced nuclear dependence of J/ψ production at x(F) ≈ 0.
doi: 10.1103/PhysRevD.52.4251
1996LE22 Nucl.Instrum.Methods Phys.Res. A374, 299 (1996) M.J.Leitch, M.E.Anderson, J.Kapustinsky, T.K.Li, C.S.Mishra, J.C.Peng, J.E.Simmons, S.A.Dytman, J.G.Hardie, K.F.Von Reden, C.Smith Performance of a BGO-NaI η Spectrometer NUCLEAR REACTIONS 1H(π-, X), E at 200, 698 MeV/c; measured missing mass, invariant mass spectra for π0, η production. Performance of two-arm spectrometer with BGO actiuve converters discussed.
doi: 10.1016/0168-9002(96)00181-7
1995DY01 Phys.Rev. C51, 2710 (1995) S.A.Dytman, W.W.Daehnick, J.G.Hardie, M.Yamazaki, E.Booth, J.Miller, M.J.Leitch, C.S.Mishra, J.C.Peng, D.R.Tieger, K.F.von Reden Study of Baryon Resonances Through γp → (Eta)p Differential Cross Sections NUCLEAR REACTIONS 1H(γ, X), E=729, 753 MeV; measured σ(θ) for eta production; analyzed σ(E); deduced deviations from S11(1535)N(*) resonance dominance picture.
doi: 10.1103/PhysRevC.51.2710
1995JA05 Phys.Rev.Lett. 74, 3118 (1995) D.M.Jansen, M.H.Schub, C.S.Mishra, P.M.Ho, C.N.Brown, T.A.Carey, Y.C.Chen, R.Childers, W.E.Cooper, C.W.Darden, G.Gidal, K.N.Gounder, L.D.Isenhower, R.G.Jeppesen, D.M.Kaplan, J.S.Kapustinsky, G.C.Kiang, M.S.Kowitt, D.W.Lane, L.M.Lederman, M.J.Leitch, J.W.Lillberg, W.R.Luebke, K.B.Luk, P.L.McGaughey, J.M.Moss, J.C.Peng, R.S.Preston, D.Pripstein, J.Sa, M.E.Sadler, R.Schnathorst, V.Tanikella, P.K.Teng, J.R.Wilson Measurement of the Bottom-Quark Production Cross Section in 800 GeV/c Proton-Gold Collisions NUCLEAR REACTIONS 197Au(p, X), E at 800 GeV/c; measured dimuon invariant mass distribution; deduced bottom quark decay features, production σ.
doi: 10.1103/PhysRevLett.74.3118
1995PE05 Phys.Lett. 344B, 1 (1995) J.C.Peng, D.M.Jansen, Y.C.Chen Probing (u-bar)/(d-bar) Asymmetry in the Proton Via Quarkonium Production NUCLEAR REACTIONS Cu(p, X), E=800 GeV; analyzed J/psi, Y production data; deduced u-bar/d-bar asymmetry dependence.
doi: 10.1016/0370-2693(94)01466-P
1995PE15 Phys.Lett. 354B, 460 (1995) Probing (u-bar)/(d-bar) Asymmetry in the Proton Via W and Z Production NUCLEAR REACTIONS 2,1H(p, X), E=high; calculated W+, W- and W+, Z production σ ratio; deduced sensitivity to (u-bar)/(d-bar) asymmetry in proton.
doi: 10.1016/0370-2693(95)00652-2
1995SC56 Phys.Rev. D52, 1307 (1995) M.H.Schub, D.M.Jansen, C.S.Mishra, P.M.Ho, C.N.Brown, T.A.Carey, Y.C.Chen, R.Childers, W.E.Cooper, C.W.Darden, G.Gidal, K.N.Gounder, L.D.Isenhower, R.G.Jeppesen, D.M.Kaplan, J.S.Kapustinsky, G.C.Kiang, M.S.Kowitt, D.W.Lane, L.M.Lederman, M.J.Leitch, J.W.Lillberg, W.R.Luebke, K.B.Luk, P.L.McGaughey, J.M.Moss, J.C.Peng, R.S.Preston, D.Pripstein, J.Sa, M.E.Sadler, R.Schnathorst, V.Tanikella, P.K.Teng, J.R.Wilson Measurement of J/ψ and ψ' Production in 800 GeV/c Proton-Gold Collisions NUCLEAR REACTIONS 197Au(p, X), E at 800 GeV/c; measured J/ψ, ψ' production associated differential σ vs Feynman-x.
