NSR Query Results
Output year order : Descending NSR database version of April 27, 2024. Search: Author = P.Zhang Found 60 matches. 2024PE06 Nucl.Instrum.Methods Phys.Res. A1060, 169039 (2024) X.G.Peng, F.Y.Liu, L.Wang, P.Zhang, P.Kuang, X.Z.Cao, R.S.Yu, B.Y.Wang Triple-coincidence positron annihilation lifetime spectrometer based on ultrafast discrimination
doi: 10.1016/j.nima.2023.169039
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
2024ZH15 Nucl.Instrum.Methods Phys.Res. A1059, 168983 (2024) H.Q.Zhang, P.Kuang, X.T.Yu, P.Zhang, F.Y.Liu, R.S.Yu, X.Z.Cao, B.Y.Wang Development of novel positron lifetime measurement system for potential liquid material inspection
doi: 10.1016/j.nima.2023.168983
2023AK05 Phys.Lett. B 845, 138128 (2023) T.Akaishi, H.Asano, X.Chen, A.Clozza, C.Curceanu, R.Del Grande, C.Guaraldo, C.Han, T.Hashimoto, M.Iliescu, K.Inoue, S.Ishimoto, K.Itahashi, M.Iwasaki, Y.Ma, M.Miliucci, R.Murayama, H.Noumi, H.Ohnishi, S.Okada, H.Outa, K.Piscicchia, A.Sakaguchi, F.Sakuma, M.Sato, A.Scordo, K.Shirotori, D.Sirghi, F.Sirghi, S.Suzuki, K.Tanida, T.Toda, M.Tokuda, T.Yamaga, X.Yuan, P.Zhang, Y.Zhang, H.Zhang Precise lifetime measurement of 4ΛH hypernucleus using in-flight 4He(K-, π0)4ΛH reaction RADIOACTIVITY 4H(π-) [from 4He(K-, π0), E not given]; measured decay products, Eγ, Iγ; deduced hypernucleus T1/2. Comparison with available data. Experiment (J-PARC E73).
doi: 10.1016/j.physletb.2023.138128
2023BA40 Eur.Phys.J. A 59, 284 (2023); Erratum Eur.Phys.J. A 60, 23 (2024) X.H.Bai, Z.Wei, K.Wu, S.Y.Zhang, P.Q.Zhang, Y.N.Han, M.Li, J.Y.Wang, Z.Y.Wei, Z.E.Yao, J.R.Wang, Y.Zhang Physical design of a high-intensity compact D–D/D–T neutron generator based on the internal antenna RF ion source NUCLEAR REACTIONS 2,3H(d, n), E=200 keV; measured reaction products, En, In; deduced neutron yields.
doi: 10.1140/epja/s10050-023-01177-3
2023GA21 J.Radioanal.Nucl.Chem. 332, 3037 (2023) X.Gao, P.Zhang, J.Li, W.Mao, Z.Guo, J.Li, Y.Zhang, J.Chen, L.Sheng, M.Lin Production of 99Mo via photoneutron reaction using a 50 MeV electron linear accelerator NUCLEAR REACTIONS 100Mo(γ, n), E<50 MeV; calculated yields using FLUKA program; deduced guidance on the size of W conversion and molybdenum targets, as well as the selection of molybdenum species.
doi: 10.1007/s10967-023-09003-2
2023HU15 Phys.Rev. C 108, 024608 (2023) D.-y.Huo, Z.Wei, K.Wu, C.Han, Y.-n.Han, Y.-x.Wang, P.-q.Zhang, Y.He, X.-j.Bao, Z.-y.Deng, Z.-e.Yao Effect of octupole deformation of fragments on mass-asymmetric yields of fission of actinide nuclei NUCLEAR REACTIONS 235,236,238,239U, 232Th, 239,240Pu, 237Np(n, F), E=1-10 MeV; calculated mass distributions of fission fragments, quadrupole and octupole deformations of scission configurations as a function of mass number of the fission fragments, neutron-charge ratio of fragments. Scission-point model with considering octupole deformation of fragments. Comparison to experimental data.
doi: 10.1103/PhysRevC.108.024608
2023QI02 Phys.Rev. A 107, L010802 (2023) X.-Q.Qi, P.-P.Zhang, Z.-C.Yan, T.-Y.Shi, G.W.F.Drake, A.-X.Chen, Z.-X.Zhong Theoretical hyperfine splittings of 7, 9Be2+ ions for future studies of nuclear properties ATOMIC PHYSICS 7,9Be; calculated hyperfine structures and splittings within the framework of the nonrelativistic quantum electrodynamics, including relativistic and radiative corrections. Comparison with available data.
doi: 10.1103/PhysRevA.107.L010802
2023SU09 Astrophys.J.Suppl.Ser. 267, 21 (2023) Z.Sun, P.Zhang, F.Dong, J.Yao, H.Shan, E.Jullo, J.-P.Kneib, B.Yin An Unbiased Method of Measuring the Ratio of Two Data Sets
doi: 10.3847/1538-4365/acda2a
2022CU08 Eur.Phys.J. D 76, 140 (2022) K.Cui, S.Chao, C.Sun, S.Wang, P.Zhang, Y.Wei, J.Yuan, J.Cao, H.Shu, X.Huang Evaluation of the systematic shifts of a 40Ca+-27Al+ optical clock ATOMIC PHYSICS 40Ca, 27Al; analyzed available ata; deduced the total systematic uncertainty of a 40Ca+-27Al+ optical clock due to the quadratic Zeeman shift, frequency stability.
