NSR Query Results
Output year order : Descending NSR database version of April 27, 2024. Search: Author = X.Ding Found 28 matches. 2023BA34 Phys.Rev. D 108, 102005 (2023) D.Basilico, G.Bellini, J.Benziger, R.Biondi, B.Caccianiga, F.Calaprice, A.Caminata, A.Chepurnov, D.D'Angelo, A.Derbin, A.Di Giacinto, V.Di Marcello, X.F.Ding, A.Di Ludovico, L.Di Noto, I.Drachnev, D.Franco, C.Galbiati, C.Ghiano, M.Giammarchi, A.Goretti, M.Gromov, D.Guffanti, A.Ianni, A.Ianni, A.Jany, V.Kobychev, G.Korga, S.Kumaran, M.Laubenstein, E.Litvinovich, P.Lombardi, I.Lomskaya, L.Ludhova, I.Machulin, J.Martyn, E.Meroni, L.Miramonti, M.Misiaszek, V.Muratova, R.Nugmanov, L.Oberauer, V.Orekhov, F.Ortica, M.Pallavicini, L.Pelicci, O.Penek, L.Pietrofaccia, N.Pilipenko, A.Pocar, G.Raikov, M.T.Ranalli, G.Ranucci, A.Razeto, A.Re, N.Rossi, S.Schonert, D.Semenov, G.Settanta, M.Skorokhvatov, A.Singhal, O.Smirnov, A.Sotnikov, R.Tartaglia, G.Testera, E.Unzhakov, F.L.Villante, A.Vishneva, R.B.Vogelaar, F.von Feilitzsch, M.Wojcik, M.Wurm, S.Zavatarelli, K.Zuber, G.Zuzel, for the Borexino Collaboration Final results of Borexino on CNO solar neutrinos
doi: 10.1103/PhysRevD.108.102005
2023WU06 At.Data Nucl.Data Tables 154, 101602 (2023) C.Wu, X.Ding, M.Cao, D.Zhang, M.Zhang, Y.Xue, D.Yu, C.Dong Energy levels and radiative transition properties of the 2s2p double K-shell vacancy state in He-like ions (4 ≤ Z ≤ 54) ATOMIC PHYSICS Z=4-54; calculated energy levels, transition energies and rates, oscillator strengths using the multi-configuration Dirac-Hartree-Fock methods. Comparison with available data.
doi: 10.1016/j.adt.2023.101602
2022LI33 Nucl.Phys. A1024, 122476 (2022) B.Li, F.Pan, X.-X.Ding, J.P.Draayer Transitional patterns in the spherical mean-field plus quadrupole-quadrupole and pairing model within two-j shells
doi: 10.1016/j.nuclphysa.2022.122476
2021DI06 Nucl.Phys. A1014, 122237 (2021) Neutron drop trapped in axially deformed external fields NUCLEAR STRUCTURE N=28; calculated energy levels, J, π using an axially symmetric harmonic oscillator (ASHO) potential within the Skyrme HFB model.
doi: 10.1016/j.nuclphysa.2021.122237
2020LI22 Int.J.Mod.Phys. E29, 2050039 (2020) B.Li, F.Pan, X.-X.Ding, J.P.Draayer Quantum phase crossover in the spherical mean-field plus quadrupole-quadrupole and pairing model with two j-orbits NUCLEAR STRUCTURE 103,104,105,106,107,108,109,110Sn; calculated level energies, J, π, B(Eλ) ratios; deduced parameters.