doi: 10.1103/PhysRevD.52.1307
1994KO14 Phys.Rev.Lett. 72, 1318 (1994) M.S.Kowitt, G.Gidal, P.M.Ho, K.B.Luk, D.Pripstein, L.D.Isenhower, M.E.Sadler, R.Schnathorst, R.Schwint, L.M.Lederman, M.H.Schub, C.N.Brown, W.E.Cooper, H.D.Glass, K.N.Gounder, C.S.Mishra, J.Boissevain, T.A.Carey, D.M.Jansen, R.G.Jeppesen, J.S.Kapustinsky, D.W.Lane, M.J.Leitch, J.W.Lillberg, P.L.McGaughey, J.M.Moss, J.C.Peng, D.M.Kaplan, W.R.Luebke, V.M.Martin, R.S.Preston, J.Sa, V.Tanikella, R.L.Childers, C.W.Darden, J.R.Wilson, G.C.Kiang, P.K.Teng, Y.C.Chen Production of J/(Psi) at Large x(F) in 800 GeV/c p-Copper and p-Beryllium Collisions
doi: 10.1103/PhysRevLett.72.1318
1994LE09 Phys.Rev.Lett. 72, 2542 (1994) M.J.Leitch, J.Boissevain, T.A.Carey, D.M.Jansen, R.G.Jeppesen, J.S.Kapustinsky, D.W.Lane, J.W.Lillberg, P.L.McGaughey, J.M.Moss, J.C.Peng, L.D.Isenhower, M.E.Sadler, R.Schnathorst, G.Gidal, P.M.Ho, M.S.Kowitt, K.B.Luk, D.Pripstein, L.M.Lederman, M.H.Schub, C.N.Brown, W.E.Cooper, H.D.Glass, K.N.Gounder, C.S.Mishra, D.M.Kaplan, W.R.Luebke, V.M.Martin, R.S.Preston, J.Sa, V.Tanikella, R.Childers, C.W.Darden, J.R.Wilson, Y.C.Chen, G.C.Kiang, P.K.Teng Nuclear Dependence of Neutral-D-Meson Production by 800 GeV/c Protons NUCLEAR REACTIONS 9Be, 197Au(p, X), E at 800 GeV/c; measured neutral D-meson production differential σ; deduced nuclear dependence features.
doi: 10.1103/PhysRevLett.72.2542
1992BA03 Phys.Rev. C45, 293 (1992) D.B.Barlow, B.M.K.Nefkens, C.Pillai, J.W.Price, I.Slaus, M.J.Wang, J.A.Wightman, K.W.Jones, M.J.Leitch, C.S.Mishra, C.L.Morris, J.-C.Peng, P.K.Teng, J.M.Tinsley 3He and 4He Production by 800 MeV Protons from 12C, Ti, and Pb at Forward Angles NUCLEAR REACTIONS 12C, Ti, Pb(p, X)3He/4He, E=800 MeV; measured σ(θ) vs momentum for 4,3He; deduced 3,4He production σ ratio, reaction mechanism.
