NSR Query Results
Output year order : Descending NSR database version of April 27, 2024. Search: Author = C.Cheng Found 22 matches. 2024YA08 Phys.Rev.Lett. 132, 152502 (2024) X.Yan, Zh.Cheng, A.Abdukerim, Z.Bo, W.Chen, X.Chen, Ch.Cheng, X.Cui, Y.Fan, D.Fang, Ch.Fu, M.Fu, L.Geng, K.Giboni, L.Gu, X.Guo, Ch.Han, K.Han, Ch.He, J.He, D.Huang, Y.Huang, J.Huang, Zh.Huang, R.Hou, Y.Hou, X.Ji, Y.Ju, Ch.Li, J.Li, M.Li, Sh.Li, T.Li, Q.Lin, J.Liu, X.Lu, C.Lu, L.Luo, Y.Luo, W.Ma, Y.Ma, Y.Mao, Y.Meng, X.Ning, B.Pang, N.Qi, Zh.Qian, X.Ren, N.Shaheed, X.Shang, X.Shao, G.Shen, L.Si, W.Sun, A.Tan, Y.Tao, A.Wang, M.Wang, Q.Wang, Sh.Wang, S.Wang, W.Wang, X.Wang, Zh.Wang, Y.Wei, M.Wu, W.Wu, J.Xia, M.Xiao, X.Xiao, P.Xie, B.Yan, J.Yang, Y.Yang, Y.Yao, Ch.Yu, Y.Yuan, Zh.Yuan, X.Zeng, D.Zhang, M.Zhang, P.Zhang, Sh.Zhang, Sh.Zhang, T.Zhang, W.Zhang, Y.Zhang, Y.Zhang, Y.Zhang, L.Zhao, Q.Zheng, J.Zhou, N.Zhou, X.Zhou, Y.Zhou, Y.Zhou, for the PandaX Collaboration Searching for Two-Neutrino and Neutrinoless Double Beta Decay of 134Xe with the PandaX-4T Experiment RADIOACTIVITY 134Xe(2β-); measured decay products, Eβ, Iβ; deduced two-neutrino and neutrinoless T1/2 limits. Comparison with available data. The cylindrical active volume PandaX-4T dual-phase TPC.
doi: 10.1103/PhysRevLett.132.152502
2023RO02 Phys.Rev.Lett. 130, 122502 (2023) M.Rocchini, P.E.Garrett, M.Zielinska, S.M.Lenzi, D.D.Dao, F.Nowacki, V.Bildstein, A.D.MacLean, B.Olaizola, Z.T.Ahmed, C.Andreoiu, A.Babu, G.C.Ball, S.S.Bhattacharjee, H.Bidaman, C.Cheng, R.Coleman, I.Dillmann, A.B.Garnsworthy, S.Gillespie, C.J.Griffin, G.F.Grinyer, G.Hackman, M.Hanley, A.Illana, S.Jones, A.T.Laffoley, K.G.Leach, R.S.Lubna, J.McAfee, C.Natzke, S.Pannu, C.Paxman, C.Porzio, A.J.Radich, M.M.Rajabali, F.Sarazin, K.Schwarz, S.Shadrick, S.Sharma, J.Suh, C.E.Svensson, D.Yates, T.Zidar First Evidence of Axial Shape Asymmetry and Configuration Coexistence in 74Zn: Suggestion for a Northern Extension of the N=40 Island of Inversion RADIOACTIVITY 74Cu(β-) [from Ta(p, X)74Cu, E=490 MeV]; measured decay products, Eγ, Iγ; deduced γ-ray energies and relative intensities, energy levels, J, π, relative B(E2), ground state enhanced axial shape asymmetry (triaxiality). Comparison with available data, with shell-model calculations (SM) and shell-model calculations in a deformed Hartree-Fock basis (DNO-SM). The GRIFFIN γ-ray spectrometer, TRIUMF-ISAC1 facility.