doi: 10.1140/epjd/s10053-022-00451-1
2022LI28 Few-Body Systems 63, 43 (2022) W.P.Liu, Z.H.Li, J.J.He, X.D.Tang, G.Lian, J.Su, Y.P.Shen, Z.An, F.Q.Chao, J.J.Chang, L.H.Chen, H.Chen, X.J.Chen, Y.H.Chen, Z.J.Chen, B.Q.Cui, X.C.Du, X.Fang, C.B.Fu, L.Gan, B.Guo, Z.Y.Han, X.Y.Guo, G.Z.He, J.R.He, A.Heger, S.Q.Hou, H.X.Huang, N.Huang, B.L.Jia, L.Y.Jiang, S.Kubono, J.M.Li, M.C.Li, K.A.Li, E.T.Li, T.Li, Y.J.Li, M.Lugaro, X.B.Luo, H.Y.Ma, S.B.Ma, D.M.Mei, W.Nan, W.K.Nan, N.C.Qi, Y.Z.Qian, J.C.Qin, J.Ren, C.S.Shang, L.T.Sun, W.L.Sun, W.P.Tan, I.Tanihata, S.Wang, P.Wang, Y.B.Wang, Q.Wu, S.W.Xu, S.Q.Yan, L.T.Yang, Y.Yang, X.Q.Yu, Q.Yue, S.Zeng, L.Zhang, H.Zhang, H.Y.Zhang, L.Y.Zhang, N.T.Zhang, P.Zhang, Q.W.Zhang, T.Zhang, X.P.Zhang, X.Z.Zhang, W.Zhao, J.F.Zhou, Y.Zho Progress of Underground Nuclear Astrophysics Experiment JUNA in China NUCLEAR REACTIONS 12C(α, γ), 13C(α, n), 25Mg(p, γ), 19F(p, α), E(cm)<600 keV; measured reaction products; deduced yields near the Gamow window. Comparison with available data.
doi: 10.1007/s00601-022-01735-3
2022ZH67 Phys.Rev. C 106, 055803 (2022) L.Y.Zhang, J.Su, J.J.He, R.J.deBoer, D.Kahl, M.Wiescher, D.Odell, Y.J.Chen, X.Y.Li, J.G.Wang, L.Zhang, F.Q.Cao, H.Zhang, Z.C.Zhang, T.Y.Jiao, Y.D.Sheng, L.H.Wang, L.Y.Song, X.Z.Jiang, Z.M.Li, E.T.Li, S.Wang, G.Lian, Z.H.Li, B.Guo, X.D.Tang, L.T.Sun, Q.Wu, J.Q.Li, B.Q.Cui, L.H.Chen, R.G.Ma, N.C.Qi, W.L.Sun, X.Y.Guo, P.Zhang, Y.H.Chen, Y.Zhou, J.F.Zhou, J.R.He, C.S.Shang, M.C.Li, J.P.Cheng, W.P.Liu Direct measurement of the astrophysical 19F(p, αγ)16O reaction in a deep-underground laboratory NUCLEAR REACTIONS 19F(p, αγ), E(cm)=72.4-344 keV; measured Eγ, Iγ; deduced astrophysical S-factor, thermonuclear astrophysical reaction rates (range 0.05–1 GK), contributions from different channels. R-matrix analysis with AZURE2 together with a MCMC Bayesian uncertainty estimation. Comparison to other experimental data. 4π BGO γ-array with proton beam from JUNA accelerator at China JinPing underground Laboratory (CJPL).
doi: 10.1103/PhysRevC.106.055803
2021ZH53 Phys.Rev.Lett. 127, 152702 (2021) L.Y.Zhang, J.Su, J.J.He, M.Wiescher, R.J.deBoer, D.Kahl, Y.J.Chen, X.Y.Li, J.G.Wang, L.Zhang, F.Q.Cao, H.Zhang, Z.C.Zhang, T.Y.Jiao, Y.D.Sheng, L.H.Wang, L.Y.Song, X.Z.Jiang, Z.M.Li, E.T.Li, S.Wang, G.Lian, Z.H.Li, X.D.Tang, H.W.Zhao, L.T.Sun, Q.Wu, J.Q.Li, B.Q.Cui, L.H.Chen, R.G.Ma, B.Guo, S.W.Xu, J.Y.Li, N.C.Qi, W.L.Sun, X.Y.Guo, P.Zhang, Y.H.Chen, Y.Zhou, J.F.Zhou, J.R.He, C.S.Shang, M.C.Li, X.H.Zhou, Y.H.Zhang, F.S.Zhang, Z.G.Hu, H.S.Xu, J.P.Chen, W.P.Liu Direct Measurement of the Astrophysical 19F(p, αγ)16O Reaction in the Deepest Operational Underground Laboratory NUCLEAR REACTIONS 19F(p, α), E(cm)=72.4-188.8 keV; measured reaction products, Eγ, Iγ; deduced yields, S-factors, reaction rates. The China Jinping Underground Laboratory (CJPL), JUNA accelerator.
doi: 10.1103/physrevlett.127.152702
2019EL05 Prog.Theor.Exp.Phys. 2019, 053D01 (2019) Marchenko method with incomplete data and singular nucleon scattering
doi: 10.1093/ptep/ptz034
2019LI32 Phys.Rev. C 99, 064614 (2019) X.Liu, S.P.Maydanyuk, P.-M.Zhang, L.Liu First investigation of hypernuclei in reactions via analysis of emitted bremsstrahlung photons RADIOACTIVITY 210Po, 106,108Te, 9B, 9Be(α); calculated emission probabilities of bremsstrahlung photons of Eγ=100-700 keV during the decay of normal nuclei. 211Po, 107,109Te, 10B, 10Be(α); calculated emission probabilities of bremsstrahlung photons of Eγ=100-700 keV during the decay of hypernuclei, and contribution of hyperon magnetic moment to the emission probability of bremsstrahlung photons; estimated influence of α-hypernucleus potential on the bremsstrahlung spectrum. Generalized Pauli equation for nucleons in the α-nucleus system and operator of emission of photons. NUCLEAR REACTIONS 197Au(α, α'), E=50 MeV; calculated double-differential σ(Eγ) for emission of coherent bremsstrahlung photons in Eγ=14-30 MeV range; deduced evidence of oscillations in the calculated bremsstrahulung spectrum. Generalized Pauli equation for nucleons in the α-nucleus system and operator of emission of photons. Comparison with experimental data.