doi: 10.1103/PhysRevC.45.293
1991PI07 Phys.Rev.Lett. 66, 2585 (1991) P.H.Pile, S.Bart, R.E.Chrien, D.J.Millener, R.J.Sutter, N.Tsoupas, J.-C.Peng, C.S.Mishra, E.V.Hungerford, T.Kishimoto, L.-G.Tang, W.von Witsch, Z.Xu, K.Maeda, D.Gill, R.McCrady, B.Quinn, J.Seydoux, J.W.Sleight, R.L.Stearns, H.Plendl, A.Rafatian, J.Reidy Study of Hypernuclei by Associated Production NUCLEAR REACTIONS 9Be, 12C, 16O, 28Si, 40Ca, 51V, 89Y(π+, K+), E at 1048 MeV/c; measured σ(θ); deduced hypernuclei production σ, binding energies.
doi: 10.1103/PhysRevLett.66.2585
1989PE12 Phys.Rev.Lett. 63, 2353 (1989) J.C.Peng, M.J.Leitch, J.D.Bowman, F.Irom, J.Kapustinsky, T.K.Li, L.C.Liu, C.S.Mishra, J.E.Simmons, Z.F.Wong, C.Smith, R.R.Whitney Coherent Eta-Meson Production in the Reaction π- + 3He → Eta + t NUCLEAR REACTIONS 3He(π-, t), (π+, t), E at 650, 620 MeV/c; measured eta production σ(θ); deduced eta production mechanism.
doi: 10.1103/PhysRevLett.63.2353
1988BR06 Phys.Rev. C37, 1345 (1988) G.Bruge, D.Garreta, P.Birien, H.Catz, A.Chaumeaux, S.Janouin, D.Legrand, M.C.Lemaire, B.Mayer, J.Pain, F.Perrot, E.Aslanides, O.Bing, D.M.Drake, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, J.Lichtenstadt, A.I.Yavin Elastic Scattering of 179.3 MeV Antiprotons by Deuterium NUCLEAR REACTIONS 2H(p-bar, p-bar), E=179.3 MeV; measured σ(θ).
doi: 10.1103/PhysRevC.37.1345
1987AS06 Nucl.Phys. A470, 445 (1987) E.Aslanides, D.M.Drake, J.C.Peng, D.Garreta, P.Birien, G.Bruge, H.Catz, A.Chaumeaux, S.Janouin, D.Legrand, M.-C.Lemaire, B.Mayer, J.Pain, F.Perrot, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, O.Bing, J.Lichtenstadt, A.I.Yavin Search for p-bar-Nucleus States using the (p-bar, p) Knock-Out Reaction at 600 MeV/c NUCLEAR REACTIONS 1,2H, 6Li, 12C, 63Cu, 208Pb, 209Bi(p-bar, p), E=180 MeV; measured σ(Ep, θ=0°); deduced temperatures, proton production σ, mass dependence, effective proton number, quasifree σ(θ=0°).
doi: 10.1016/0375-9474(87)90580-X
1987PE05 Phys.Rev.Lett. 58, 2027 (1987) J.C.Peng, J.Kapustinsky, C.Lee, M.J.Leitch, T.K.Li, C.Liu, J.M.Moss, J.E.Simmons, S.M.Tang, C.Smith, R.R.Whitney Observation of Eta-Meson Production in the Reaction π- + 3He → Eta + t NUCLEAR REACTIONS 3He(π-, t), E at 680 MeV/c; measured triton spectra; deduced eta-meson production σ. Large acceptance spectrometer.
doi: 10.1103/PhysRevLett.58.2027
1987RI06 Phys.Lett. 197B, 23 (1987) P.J.Riley, M.Bachman, C.L.Hollas, K.H.McNaughton, S.-W.Xu, B.E.Bonner, O.B.Van Dyck, J.McGill, M.W.McNaughton, J.C.Peng, R.R.Silbar, J.Dubach, W.M.Kloet Polarization Observables for the Reaction pp → ppπ0 at 800 MeV NUCLEAR REACTIONS 1H(polarized p, pπ0), E=647, 733, 800 MeV; measured induced polarization, analyzing power, Wolfenstein parameters. Orthogonal beam polarization.