doi: 10.1103/PhysRevLett.130.122502
2023XI04 Appl.Radiat.Isot. 197, 110817 (2023) Y.Xie, C.Cheng, W.Zhang, X.Wang, W.Qin, W.Liu, S.Lin, P.Xiao, Z.Wu, W.Jia Feasibility study of on-line monitoring gadolinium based on neutron induced gamma activation
doi: 10.1016/j.apradiso.2023.110817
2020MA59 Phys.Rev. C 102, 054325 (2020) A.D.MacLean, A.T.Laffoley, C.E.Svensson, G.C.Ball, J.R.Leslie, C.Andreoiu, A.Babu, S.S.Bhattacharjee, H.Bidaman, V.Bildstein, C.Burbadge, M.Bowry, C.Cheng, D.S.Cross, A.Diaz Varela, I.Dillmann, M.R.Dunlop, R.Dunlop, L.J.Evitts, P.Finlay, S.Gillespie, A.B.Garnsworthy, P.E.Garrett, E.Gopaul, C.J.Griffin, G.F.Grinyer, G.Hackman, J.Henderson, B.Jigmeddorj, K.G.Leach, E.Kassanda, J.McAfee, M.Moukaddam, C.Natzke, S.Nittala, B.Olaizola, J.Park, C.Paxman, J.L.Pore, C.Porzio, A.J.Radich, P.Ruotsalainen, Y.Saito, S.Sharma, J.Smallcombe, J.K.Smith, R.Sultana, J.Turko, J.Williams, D.Yates, T.Zidar High-precision branching ratio measurement and spin assignment implications for 62Ga superallowed β decay RADIOACTIVITY 62Ga(β+), (EC); measured Eγ, Iγ, β+, β+γ- and βγγ-coin, γγ(θ) using GRIFFIN array of 16 Compton-suppressed HPGe clover detectors for γ rays, and SCEPTAR array of plastic scintillators for β particles at TRIUMF-ISAC facility. 62Zn; deduced levels, J, π, multipole mixing ratios, precise β branch for superallowed 0+ to 0+ transition, β feedings to excited 0+ and (1+) states, isospin-symmetry-breaking correction. Comparison with previous experimental results and implications for theoretical studies of isospin-symmetry-breaking correction calculations.
doi: 10.1103/PhysRevC.102.054325
2013YA25 Sci. Rep. 3, 1596 (2013) G.-M.Yang, C.-F.Cheng, W.Jiang, Z.-T.Lu, R.Purtschert, Y.-R.Sun, L.-Y.Tu, S.-M.Hu Analysis of 85Kr: a comparison at the 10-14 level using micro-liter samples
doi: 10.1038/srep01596
2009CH73 Nucl.Phys. A827, 481c (2009) C.-h.Cheng, and the BABAR Collaboration Update on angles and sides of the CKM unitarity triangle from BABAR
doi: 10.1016/j.nuclphysa.2009.05.105
2007CH71 Chin.Phys.Lett. 24, 3122 (2007) Calculation of Total Cross Sections for Positron-Mg Collision ATOMIC PHYSICS Mg(e+, e+), E=2-60 eV; calculated cross sections using the momentum space coupled channel optical method.
doi: 10.1088/0256-307X/24/11/029
2001CH21 Nucl.Phys. A684, 641c (2001) C.Cheng, V.Vuletic, A.J.Kerman, S.Chu High Precision Feshbach Spectroscopy of Ultracold Cesium Collisions
doi: 10.1016/S0375-9474(01)00461-4
1985AR14 Nucl.Phys. A441, 397 (1985) D.S.Armstrong, S.K.Saha, C.-W.Cheng, E.Adamides, A.Henrikson, M.A.Lone, B.C.Robertson Gamma-Ray Strength Function of 198Hg NUCLEAR REACTIONS, ICPND 197Au(p, γ), E=4 MeV; measured σ(Eγ); deduced γ-production σ. 198Hg deduced E1 γ-strength function. Natural target.
doi: 10.1016/0375-9474(85)90152-6
1981CH04 Can.J.Phys. 59, 238 (1981) C.-W.Cheng, S.K.Saha, J.Keinonen, H.-B.Mak, W.McLatchie Hydrogen Burning of 39K in Explosive Oxygen Burning NUCLEAR REACTIONS 39K(p, γ), E=0.7-2.9 MeV; measured Iγ(θ), branching ratios; deduced astrophysical reaction rates of 39K hydrogen burning. 40Ca resonance deduced relative, absolute γ transition strengths.
doi: 10.1139/p81-030
1980CH12 Can.J.Phys. 58, 697 (1980) Cross Sections and Thermonuclear Reaction Rates for the 24Mg(α, n)27Si, 25Mg(p, n)25Al, 27Al(p, n)27Si, and 28Si(α, n)31S Reactions NUCLEAR REACTIONS 24Mg(α, n), E(cm)=7.27-10.27 MeV; 28Si(α, n), E(cm)=8.3-10.93 MeV; 25Mg(p, n), E=5.28-8.89 MeV; 27Al(p, n), E=5.77-9.63 MeV; measured annihilation γγ-coin; deduced σ(E), reaction rates. Statistical model analysis. Enriched Mg targets.
doi: 10.1139/p80-095
1980CH33 Can.J.Phys. 58, 1677 (1980) Cross Section and Thermonuclear Reaction Rates for the 58Ni(p, γ)59Cu Reaction NUCLEAR REACTIONS 58Ni(p, γ), E(cm)=0.98-5 MeV; measured σ(E); dedued thermonuclear reaction rates. Thin, thick, enriched targets, annihilation γβ+-coin technique, NaI(Tl) detector.