doi: 10.1103/PhysRevC.99.064614
2019LI54 J.Phys.(London) G46, 105106 (2019) Z.-Q.Li, S.-Y.Wang, J.-Z.Guan, W.-Ju.Zhang, T.Liu, B.Qi, S.Wang, D.-P.Sun, L.Liu, C.Liu, P.Zhang, N.-B.Zhang, H.Jia, Y.-M.Zhang, R.i-J.Guo, X.Xiao, X.-C.Han, C.-Y.Niu, Z.-Q.Chen, Pi.Lv, C.-Y.Li, X.-G.Wu, G.-S.Li, C.-Y.He, Y.Zheng, C.-B.Li, H.-W.Li, P.-W.Luo First observation of high-spin states in the N=83 nucleus 142Pr NUCLEAR REACTIONS 138Ba(7Li, 3n), E = 38 MeV; measured reaction products, Eγ, Iγ; deduced level energies, J, π, asymmetric angular distribution from oriented states (ADO). Comparison with systematics, shell model calculations.
doi: 10.1088/1361-6471/ab3698
2019MA42 Phys.Rev. C 99, 064602 (2019) S.P.Maydanyuk, P.-M.Zhang, L.-P.Zou Nucleon microscopy in proton-nucleus scattering via analysis of bremsstrahlung emission NUCLEAR REACTIONS 197Au(p, p'), E=190 MeV; calculated electric and magnetic bremsstrahlung photon differential σ(E) for Eγ=20-180 MeV; analyzed coherent and incoherent bremsstrahlung emissions. Many-nucleon generalization of Dirac equation with the addition of form factors of nucleon, and contribution of emission of bremsstrahlung photons of electric and magnetic type. Discussed bremsstrahlung measurement as probe for form factor and internal structure of proton. Comparison with experimental data for proton scattering. RADIOACTIVITY 226Ra(α); calculated bremsstrahlung photon emission probability at Eγ<700 keV during α decay, and contribution from emission of bremsstrahlung photons from tunneling region.
doi: 10.1103/PhysRevC.99.064602
2019XU13 Phys.Rev. C 100, 051303 (2019) X.Xu, J.H.Liu, C.X.Yuan, Y.M.Xing, M.Wang, Y.H.Zhang, X.H.Zhou, Yu.A.Litvinov, K.Blaum, R.J.Chen, X.C.Chen, C.Y.Fu, B.S.Gao, J.J.He, S.Kubono, Y.H.Lam, H.F.Li, M.L.Liu, X.W.Ma, P.Shuai, M.Si, M.Z.Sun, X.L.Tu, Q.Wang, H.S.Xu, X.L.Yan, J.C.Yang, Y.J.Yuan, Q.Zeng, P.Zhang, X.Zhou, W.L.Zhan, S.Litvinov, G.Audi, S.Naimi, T.Uesaka, Y.Yamaguchi, T.Yamaguchi, A.Ozawa, B.H.Sun, K.Kaneko, Y.Sun, F.R.Xu Masses of ground and isomeric states of 101In and configuration-dependent shell evolution in odd-$A$ indium isotopes ATOMIC MASSES 101In, 101mIn; measured mass excesses using storage-ring based isochronous mass spectrometry technique; deduced energy of the isomeric state. Comparison with systematic values in AME-2016 values. Systematics of 1/2- isomeric states in 101,103,105,107,109,111In, data from the present experiment for 101In and from the ENSDF database for others. NUCLEAR STRUCTURE 101,103,105,107,109,111,113In; calculated energies of the 1/2- isomeric levels, neutron occupation numbers for 1/2- and 9/2+ levels, neutron effective single-particle energies of ν1g7/2 with respect to ν2d5/2 for 9/2+ and 1/2- levels using state-of-the-art shell-model calculations. Comparison with available experimental data. NUCLEAR REACTIONS 9Be(112Sn, X)31P/33S/35Cl/37Ar/39K/58Ni/60Cu/62Zn/64Ga/66Ge/68As/70Se/72Br/74Rb/76Rb/78Sr/80Y/89Tc/91Ru/91mRu/93Rh/95Pd/95mPd/97Ag/99Cd/101In/101mIn/103Sn, E=400.88 MeV/nucleon; measured reaction products selected and analyzed by RIBLL2 separator, and revolution time spectrum at the Cooler Storage Ring (CSR) accelerator complex of HIRFL-Lanzhou facility.
doi: 10.1103/PhysRevC.100.051303
2018EL06 J.Phys.(London) G45, 105103 (2018) Neutron-proton scattering and singular potentials
doi: 10.1088/1361-6471/aadc77
2018FU06 Phys.Rev. C 97, 024339 (2018) G.J.Fu, Y.Y.Cheng, Y.H.Zhang, P.Zhang, P.Shuai, Y.M.Zhao, M.Wang New local mass relation for isobaric analogue states and isospin-nonconserving forces ATOMIC MASSES A=20-60; A=41-52; derived a new local mass relation for isobaric analog states of four neighboring nuclei, and compared with AME-2012 and IAS-2014 evaluations; discussed empirical Coulomb energy formula and the isobaric multiplet mass equation (IMME), and odd-even staggering of the IMME coefficients.
doi: 10.1103/PhysRevC.97.024339
2018FU11 Phys.Rev. C 98, 014315 (2018) C.Y.Fu, Y.H.Zhang, X.H.Zhou, M.Wang, Yu.A.Litvinov, K.Blaum, H.S.Xu, X.Xu, P.Shuai, Y.H.Lam, R.J.Chen, X.L.Yan, T.Bao, X.C.Chen, H.Chen, J.J.He, S.Kubono, D.W.Liu, R.S.Mao, X.W.Ma, M.Z.Sun, X.L.Tu, Y.M.Xing, P.Zhang, Q.Zeng, X.Zhou, W.L.Zhan, S.Litvinov, G.Audi, T.Uesaka, Y.Yamaguchi, T.Yamaguchi, A.Ozawa, B.H.Sun, Y.Sun, F.R.Xu Masses of the Tz = -3/2 nuclei 27P and 29S ATOMIC MASSES 27P, 29S; measured revolution time spectrum, and mass excesses using isochronous mass spectrometry (IMS) technique at Cooler Storage Ring (CSR) of HIRFL-Lanzhou facility. 29S, 29P, 29Si, 29Al; analyzed linear and quadratic coefficients of the isobaric multiplet mass equation (IMME). Comparison with AME-2016 values. 27P, 29S; isotopes produced in 9Be(58Ni, X), E=468 MeV/nucleon reaction, and using RIBLL2 fragment separator.