doi: 10.1016/0370-2693(87)90334-0
1986BR04 Phys.Lett. 169B, 14 (1986) G.Bruge, A.Chaumeaux, P.Birien, D.M.Drake, D.Garreta, S.Janouin, D.Legrand, M.C.Lemaire, B.Mayer, J.Pain, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.Aslanides, O.Bing, J.Lichtenstadt, A.I.Yavin, J.C.Peng Comparative Study of the Elastic Scattering of 178.4 MeV Antiprotons by the 16O and 18O Isotopes NUCLEAR REACTIONS 16,18O(p-bar, p-bar), E=178.4 MeV; measured σ(θ); deduced optical model parameters, neutron excess role.
doi: 10.1016/0370-2693(86)90676-3
1986CI06 Nucl.Phys. A459, 438 (1986) N.Cindro, D.Pocanic, D.M.Drake, J.D.Moses, J.C.Peng, N.Stein, J.W.Sunier Elastic Scattering of 28Si on 24Mg and 26Mg NUCLEAR REACTIONS 26,24Mg(28Si, 28Si), E=74.5-83 MeV; 24Mg(28Si, 24Mg), (28Si, 26Mg), E=83 MeV; measured σ(θ), σ(E); deduced intermediate structure.
doi: 10.1016/0375-9474(86)90144-2
1986DA15 Phys.Rev. C34, 815 (1986) W.W.Daehnick, R.E.Brown, E.R.Flynn, R.A.Hardekopf, J.C.Peng Analyzing Powers for 207Pb(t(pol), p)209Pb at 17 MeV as Evidence for Multistep Contributions NUCLEAR REACTIONS 207Pb(polarized t, p), E=17 MeV; measured σ(Ep), σ(θ), A(θ); deduced reaction mechanism, model parameters. 209Pb levels deduced L, transfer j, spectroscopic amplitudes, σ. DWBA analysis.
doi: 10.1103/PhysRevC.34.815
1986JA04 Nucl.Phys. A451, 541 (1986) S.Janouin, M.-C.Lemaire, D.Garreta, P.Birien, G.Bruge, D.M.Drake, D.Legrand, B.Mayer, J.Pain, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.Aslanides, O.Bing, J.Lichtenstadt, A.I.Yavin Optical-Model Analysis of Antiproton-Nucleus Elastic Scattering at 50 and 180 MeV NUCLEAR REACTIONS 12C, 40Ca, 208Pb(p-bar, p-bar), E ≈ 50, 180 MeV; 16,18O(p-bar, p-bar), E=178.4 MeV; analyzed σ(θ); deduced reaction σ, potential parameters.
doi: 10.1016/0375-9474(86)90291-5
1986LE13 Nucl.Phys. A456, 557 (1986) M.-C.Lemaire, P.Birien, G.Bruge, D.M.Drake, D.Garreta, S.Janouin, D.Legrand, B.Mayer, J.Pain, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.L.Aslanides, O.Bing, J.Lichtenstadt, A.I.Yavin Inelastic Scattering of Antiprotons from 12C and 18O at 50 and 180 MeV NUCLEAR REACTIONS 18O, 12C(p-bar, p-bar), (p-bar, p-bar'), E=46.7, 179.7, 178.4 MeV; measured σ(θ); deduced potential parameters. 12C deduced quadrupole deformation parameters, deformation lengths, B(λ), δ. 18O deduced quadrupole, hexadecapole deformation lengths.
doi: 10.1016/0375-9474(86)90075-8
1985BE31 Phys.Lett. 158B, 19 (1985) R.Bertini, P.Birien, K.Braune, W.Bruckner, G.Bruge, H.Catz, A.Chaumeaux, J.Ciborowski, H.Dobbeling, J.M.Durand, R.W.Frey, D.Garreta, S.Janouin, T.J.Ketel, K.Kilian, H.Kneis, S.Majewski, B.Mayer, J.C.Peng, B.Povh, R.D.Ransome, R.Szwed, T.-A.Shibata, A.Thiessen, M.Treichel, M.Uhrmacher, Th.Walcher, and the Heidelberg-Saclay Collaboration The (K-, π+) Strangeness Exchange Reaction on 16O NUCLEAR REACTIONS 12C, 16O(K-, π+), E at 450 MeV/c; measured σ(E(π)); deduced Σ hypernuclear states.