doi: 10.1139/p80-222
1979CH23 J.Phys.(London) G5, 1261 (1979); see 79Ch29 Cross Sections for the 42Ca(p, γ)43Sc, 42Ca(α, n)45Ti and 44Ca(p, n)44Sc Reactions
doi: 10.1088/0305-4616/5/9/010
1979CH24 Phys.Rev. C20, 851 (1979) M.S.Chiou, J.V.Maher, C.M.Cheng, W.Oelert, W.J.Jordan 12C + 24Mg Elastic Scattering NUCLEAR REACTIONS 24Mg(12C, 12C), E=20-36 MeV; measured σ(E, θ); deduced optical-model parameters.
doi: 10.1103/PhysRevC.20.851
1979CH25 Phys.Rev. C20, 1042 (1979) C.M.Cheng, J.V.Maher, M.S.Chiou, W.J.Jordan, J.C.Peng, W.Oelert, G.D.Gunn, F.D.Snyder Elastic Scattering of 12C by 28Si NUCLEAR REACTIONS 28Si(12C, 12C), E=19-48 MeV; measured σ(E, θ); deduced optical model parameters.
doi: 10.1103/PhysRevC.20.1042
1979CH29 J.Phys.(London) G5, 1261 (1979) Cross Sections for the 42Ca(p, γ)43Sc, 42Ca(α, n)45Ti and 44Ca(p, n)44Sc Reactions NUCLEAR REACTIONS 42Ca(p, γ), E=0.66-5.39 MeV; 42Ca(α, n), E=5.41-10.95 MeV; 44Ca(p, n), E=4.49-7.57 MeV; measured σ(E). Enriched targets. NaI(Tl) detectors. Statistical model interpretation.
doi: 10.1088/0305-4616/5/9/010
1979KI02 Can.J.Phys. 57, 286 (1979) Cross Sections for the 26Mg(p, n)26gAl (7.3 X 105 yr) and 26Mg(p, n)26mAl (6.35 s) Reactions NUCLEAR REACTIONS 26Mg(p, n), E=4.8-7.0 MeV; measured nothing; calculated production σ. Statistical compound nuclear model. 26Al, 26mAl deduced ratio of production σ.
doi: 10.1139/p79-036
1978VL02 Nucl.Phys. A309, 506 (1978) A.E.Vlieks, C.W.Cheng, J.D.King Cross Section and Stellar Reaction Rates for the 42Ca(p, γ) Reaction NUCLEAR REACTIONS 42Ca(p, γ), E=0.7-5.5 MeV; measured σ(E); deduced reaction rates for stellar nucleosynthesis.
doi: 10.1016/0375-9474(78)90492-X
1977CH25 Phys.Lett. 71B, 304(1977) C.M.Cheng, J.V.Maher, W.Oelert, F.D.Snyder Optical Potential for 12C+28Si Scattering NUCLEAR REACTIONS 28Si(12C, 12C), E=19-36 MeV; measured σ(E, θ); deduced optical model parameters.
doi: 10.1016/0370-2693(77)90222-2
1976MA51 Phys.Rev. C14, 2174 (1976) J.V.Maher, J.C.Peng, D.A.Sink, C.M.Cheng, H.S.Song, T.J.Lewis Reaction Dynamic Dependences of (16O, 15N) Small Angle Cross Sections NUCLEAR REACTIONS 26Mg, 27Al, 48,50Ti, 56Fe, 62Ni(16O, 15N), E=36-53 MeV; measured σ(E, θ). 27Al, 28Si, 49,51V, 57Co, 63Cu levels deduced S. DWBA analysis. Enriched targets.
doi: 10.1103/PhysRevC.14.2174
1976PE02 Phys.Rev. C13, 1451 (1976) J.C.Peng, J.V.Maher, G.H.Wedberg, C.M.Cheng Spectroscopic and Reaction Mechanism Information Derived from 160Gd(d, t)159Gd and 162Dy(d, t)161Dy Reaction Measurements NUCLEAR REACTIONS 160Gd, 162Dy(d, t), E=17 MeV; measured σ(Et, θ). 159Gd, 161Dy deduced levels, L, S. DWBA analysis.
doi: 10.1103/PhysRevC.13.1451
1973LE14 Phys.Rev. C8, 678 (1973) T.J.Lewis, G.H.Wedberg, J.C.Peng, J.L.Ricci, C.M.Cheng, J.V.Maher Possible Recoil Effects in (16O, 15N) Transitions About 10 MeV Above the Coulomb Barrier NUCLEAR REACTIONS 26Mg, 30Si(16O, 15N), E=42 MeV; measured σ(E(15N), θ). 27Al, 31P levels deduced S.
doi: 10.1103/PhysRevC.8.678
Back to query form Note: The following list of authors and aliases matches the search parameter C.Cheng: , C.F.CHENG, C.H.CHENG, C.M.CHENG, C.W.CHENG, C.Y.CHENG |