doi: 10.1103/PhysRevC.98.014315
2018MA66 Phys.Rev. C 98, 054613 (2018) S.P.Maydanyuk, P.-M.Zhang, L.-P.Zou Manifestation of the important role of nuclear forces in the emission of photons in pion scattering off nuclei NUCLEAR REACTIONS 44Ca(π+, π+'), E=116 MeV; 208Pb(p, p'), E=140 MeV; 197Au(p, p'), E=190 MeV; calculated differential σ(E) of bremsstrahlung photon emission probabilities using relativistic Johnson-Satchler model from Klien-Gordon equation, and non-relativistic Woods-Saxon optical model. Comparison with experimental data. Discussed essential dependence of bremsstrahlung spectra on nuclear forces.
doi: 10.1103/PhysRevC.98.054613
2018WU02 Phys.Rev. A 97, 032702 (2018) Y.Wu, Y.Liang, M.X.Xu, Y.Yuan, C.H.Chang, Z.C.Qian, B.Y.Wang, P.Kuang, P.Zhang Thick-target-method study of Mαβ x-ray production cross sections of Pb and Bi impacted by positrons up to 9 keV NUCLEAR REACTIONS Pb, 209Bi(e+, X), E<9 keV; measured reaction products, Eγ, Iγ, X-rays; deduced thick target production X-ray σ. Comparison with theoretical calculations.
doi: 10.1103/PhysRevA.97.032702
2018XI04 Phys.Lett. B 781, 358 (2018) Y.M.Xing, K.A.Li, Y.H.Zhang, X.H.Zhou, M.Wang, Yu.A.Litvinov, K.Blaum, S.Wanajo, S.Kubono, G.Martinez-Pinedo, A.Sieverding, R.J.Chen, P.Shuai, C.Y.Fu, X.L.Yan, W.J.Huang, X.Xu, X.D.Tang, H.S.Xu, T.Bao, X.C.Chen, B.S.Gao, J.J.He, Y.H.Lam, H.F.Li, J.H.Liu, X.W.Ma, R.S.Mao, M.Si, M.Z.Sun, X.L.Tu, Q.Wang, J.C.Yang, Y.J.Yuan, Q.Zeng, P.Zhang, X.Zhou, W.L.Zhan, S.Litvinov, G.Audi, T.Uesaka, Y.Yamaguchi, T.Yamaguchi, A.Ozawa, C.Frohlich, T.Rauscher, F.-K.Thielemann, B.H.Sun, Y.Sun, A.C.Dai, F.R.Xu Mass measurements of neutron-deficient Y, Zr, and Nb isotopes and their impact on rp and νp nucleosynthesis processes ATOMIC MASSES 78,79Y, 80,81Zr, 82,83,84Nb, 84Mo; measured revolution time spectrum; deduced mass excess values and proton separation energies. Comparison with available data.
doi: 10.1016/j.physletb.2018.04.009
2018XU09 Acta Phys.Pol. B49, 515 (2018) X.Xu, P.Shuai, P.Zhang, Y.Zhang, M.Wang Extremely Small Isospin Impurity in the Lowest T=2 Isobaric Analogue State in 52Co NUCLEAR REACTIONS 9Be(58Ni, x), E=467.91 MeV/nucleon; measured revolution time spectrum (counts vs revolution time) using in-flight fragment separator RIBLL2 and cooler-storage ring CSRe; deduced peaks corresponding to TZ=-1 and -1/2 nuclei, new partial decay scheme of 52Co gs and 2+ isomeric state; compared with old partial decay scheme based on conventional 52Ni β-delayed proton assignment (using published data), compared also with recent β-delayed protons and γ-rays experiment; compiled published data on 40Ti, 44Cr, 46Mn, 48Fe, 50Co, 52Ni, 56Zn proton decay strengths, theoretical feeding of IAS as a super-allowed β-decay branch, γ-deexcitation strength of IAS proton decay group with highest intensity corresponds to the decay of 1+ excited state in 52Co and not from Jπ=0+, T=2 IAS. Effort to find an explanation for that is highly called for.
doi: 10.5506/aphyspolb.49.515
2018ZH29 Phys.Rev. C 98, 014319 (2018) Y.H.Zhang, P.Zhang, X.H.Zhou, M.Wang, Yu.A.Litvinov, H.S.Xu, X.Xu, P.Shuai, Y.H.Lam, R.J.Chen, X.L.Yan, T.Bao, X.C.Chen, H.Chen, C.Y.Fu, J.J.He, S.Kubono, D.W.Liu, R.S.Mao, X.W.Ma, M.Z.Sun, X.L.Tu, Y.M.Xing, Q.Zeng, X.Zhou, W.L.Zhan, S.Litvinov, K.Blaum, G.Audi, T.Uesaka, Y.Yamaguchi, T.Yamaguchi, A.Ozawa, B.H.Sun, Y.Sun, F.R.Xu Isochronous mass measurements of Tz = -1 fp-shell nuclei from projectile fragmentation of 58Ni ATOMIC MASSES 43Ti, 44,44m,45V, 46,47Cr, 48,49Mn, 50,51Fe, 52,52mCo, 54Ni, 56Cu; measured time revolution spectra, and mass excesses using isochronous mass spectrometry (IMS) technique using Cooler Storage Ring (CSRm) at HIRFL-Lanzhou. Comparison with AME-2012 evaluation, and with predictions of several mass models. 52,52mCo, 44,44mV; deduced precise energies of the isomeric states from direct mass measurements, and compared with previously known values. 52,52mCo, 52Mn; deduced revised level energies in 52Co from new mass measurements for 52,52mCo and known level energies in 52Mn mirror nucleus. 56Co, 56Cu; deduced revised 56Cu level energies from new mass measurement for 56Cu and using known level energies of 56Co mirror nucleus. 52Co, 52Fe, 52Mn, 52Cr; analyzed quadratic and cubic fit coefficients of the isobaric multiplet mass equation (IMME). Discussed impact of new mass measurements on different aspects in nuclear structure. Isotopes produced in 9Be(58Ni, X), E=467.91 MeV/nucleon reaction, and fragments separated using RIBLL2 separator at Lanzhou.