doi: 10.1016/0370-2693(85)90730-0
1985CO22 Z.Phys. A322, 491 (1985) M.D.Cohler, R.Wadsworth, S.M.Lane, D.L.Watson, M.J.Smithson, R.E.Brown, D.M.Drake, N.Stein, J.-C.Peng, J.W.Sunier Investigation of a Possible Abrupt Change in Structure at N = 58-60 using Two-Proton Transfer NUCLEAR REACTIONS 106,110,112,116Cd(14C, 14C), (14C, 16O), E=60 MeV; measured σ(θ); deduced optical model parameters. 104,108,110,114Pd levels deduced relative S.
doi: 10.1007/BF01412085
1985GA02 Phys.Lett. 150B, 95 (1985) D.Garreta, P.Birien, G.Bruge, A.Chaumeaux, D.M.Drake, S.Janouin, D.Legrand, M.C.Lemaire, B.Mayer, J.Pain, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.Aslanides, O.Bing, J.Lichtenstadt, A.I.Yavin Search for Antiproton-Nucleus States with (p-bar, p) Reactions NUCLEAR REACTIONS 12C, 63Cu, 209Bi(p-bar, pX), E=180 MeV; measured inclusive σ(θ, Ep); deduced no (p-bar)-nucleus states. Intranuclear cascade model.
doi: 10.1016/0370-2693(85)90146-7
1985HO16 Phys.Rev.Lett. 55, 29 (1985) C.L.Hollas, K.H.McNaughton, P.J.Riley, Shen-wu Xu, B.E.Bonner, O.B.van Dyck, J.McGill, M.W.McNaughton, J.C.Peng, R.R.Silbar, J.Dubach, W.M.Kloet Wolfenstein Polarization Observables for the Reaction p(pol)p → p(pol)πn at 800 MeV NUCLEAR REACTIONS 1H(polarized p, pπ+), E=650, 733, 800 MeV; measured Wolfenstein polarization parameters, induced polarization, σ(θ1, θ2) vs proton momentum.
doi: 10.1103/PhysRevLett.55.29
1985LI16 Phys.Rev. C32, 1096 (1985) J.Lichtenstadt, A.I.Yavin, S.Janouin, P.Birien, G.Bruge, A.Chaumeaux, D.Drake, D.Garreta, D.Legrand, M.C.Lemaire, B.Mayer, J.Pain, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.Aslanides, O.Bing Black Body Description of Antiproton-Nucleus Scattering NUCLEAR REACTIONS 12C, 16,18O, 40Ca(p-bar, p-bar), E=180 MeV; 12C, 40Ca(p-bar, p-bar), E=47 MeV; analyzed σ(θ). 12C, 16,18O, 40Ca deduced black disk radii, diffuseness parameters. Fuzzy black disk model.
doi: 10.1103/PhysRevC.32.1096
1985MI04 Phys.Rev.Lett. 54, 1237 (1985) C.Milner, M.Barlett, G.W.Hoffmann, S.Bart, R.E.Chrien, P.Pile, P.D.Barnes, G.B.Franklin, R.Grace, H.S.Plendl, J.F.Amann, T.S.Bhatia, T.Kozlowski, J.C.Peng, R.R.Silbar, H.A.Thiessen, C.Glashausser, J.A.McGill, R.Hackenburg, E.V.Hungerford, R.L.Stearns Observation of Lambda-Hypernuclei in the Reaction 12C(π+, K+)12C(Lamdba) NUCLEAR REACTIONS 12C(π+, K+), E at 716, 728 MeV/c; measured σ(θ); deduced 12C hypernuclear levels.