doi: 10.1142/S0218301320500391
2019CA17 Phys.Rev. C 100, 015501 (2019) N.Callahan, C.-Y.Liu, F.Gonzalez, E.Adamek, J.D.Bowman, L.Broussard, S.M.Clayton, S.Currie, C.Cude-Woods, E.B.Dees, X.Ding, W.Fox, P.Geltenbort, K.P.Hickerson, M.A.Hoffbauer, A.T.Holley, A.Komives, S.W.T.MacDonald, M.Makela, C.L.Morris, J.D.Ortiz, R.W.Pattie, J.Ramsey, D.J.Salvat, A.Saunders, E.I.Sharapov, S.K.L.Sjue, Z.Tang, J.Vanderwerp, B.Vogelaar, P.L.Walstrom, Z.Wang, H.Weaver, W.Wei, J.Wexler, A.R.Young Monte Carlo simulations of trapped ultracold neutrons in the UCNt experiment RADIOACTIVITY 1n(β-); calculated neutron dynamics, trajectory and neutron detection rate in Ultra-cold neutron (UCN) magneto-gravitational neutron trap by developing an in-depth Monte Carlo model for the UCNτ experiments. Discussed implications of chaotic dynamics on controlling the systematic effects, such as spectral cleaning and microphonic heating, for a successful UCN lifetime experiment to reach 0.01% level of precision.
doi: 10.1103/PhysRevC.100.015501
2018IT01 Phys.Rev. C 97, 012501 (2018) T.M.Ito, E.R.Adamek, N.B.Callahan, J.H.Choi, S.M.Clayton, C.Cude-Woods, S.Currie, X.Ding, D.E.Fellers, P.Geltenbort, S.K.Lamoreaux, C.-Y.Liu, S.MacDonald, M.Makela, C.L.Morris, R.W.Pattie, J.C.Ramsey, D.J.Salvat, A.Saunders, E.I.Sharapov, S.Sjue, A.P.Sprow, Z.Tang, H.L.Weaver, W.Wei, A.R.Young Performance of the upgraded ultracold neutron source at Los Alamos National Laboratory and its implication for a possible neutron electric dipole moment experiment RADIOACTIVITY 1n(β-); measured cold neutron time of arrival (TOA) spectrum, UCN density, dUCNcounts normalized to the UCN monitor detector near the exit of the biological shield using upgraded ultracold neutron (UCN) source at Los Alamos National Laboratory. Discussed implication for a possible neutron electric dipole moment (EDM) experiment.
doi: 10.1103/PhysRevC.97.012501
2018PA18 Nucl.Phys. A974, 86 (2018) F.Pan, X.Ding, K.D.Launey, J.P.DraayerJ.P.Draayer A simple procedure for construction of the orthonormal basis vectors of irreducible representations of O(5) in the OT(3) (X) ON (2) basis
doi: 10.1016/j.nuclphysa.2018.03.011
2018PA53 Science 360, 627 (2018) R.W.Pattie, N.B.Callahan, C.Cude-Woods, E.R.Adamek, L.J.Broussard, S.M.Clayton, S.A.Currie, E.B.Dees, X.Ding, E.M.Engel, D.E.Fellers, W.Fox, P.Geltenbort, K.P.Hickerson, M.A.Hoffbauer, A.T.Holley, A.Komives, C.-Y.Liu, S.W.T.MacDonald, M.Makela, C.L.Morris, J.D.Ortiz, J.Ramsey, D.J.Salvat, A.Saunders, S.J.Seestrom, E.I.Sharapov, S.K.Sjue, Z.Tang, J.Vanderwerp, B.Vogelaar, P.L.Walstrom, Z.Wang, W.Wei, H.L.Weaver, J.W.Wexler, T.L.Womack, A.R.Young, B.A.Zeck Measurement of the neutron lifetime using a magneto-gravitational trap and in situ detection RADIOACTIVITY 1NN(β-); measured T1/2 of free neutron using ultracold neutrons stored in a magneto-gravitational trap at the Los Alamos Neutron Science Center UCN facility. Comparison with previous measurements.
doi: 10.1126/science.aan8895
2017DI13 At.Data Nucl.Data Tables 119, 354 (2017) X.-b.Ding, R.Sun, F.Koike, I.Murakami, D.Kato, H.A.Sakaue, N.Nakamura, C.-z.Dong Energy levels, lifetimes and radiative data of W LV ATOMIC PHYSICS W; calculated energy levels, radiative data and lifetimes for tungsten Ca-like ion (W LV) by using multi-configuration Dirac-Fock (MCDF) method.