doi: 10.1103/PhysRevC.98.014319
2017MA40 Phys.Rev. C 96, 014602 (2017) S.P.Maydanyuk, P.-M.Zhang, L.-P.Zou New quasibound states of the compound nucleus in α-particle capture by the nucleus NUCLEAR REACTIONS 44Ca(α, X)48Ti*, E=0-50 MeV; calculated probability of existence of the compound nucleus, penetrability and amplitude of oscillations, fusion σ(E), energies of the quasibound states of the compound nucleus, resonant term of the S matrix. Improved multiple internal reflections (MIR) method. Comparison with experimental data.
doi: 10.1103/PhysRevC.96.014602
2017ZE02 Phys.Rev. C 96, 031303 (2017) Q.Zeng, M.Wang, X.H.Zhou, Y.H.Zhang, X.L.Tu, X.C.Chen, X.Xu, Yu.A.Litvinov, H.S.Xu, K.Blaum, R.J.Chen, C.Y.Fu, Z.Ge, W.J.Huang, H.F.Li, J.H.Liu, B.Mei, P.Shuai, M.Si, B.H.Sun, M.Z.Sun, Q.Wang, G.Q.Xiao, Y.M.Xing, T.Yamaguchi, X.L.Yan, J.C.Yang, Y.J.Yuan, Y.D.Zang, P.Zhang, W.Zhang, X.Zhou Half-life measurement of short-lived 94m44Ru44+ using isochronous mass spectrometry RADIOACTIVITY 94mRu(IT)[from 9Be(112Sn, X), E=376.42 MeV/nucleon]; measured half-life of the fully-ionized (bare) ions of 8+ isomeric state at 2644 keV at the Experimental Cooler Storage Ring (CSRe) in Heavy Ion Research Facility (HIRFL), Lanzhou; deduced ICC. Comparison with calculations using BrIcc code, and with theoretical predictions. See also 2017Ch37 from the same laboratory for a detailed statistical analysis for extraction of half-life from experimental data. ATOMIC MASSES 94Ru, 94mRu; measured mass excesses of the isomer and the ground state of 94Ru using isochronous mass spectrometry (IMS) at Heavy Ion Research Facility (HIRFL), Lanzhou, and compared with AME-2016.
doi: 10.1103/PhysRevC.96.031303
2017ZH12 Phys.Lett. B 767, 20 (2017) P.Zhang, X.Xu, P.Shuai, R.J.Chen, X.L.Yan, Y.H.Zhang, M.Wang, Yu.A.Litvinov, K.Blaum, H.S.Xu, T.Bao, X.C.Chen, H.Chen, C.Y.Fu, J.J.He, S.Kubono, Y.H.Lam, D.W.Liu, R.S.Mao, X.W.Ma, M.Z.Sun, X.L.Tu, Y.M.Xing, J.C.Yang, Y.J.Yuan, Q.Zeng, X.Zhou, X.H.Zhou, W.L.Zhan, S.Litvinov, G.Audi, T.Uesaka, Y.Yamaguchi, T.Yamaguchi, A.Ozawa, B.H.Sun, Y.Sun, F.R.Xu High-precision QEC values of superallowed 0+ → 0+β-emitters 46Cr, 50Fe and 54Ni ATOMIC MASSES 42Ti, 46Cr, 48Mn, 50Fe, 54Ni; measured the revolution time spectrum; deduced precision mass excesses, corrected log ft values. Comparison with AME12 evaluated data.
doi: 10.1016/j.physletb.2017.01.039
2016KO08 Phys.Rev. C 93, 021901 (2016) N.Kochelev, H.-J.Lee, Y.Oh, B.Zhang, P.Zhang Nonperturbative collisional energy loss of heavy quarks in quark-gluon plasma
doi: 10.1103/PhysRevC.93.021901
2016LI34 Phys.Rev. C 94, 014315 (2016); Erratum Phys.Rev. C 102, 019902 (2020) Z.Q.Li, S.Y.Wang, C.Y.Niu, B.Qi, S.Wang, D.P.Sun, C.Liu, C.J.Xu, L.Liu, P.Zhang, X.G.Wu, G.S.Li, C.Y.He, Y.Zheng, C.B.Li, B.B.Yu, S.P.Hu, S.H.Yao, X.P.Cao, J.L.Wang High-spin states in the semimagic nucleus 89Y and neutron-core excitations in the N=50 isotones NUCLEAR REACTIONS 82Se(11B, 4n), E=48, 52 MeV; measured Eγ, Iγ, γγ-coin, γ(θ)(ADO ratios) at HI-13 tandem accelerator of CIAE-Beijing. 89Y; deduced high-spin levels, J, π, multipolarity, configurations. Comparison with large-basis shell-model calculations using OXBASH code, assuming 66Ni as an inert core. Level energy and Jπ systematics of N=50 even-even and odd-A isotones: 86Kr, 88Sr, 90Zr, 92Mo, 87Rb, 89Y, 91Nb and 93Tc.
doi: 10.1103/PhysRevC.94.014315
2016MA08 Phys.Rev. C 93, 014617 (2016) S.P.Maydanyuk, P.-M.Zhang, L.-P.Zou New approach for obtaining information on the many-nucleon structure in α decay from accompanying bremsstrahlung emission RADIOACTIVITY 106,110Te, 210Po, 219Pa(α); calculated bremsstrahlung probabilities of the emitted photons with and without the inclusion of many-nucleon structure; deduced visible effects on bremsstrahlung spectrum in the case of 106Te α decay, whereas no effect for other decays. Comparison with experimental data. NUCLEAR REACTIONS 121Sb(p, γ)122Te, E=10, 50, 100, 300 MeV; calculated bremsstrahlung probabilities of the emitted photons in proton capture with and without the inclusion of many-nucleon structure. Relevance to nucleosynthesis in the p process.