doi: 10.1103/PhysRevLett.54.1237
1985VI01 Nucl.Phys. A433, 441 (1985) F.Videbaek, O.Hansen, B.S.Nilsson, E.R.Flynn, J.C.Peng One- and Two-Neutron Transfer Reactions with 14C NUCLEAR REACTIONS 40Ca, 58,60Ni(14C, 13C), (14C, 12C), E=64 MeV; 124Sn(14C, 12C), E=59.75 MeV; 138Ba(14C, 12C), E=64 MeV; measured σ(θ), σ(E(13C)), σ(E(12C)); deduced optical model parameters. 41,42Ca, 58,59,60,61,62Ni, 126Sn, 140Ba levels deduced L, spectroscopic factors. Simultaneous, sequential two-nucleon transfer, DWBA analysis.
doi: 10.1016/0375-9474(85)90275-1
1984BE07 Phys.Lett. 136B, 29 (1984) R.Bertini, P.Birien, K.Braune, W.Bruckner, G.Bruge, H.Catz, A.Chaumeaux, J.Ciborowski, H.Dobbeling, J.M.Durand, R.W.Frey, D.Garreta, S.Janouin, T.J.Ketel, K.Kilian, H.Kneis, S.Majewski, B.Mayer, J.C.Peng, B.Povh, R.D.Ransome, R.Szwed, T.-A.Shibata, A.Thiessen, M.Treichel, M.Uhrmacher, Th.Walcher Sigma Hypernuclear States in (K-, π(±)) Reactions on 12C NUCLEAR REACTIONS 12C(K-, π+), (K-, π-), E at 400, 450 MeV/c; measured hypernuclear mass spectra; deduced Sigma hypernuclear states in 12C.
doi: 10.1016/0370-2693(84)92049-5
1984CO19 Z.Phys. A319, 107 (1984) M.D.Cohler, D.L.Watson, R.Wadsworth, S.M.Lane, M.J.Smithson, R.E.Brown, J.-C.Peng, N.Stein, J.W.Sunier, D.M.Drake Measurement of the Mass of 110Pd and 114Pd using the (14C, 16O) Reaction NUCLEAR REACTIONS 112,114Cd(14C, 16O), E=60 MeV; measured σ(E(16O)). 110,114Pd deduced mass. Enriched target. Mass model comparison.
doi: 10.1007/BF01429774
1984GA04 Phys.Lett. 135B, 266 (1984) D.Garreta, P.Birien, G.Bruge, A.Chaumeaux, D.M.Drake, S.Janouin, D.Legrand, M.C.Mallet-Lemaire, B.Mayer, J.Pain, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.Aslanides, O.Bing, A.Erell, J.Lichtenstadt, A.I.Yavin Scattering of Antiprotons from Carbon at 46.8 MeV NUCLEAR REACTIONS 12C(p-bar, p-bar), (p-bar, p-bar'), E=46.8 MeV; calculated σ(E(p-bar)), σ(θ); deduced (p-bar)-carbon optical potential parameter limits.
doi: 10.1016/0370-2693(84)90388-5
1984GA32 Phys.Lett. 149B, 64 (1984) D.Garreta, P.Birien, G.Bruge, A.Chaumeaux, D.M.Drake, S.Janouin, D.Legrand, M.C.Lemaire, B.Mayer, J.Pain, J.C.Peng, M.Berrada, J.P.Bocquet, E.Monnand, J.Mougey, P.Perrin, E.Aslanides, O.Bing, J.Lichtenstadt, A.I.Yavin Elastic Scattering of Antiprotons from Carbon, Calcium, and Lead at 180 MeV NUCLEAR REACTIONS 12C, 40Ca, 208Pb(p-bar, p-bar), E=180 MeV; measured σ(θ); deduced potential parameters. Optical model analysis.