doi: 10.1016/j.adt.2017.02.002
2017KW02 At.Data Nucl.Data Tables 119, 250 (2017) D.-H.Kwon, W.Lee, S.Preval, C.P.Ballance, E.Behar, J.Colgan, C.J.Fontes, T.Nakano, B.Li, X.Ding, C.Z.Dong, Y.B.Fu, N.R.Badnell, M.O'Mullane, H.-K.Chung, B.J.Braams Iso-nuclear tungsten dielectronic recombination rates for use in magnetically-confined fusion plasmas ATOMIC PHYSICS W; analyzed dielectronic recombination (DR) rate coefficients for various ion stages of tungsten (W).
doi: 10.1016/j.adt.2017.04.002
2016PA05 Nucl.Phys. A947, 234 (2016) F.Pan, X.Ding, K.D.Launey, H.Li, X.Xu, J.P.Draayer An exactly solvable spherical mean-field plus extended monopole pairing model NUCLEAR STRUCTURE 12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28O; calculated neutron single-particle energy, J, π using spherical shell model, pairing strength vs mass number, gs energy, mass excess vs mass number.
doi: 10.1016/j.nuclphysa.2016.01.004
2008DI02 Chinese Physics B 17, 592 (2008) X.-B.Ding, C.-Z.Dong, F.Koike, T.Kato, S.Fritzsche Excitation and decay dynamics of 1s2s inner-shell double-vacancy states of neon atoms
doi: 10.1088/1674-1056/17/2/039
2007BA76 Chin.Phys.Lett. 24, 3384 (2007) Z.Bai, Q.Wang, J.-L.Han, ZG.Xiao, H.-S.Xu, Z.-Y.Sun, Z.-G.Hu, X.-Y.Zhang, H.-W.Wang, R.-S.Mao, X-H.Yuan, Z.-G.Xu, H.-B.Zhang, H.-G.Xu, H.-R.Qi, Y.Wang, F.Jia, L.-J.Wu, X.-L.Ding, Q.Gao, H.Gao, S.-L.Li, J.-Q.Li, Y.-P.Zhang, G.-Q.Xiao, G.-M.Jin, Z.-Z.Ren, S.-G.Zhou, W.Xu, G.-T.Fan, S.-Q.Zhang, D.-Y.Pang, Y.-K.Sergey Angular Dispersion and Deflection Function for Heavy Ion Elastic Scattering NUCLEAR REACTIONS 208Pb(17F, 17F), E=141 MeV; 208Pb(17O, 17O), E=128 MeV; measured differential cross sections, angular dispersion plots. 208Pb(16O, 16O), E=170.1 MeV; 208Pb(6He, 6He), E=27, 29.6 MeV; 208Pb(6Li, 6Li), E=73.7, 99 MeV; 208Pb(α, α), E=40 MeV; analyzed differential cross sections, angular dispersion plots.
doi: 10.1088/0256-307X/24/12/027
2007LI01 Chin.Phys.Lett. 24, 83 (2007) Resonance Energies, Absorption Oscillator Strengths and Ionization Potentials for the Element Hassium (Z = 108) ATOMIC PHYSICS Hs; calculated resonance energies, absorption oscillator strengths, ionization potentials. Multiconfiguration Dirac-Fock method.
doi: 10.1088/0256-307X/24/1/023
2007LO05 Phys.Rev. C 75, 057302 (2007) J.L.Lou, Z.H.Li, Y.L.Ye, H.Hua, D.X.Jiang, L.H.Lv, Z.Kong, Y.M.Zhang, F.R.Xu, T.Zheng, X.Q.Li, Y.C.Ge, C.Wu, G.L.Zhang, Z.Q.Chen, C.Li, D.Y.Pang, H.S.Xu, Z.Y.Sun, L.M.Duan, Z.G.Hu, R.J.Hu, H.G.Xu, R.S.Mao, Y.Wang, X.H.Yuan, H.Gao, L.J.Wu, H.R.Qi, T.H.Huang, F.Fu, F.Jia, Q.Gao, X.L.Ding, J.L.Han, X.Y.Zhang Observation of a new transition in the beta-delayed neutron decay of 18N RADIOACTIVITY 18N(β-); measured β-delayed neutron spectra. 18O; deduced level energies, J, π. Deduced B(GT), compared to shell model calculations.