doi: 10.1103/PhysRevC.93.014617
2016XU10 Phys.Rev.Lett. 117, 182503 (2016) X.Xu, P.Zhang, P.Shuai, R.J.Chen, X.L.Yan, Y.H.Zhang, M.Wang, Yu.A.Litvinov, H.S.Xu, T.Bao, X.C.Chen, H.Chen, C.Y.Fu, S.Kubono, Y.H.Lam, D.W.Liu, R.S.Mao, X.W.Ma, M.Z.Sun, X.L.Tu, Y.M.Xing, J.C.Yang, Y.J.Yuan, Q.Zeng, X.Zhou, X.H.Zhou, W.L.Zhan, S.Litvinov, K.Blaum, G.Audi, T.Uesaka, Y.Yamaguchi, T.Yamaguchi, A.Ozawa, B.H.Sun, Y.Sun, A.C.Dai, F.R.Xu Identification of the Lowest T=2, Jπ = 0+ Isobaric Analog State in 52Co and Its Impact on the Understanding of β-Decay Properties of 52Ni NUCLEAR REACTIONS Be(58Ni, X)52Co, E=467.91 MeV/nucleon; measured reaction products, TOF; deduced atomic masses, energy of T=2 isobaric analog state, level scheme. Comparison with shell model calculations using GXPF1J interaction.
doi: 10.1103/PhysRevLett.117.182503
2016ZH08 Phys.Rev. A 93, 032709 (2016) R.T.Zhang, W.T.Feng, X.L.Zhu, S.F.Zhang, D.L.Guo, Y.Gao, D.B.Qian, S.Xu, S.C.Yan, P.Zhang, Z.K.Huang, H.B.Wang, B.Hai, D.M.Zhao, X.Ma Two-electron transfer and ionization mechanism in 80-keV/u Ne8+ on He collisions NUCLEAR REACTIONS He(Ne, X), E=80 keV/nucleon; measured reaction products, Eβ, Iβ; deduced autoionization decay from doubly excited states with symmetric and asymmetric configurations.
doi: 10.1103/PhysRevA.93.032709
2015CH24 Phys.Rev. C 91, 044303 (2015) Z.Q.Chen, S.Y.Wang, L.Liu, P.Zhang, H.Jia, B.Qi, S.Wang, D.P.Sun, C.Liu, Z.Q.Li, X.G.Wu, G.S.Li, C.Y.He, Y.Zheng, L.H.Zhu High-spin states and possible "stapler'" band in 115In NUCLEAR REACTIONS 114Cd(7Li, 2nα), E=48 MeV; measured Eγ, Iγ, γγ-coin, angular distribution (ADO) ratios of γ rays using HI-13 tandem accelerator at CIAE-Beijing facility. 115In; deduced levels, J, π, dipole bands, multipolarity, configuration, alignment plot, oblate band built on the stapler mechanism. Comparison with tilted axis cranking model based on covariant density functional theory (TAC-CDFT) calculations.
doi: 10.1103/PhysRevC.91.044303
2015LI21 Phys.Rev. C 91, 064319 (2015) Z.Q.Li, S.Y.Wang, L.Liu, Y.M.Zhang, B.Qi, S.Wang, D.P.Sun, C.Liu, P.Zhang, N.B.Zhang, H.Jia, Q.Hu, C.Y.Niu, Z.Q.Chen, P.Lv, C.Y.Li, X.G.Wu, G.S.Li, C.Y.He, Y.Zheng, C.B.Li, H.W.Li, P.W.Luo High-spin states of the semimagic nucleus 141Pr NUCLEAR REACTIONS 138Ba(7Li, 4n), E=38 MeV; measured Eγ, Iγ, γγ-coin, γγ(θ)(ADO ratios) at HI-13 tandem accelerator facility of the CIAE-Beijing. 141Pr; deduced high-spin levels, J, π, internal conversion coefficients from γ-intensity balance, multipolarity, configuration, mainly proton excitations above the Z=50 shell, Comparison with shell model calculations using OXBASH computer code. Systematics of level structures in N=82 isotones 133Sb, 135I, 137Cs, 139La, 141Pr, 143Pm and 143Eu. NUCLEAR STRUCTURE 141Pr; calculated levels, J, π, wave functions using shell model and OXBASH computer code. Comparison with experimental data.
doi: 10.1103/PhysRevC.91.064319
2015MA11 Phys.Rev. C 91, 024605 (2015) New approach to determine proton-nucleus interactions from experimental bremsstrahlung data NUCLEAR REACTIONS 208Pb(p, X), E=140, 145 MeV; 12C, 58Ni, 107Ag, 197Au(p, X), E=190 MeV; calculated angular photon bremsstrahlung cross sections on the basis of the first, second, and third matrix elements, ratio between the incoherent emission and the coherent emission of photons and transition between them versus photon energy; explained hump-shaped plateau in the intermediate and high energy regions of the bremsstrahlung spectra; deduced radius parameters of the proton-nucleus potentials. Microscopic bremsstrahlung model in proton-nucleus scattering.
doi: 10.1103/PhysRevC.91.024605
2015MA35 Nucl.Phys. A940, 89 (2015) S.P.Maydanyuk, P.-M.Zhang, S.V.Belchikov Quantum design using a multiple internal reflections method in a study of fusion processes in the capture of alpha-particles by nuclei NUCLEAR REACTIONS 44Ca(α, x), E=2-30 MeV; calculated potential, penetrability, fusion probability, fusion σ with contributions of different partial waves. 40,44,46Ca(α, x), E=4-30 MeV; calculated fusion probability, fusion σ; deduced α-nucleus potential parameters. MIR (multiple internal reflection) method with WKB formula. Compared with available data.
doi: 10.1016/j.nuclphysa.2015.04.002
2014LI31 Phys.Rev. C 90, 014313 (2014), Erratum Phys.Rev. C 108, 059901 (2023) L.Liu, S.Y.Wang, Z.Q.Chen, C.Liu, B.Qi, D.P.Sun, S.Wang, Q.An, C.J.Xu, P.Zhang, Z.Q.Li, C.Y.Niu, X.G.Wu, G.S.Li, C.Y.He, Y.Zheng, C.B.Li, S.H.Yao, S.P.Hu, H.W.Li, J.J.Liu, J.L.Wang Single-particle structures, high-spin isomers, and a strongly coupled band in odd-odd 120Sb NUCLEAR REACTIONS 116Cd(7Li, 3n), E=34 MeV; measured Eγ, Iγ, γγ-coin, γγ(θ)(ADO ratios) at HI-13 tandem accelerator facility of CIAE. 120Sb; deduced high-spin levels, J, π, multipolarities, bands, configurations, B(M1)/B(E2) ratios. Comparison with triaxial relativistic mean-field, and particle-rotor model calculations for high-spin isomers. Level systematics of 118,119,120Sb.