doi: 10.1016/0370-2693(84)91552-1
1984MA06 Phys.Rev.Lett. 52, 743 (1984) C.F.Maguire, G.L.Bomar, M.E.Barclay, R.B.Piercey, A.V.Ramayya, J.L.C.Ford, Jr., D.Shapira, E.R.Flynn, J.D.Moses, J.C.Peng, N.Stein Systematic Spectroscopic-Factor Discrepancy in Heavy-Ion Proton-Pickup Reactions on 40Ca NUCLEAR REACTIONS 40Ca(10B, 11C), E=31 MeV; 40Ca(14C, 15N), E=41 MeV; measured σ(θ); deduced optical model parameters. 39K levels deduced spectroscopic factor reaction dependence. DWBA analysis, other data input.
doi: 10.1103/PhysRevLett.52.743
1984MA32 Phys.Rev.Lett. 53, 548 (1984) C.F.Maguire, G.L.Bomar, L.Cleemann, J.H.Hamilton, R.B.Piercey, J.C.Peng, N.Stein, P.D.Bond Unexpected Backward-Angle Enhancement in 19F + 12C Scattering NUCLEAR REACTIONS 19F(12C, 12C), (12C, 12C'), E(cm) ≈ 7-25 MeV; measured σ(θ) vs E; deduced resonance structure.
doi: 10.1103/PhysRevLett.53.548
1984WA05 J.Phys.(London) G10, L79 (1984) R.Wadsworth, M.D.Cohler, S.M.Lane, M.J.Smithson, D.L.Watson, R.E.Brown, D.M.Drake, J.-C.Peng, N.Stein, J.W.Sunier A Study of the (14C, 16O) Reaction in the Mass-100 Region NUCLEAR REACTIONS 96,100,102,104Ru, 106,108,110Pd(14C, 16O), E=60 MeV; measured σ(θ). 94,98,100,102Mo, 104,106,108Ru levels deduced relative spectroscopic factors. 96,102,104Ru, 106,108,110Pd(14C, 14C), E=60 MeV; 100Mo(16O, 16O), E=65 MeV; measured σ(θ); deduced optical model parameters. Exact finite-range DWBA analysis.
doi: 10.1088/0305-4616/10/4/003
1983VO04 Z.Phys. A310, 275 (1983) W.von Oertzen, E.R.Flynn, J.C.Peng, J.W.Sunier, R.E.Brown Study of Spin-Orbit Interaction of 13C and 15N Nuclei in 14C Induced Transfer Reactions on 138Ba NUCLEAR REACTIONS 138Ba(14C, 15N), (14C, 13C), E=64 MeV; measured σ(E(15N)), σ(E(13C)), σ(θ), reaction asymmetry; deduced optical potential parameters, spin-orbit interaction role. DWBA analysis.
1983VO12 Z.Phys. A313, 371 (1983) W.von Oertzen, R.E.Brown, E.R.Flynn, J.C.Peng, J.W.Sunier Pairing Enhancement of Two-Neutron Transfer in (14C, 12C) Reactions NUCLEAR REACTIONS 138Ba(14C, 12C), E=64 MeV; 124Sn(14C, 12C), E=59.7 MeV; measured σ(E(12C)), σ(θ); deduced two-neutron transfer mechanism.
1982BE42 Phys.Lett. 116B, 7 (1982) 12Be Levels Studied with the 14C(14C, 12Be)16O Reaction NUCLEAR REACTIONS 14C(14C, 12Be), E=50-63 MeV; measured σ(θ) vs E, σ(E(12Be)); deduced multi-step process, entrance channel effects. 12Be deduced level. DWBA analysis.
doi: 10.1016/0370-2693(82)90023-5
1982DE20 Phys.Rev. C26, 301 (1982) R.M.DeVries, N.J.DiGiacomo, J.S.Kapustinsky, J.C.Peng, W.E.Sondheim, J.W.Sunier, J.G.Cramer, R.E.Loveman, C.R.Gruhn, H.H.Wieman Dominance of Nucleon-Nucleon Interactions in α + 12C Total Reaction Cross Sections NUCLEAR REACTIONS 12C(α, X), E=94, 173 MeV/nucleon; measured total σ(reaction). Attenuation method.
doi: 10.1103/PhysRevC.26.301
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