doi: 10.1103/PhysRevC.90.014313
2014ZH14 Phys.Rev. C 89, 047302 (2014) Competition between antimagnetic and core rotation in 109Cd within covariant density functional theory NUCLEAR STRUCTURE 109Cd; calculated negative-parity yrast levels, J, π, B(E2), total angular momentum as function of rotational frequency, evolution of deformation in the (β2, γ) plane with rotational frequency, angular momentum vectors of neutron particles and proton holes, contributions of anti-magnetic rotation (AMR) and core rotation to the total angular momentum. Tilted axis cranking model based on covariant density functional theory (TAC-CDFT). Comparison with experimental data.
doi: 10.1103/PhysRevC.89.047302
2013LI46 Phys.Rev. C 88, 037301 (2013) C.Liu, S.Y.Wang, B.Qi, D.P.Sun, S.Wang, C.J.Xu, L.Liu, P.Zhang, Z.Q.Li, B.Wang, X.C.Shen, M.R.Qin, H.L.Liu, Y.Gao, L.H.Zhu, X.G.Wu, G.S.Li, C.Y.He, Y.Zheng Signature splitting, shape evolution, and nearly degenerate bands in 108Ag NUCLEAR REACTIONS 104Ru(7Li, 3n), E=33 MeV; measured Eγ, Iγ, γγ-coin, γγ(θ)(DCO) at CIAE, Beijing facility. 108Ag; deduced high-spin levels, J, π, bands, multipolarities, configurations, signature splitting and signature inversion, staggering parameter. Total Routhian surface (TRS) calculations. Systematics of level energies, staggering parameter, B(M1)/B(E2) ratios, kinematic moments of inertial for bands in 98,100Tc, 104,106Rh, 106,108Ag, and comparison with behavior of chiral partner bands.
doi: 10.1103/PhysRevC.88.037301
2012QI14 Chin.Phys.C 36, 958 (2012) B.Qi, P.Zhang, J.Zhang, J.Fu, Y.-Q.Li, H.-H.Song, S.-Y.Wang Description of the candidate chiral doublet bands in 98Tc NUCLEAR STRUCTURE 98Tc; calculated energy spectra of the two lowest bands, B(M1)/B(E2), total angular momentum; deduced properties of chiral doublet bands candidates. Triaxial particle rotor model, comparison with available data.
doi: 10.1088/1674-1137/36/10/007
2012WA34 Phys.Rev. C 86, 064302 (2012) S.Y.Wang, D.P.Sun, B.Qi, Z.Q.Chen, X.B.Hu, G.Wang, C.Liu, C.J.Xu, L.Liu, P.Zhang, Z.Q.Li, M.Z.Guo, Y.Y.Cai, Y.Q.Li, S.Y.Liu, S.M.Wyngaardt, L.H.Zhu, X.G.Wu, C.Y.He, Y.Zheng, G.S.Li Collective and noncollective states in 116Sb NUCLEAR REACTIONS 114Cd(7Li, 5n), E=48 MeV; measured Eγ, Iγ, γγ-coin, γγ(θ)(DCO). 116Sb; deduced high-spin levels, J, π, alignments, B(M1), B(E2), bands, configurations. Systematics of first 2+ states in even-even Sn (A=108-118) nuclei, and 8-, 10- and 11+ states in odd-odd Sb (A=110-120) nuclei. Comparison with triaxial particle rotor model calculations.
doi: 10.1103/PhysRevC.86.064302
2012XU07 Phys.Rev. C 86, 027302 (2012), Erratum Phys.Rev. C 102, 069901 (2020) C.J.Xu, S.Y.Wang, C.Y.Niu, C.Liu, B.Qi, D.P.Sun, L.Liu, P.Zhang, Z.Q.Li, Z.Wang, X.G.Wu, G.S.Li, C.Y.He, Y.Zheng, B.B.Yu, C.B.Li, S.P.Hu, S.H.Yao, X.P.Cao, J.L.Wang High-spin states in near-spherical 88Y NUCLEAR REACTIONS 82Se(11B, 5n)88Y, E=48, 52 MeV; measured Eγ, Iγ, γγ-coin, γ(θ), ADO ratios. 88Y; deduced high-spin levels, J, π, multipolarity, bands, configurations. Comparison with semiempirical shell-model (SESM) calculations.
doi: 10.1103/PhysRevC.86.027302
2012ZH27 Eur.Phys.J. A 48, 91 (2012) On gauge invariant nucleon spin decomposition
doi: 10.1140/epja/i2012-12091-8
2006YU04 Int.J.Mod.Phys. E15, 939 (2006) M.Yu, P.-F.Zhang, T.-N.Ruan, J.-Y.Guo Shape evolution for Ce isotopes in relativistic mean-field theory NUCLEAR STRUCTURE 120,122,124,126,128,130,132,134,136,138,140,142Ce; calculated binding energies, potential energy surfaces, single-particle energies, deformation. Relativistic mean-field approach.
doi: 10.1142/S0218301306004661
1998LI51 Chin.Phys.Lett. 15, 796 (1998) E.-K.Lin, C.-W.Wang, J.Yuan, X.-D.Liu, C.-B.Li, Z.-X.Sun, P.-H.Zhang, J.-X.Chen, Q.-X.Yang, J.-Y.Wang, L.-H.Gong Experimental Study of p-11B Reaction Related to the Clean Fusion Fuel NUCLEAR REACTIONS 11B(p, α), E=667, 1370 keV; measured α spectra, σ(Eα, θ), σ; deduced sequential decay process features. Three-body sequential decay, Monte Carlo calculations.
doi: 10.1088/0256-307X/15/11/006
1996YU04 Chin.J.Nucl.Phys. 18, No 1, 21 (1996) J.Yuan, H.Li, Z.Sun, G.Tang, Z.Shi, J.Chen, L.Gong, P.Zhang Study of p-11B Reaction Associated with Clean Fusion Fuel NUCLEAR REACTIONS 11B(p, α), E=0.165-2.58 MeV; analyzed α-spectra following 8Be breakup; deduced breakup σ, hydrogen-boron clean fusion fuel relation implications.
1995ZH25 Chin.Phys.Lett. 12, 148 (1995) L.Zhu, Z.Huang, L.Hou, D.Ding, P.Zhang, Z.Zhao Study of Giant Dipole Resonance in Hot Rotating Nucleus 132Ce NUCLEAR REACTIONS 116Sn(16O, X), E=85 MeV; measured γ multiplicity distribution. 132Ce deduced deformation parameter spin dependence, GDR parameters. Hot rotating nucleus.
1993LI60 Z.Phys. D25, 103 (1993) G.Z.Li, P.Zhang, X.Feng, G.Werth Collisional Relaxation Measurements on Pb+ Hyperfine Levels
doi: 10.1007/BF01450160
1993MO28 Nucl.Instrum.Methods Phys.Res. A334, 437 (1993) C.P.Montoya, S.Schadmand, R.Varma, P.H.Zhang, R.Butsch, I.Dioszegi, D.J.Hofman, P.Paul An Electron-Positron Pair Spectrometer for High Energy Decays of Nuclei RADIOACTIVITY 8Li(β-) [from 7Li(d, p)]; measured β-decay end point energy; deduced detector calibration. Segmented phoswich plastic scintillator array (e+, e-) pair spectrometer. NUCLEAR REACTIONS 19F(p, α), E=5.2 MeV; measured Eγ, Iγ, for GDR region in 20Ne; deduced spectrometer efficiency. Segmented phoswich plastic scintillator array (e+, e-) pair spectrometer.
doi: 10.1016/0168-9002(93)90805-R
1991MO21 Z.Phys. A340, 371 (1991) C.P.Montoya, S.Schadmand, I.Dioszegi, D.J.Hofman, P.H.Zhang, P.Paul Giant Monopole Resonances in the Statistical Model NUCLEAR STRUCTURE 110Sn; calculated (e+e-)-pair decay of isoscalar, isovector giant monopole resonance decay; deduced GDR role.
doi: 10.1007/BF01290324
1988YU01 Chin.J.Nucl.Phys. 10, 39 (1988) Yuan Rongfang, Wen Keling, Wang Zhifu, Yuan Jian, Zhang Peihua, Xu Jianping, Mao Zhiqiang, Bao Xiuming, Wang Yuanda, Wang Jianan, Sun Zuxun Study of (α, p) Three Nucleon Transfer Reactions on Odd A Nuclei in 1f7/2 Shell NUCLEAR REACTIONS 51V, 55Mn(α, p), E=25.7 MeV; measured σ(θ). 54Cr, 58Fe levels deduced transfer angular momentum characteristics. DWBA, quasitriton.
1986CH35 Nucl.Phys. A459, 239 (1986) A.E.Champagne, M.L.Pitt, P.H.Zhang, L.L.Lee, Jr., M.J.Levine Proton-Threshold States in 28Si NUCLEAR REACTIONS 27Al(3He, d), E=20 MeV; 27Al(α, t), E=40 MeV; measured σ(θ). 28Si deduced levels, J, π, L, Γp, resonance strengths. Natural target.
doi: 10.1016/0375-9474(86)90065-5
1986ST03 Phys.Rev. C33, 1420 (1986) J.Stachel, P.Braun-Munzinger, R.H.Freifelder, P.Paul, S.Sen, P.DeYoung, P.H.Zhang, T.C.Awes, F.E.Obenshain, F.Plasil, G.R.Young, R.Fox, R.Ronningen Pion Production: A probe for coherence in medium-energy heavy-ion collisions NUCLEAR REACTIONS Ni, 27Al(14N, π0X), E=35 MeV/nucleon; 27Al, Ni(16O, π0X), E=25 MeV/nucleon; measured inclusive pion production σ(θ(π), E(π)), invariant pion mass; deduced pion production, reabsorption mechanisms.
doi: 10.1103/PhysRevC.33.1420
1984BR01 Phys.Rev.Lett. 52, 255 (1984) P.Braun-Munzinger, P.Paul, L.Ricken, J.Stachel, P.H.Zhang, G.R.Young, F.E.Obenshain, E.Grosse Pion Production in Heavy-Ion Collisions at E(Lab)/A = 35 MeV NUCLEAR REACTIONS 27Al, Ni, W(14N, π0X), E=35 MeV/nucleon; measured γγ-coin following pion decay, pion production σ vs mass; deduced many nucleon role in reaction mechanism.
doi: 10.1103/PhysRevLett.52.255
1983ZH09 Chin.J.Nucl.Phys. 5, 1 (1983) Zhang Peihua, Wen Keling, Li Shuming, Bao Xiumin, Shi Yijin, Sun Zuxun Study of QFS Mechanism in 9Be, 12C(α, 2α) Reactions at Low Energy NUCLEAR REACTIONS 9Be, 12C(α, 2α), E=18 MeV; measured σ(θ1, θ2, E1). 9Be, 12C deduced α-particle momentum distribution width, clustering probability. Quasifree scattering, generator coordinate method.
1982WE15 Chin.J.Nucl.Phys. 4, 289 (1982) Wen Keling, Zhang Peihua, Sun Zuxun The Effect of α - α Final State Interaction on (α, 2α) Quasi-Free Scattering NUCLEAR REACTIONS 6Li(α, 2α), E=8, 8.5 MeV; analyzed σ(E1, θ1, θ2); deduced final state interaction effects. Plane wave impulse approximation, quasifree scattering.
1980YE02 Chin.J.Nucl.Phys. 2, 147 (1980) Ye Binqi, Wen Keling, Zhang Peihua, Yuan Rongfang, Huang Bingyin Interaction of 9.05 MeV Deuterons on 7Li Nucleus NUCLEAR REACTIONS 7Li(d, p), (d, d), (d, t), E=9.05 MeV; measured σ(θ); deduced reaction mechanism. Optical model, zero-range DWBA analysis.
1980ZH05 Chin.J.Nucl.Phys. 2, 219 (1980) Zhang Peihua, Sun Zuhsun, Wen Keling, Wang Fanglin, Wang Shumao Quasi-free Scattering in 6,7Li(α, 2α)2,3H Reactions at Low Energy NUCLEAR REACTIONS 6,7Li(α, 2α), E=18 MeV; measured αα(θ); deduced quasifree scattering effect. 6,7Li deduced cluster probalities. PWIA, on-shell approximation.
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