doi: 10.1103/PhysRevC.75.057302
2007ZH34 Nucl.Sci.Eng. 157, 354 (2007) H.Zhou, F.Deng, X.Ding, M.Hua, Q.Zhu, C.Wang, Q.Zhao, G.Fan Discrete Gamma Radiation in Interaction of 14.9-MeV Neutrons with Natural Copper NUCLEAR REACTIONS 63Cu(n, n'), (n, 2n), (n, np), (n, d), (n, p), (n, α), E=14.9 MeV; 65Cu(n, n'), (n, 2n), (n, np), (n, d), (n, p), E=14.9 MeV; measured Eγ, Iγ, and cross sections.
doi: 10.13182/NSE07-A2733
2006WA17 Chin.Phys.Lett. 23, 1731 (2006) Q.Wang, J.-L.Han, Z.-G.Xiao, H.-S.Xu, Z.-Yu.Sun, Z.-G.Hu, X.-Y.Zhang, H.-W.Wang, R.-S.Mao, X.-H.Yuan, Z.-G.Xu, T.-C.Zhao, H.-B.Zhang, H.-G.Xu, H.-R.Qi, Y.Wang, F.Jia, L.-J.Wu, X.-L.Ding, Q.Gao, H.Gao, S.-L.Li, Z.Bai, G.-Q.Xiao, G.-M.Jin, Z.-Z.Ren, S.-G.Zhou, Yu.-K.Sergey Exotic Behaviour of Angular Dispersion of Weakly Bound Nucleus 17F at Small Angles NUCLEAR REACTIONS 208Pb(17F, 17F), E=141 MeV; 208Pb(17O, 17O), E=128 MeV; measured σ(θ); deduced possible halo effects.
doi: 10.1088/0256-307X/23/7/021
2005LI60 Phys.Rev. C 72, 064327 (2005) Z.H.Li, Y.L.Ye, H.Hua, D.X.Jiang, Y.M.Zhang, F.R.Xu, Q.Y.Hu, G.L.Zhang, Z.Q.Chen, T.Zheng, C.E.Wu, J.L.Lou, X.Q.Li, D.Y.Pang, S.Wang, C.Li, H.S.Xu, Z.Y.Sun, L.M.Duan, Z.G.Hu, R.J.Hu, H.G.Xu, R.S.Mao, Y.Wang, X.H.Yuan, H.Gao, L.J.Wu, H.R.Qi, T.H.Huang, F.Fu, F.Jia, Q.Gao, X.L.Ding, J.L.Han, X.Y.Zhang β-decay of the neutron-rich nucleus 18N RADIOACTIVITY 18N(β-), (β-n) [from Be(22Ne, X)]; measured T1/2, β-delayed neutron spectra, Eγ, Iγ; deduced branching ratios, Gamow-Teller strengths. 18O deduced levels, J, π. Comparison with shell model calculations.
doi: 10.1103/PhysRevC.72.064327
1994YE02 Chin.Phys.Lett. 11, 12 (1994) Z.Ye, Y.Li, S.Ding, Z.Bao, X.Yang, C.Rong, X.Ding, J.Zheng Modified Method for Efficiency Calibration of High Energy γ Detector NUCLEAR REACTIONS 23Na, 35,37Cl(n, γ), E=thermal; 19F(p, αγ), E not given; measured radiative capture γ spectra; deduced detector efficiency calibration. High energy Ge γ-detector, Am-Be source also studied.
doi: 10.1088/0256-307X/11/1/004
1992WA31 Nucl.Instrum.Methods Phys.Res. B71, 241 (1992) D.Wang, X.Ding, X.Wang, H.Yang, H.Zhou, X.Shen, G.Zhu X-Ray Attenuation Coefficients and Photoelectric Cross Sections of Cu and Fe in the Range 3 keV to 29 keV NUCLEAR REACTIONS 27Al, Si, K, I, Ti, 51V, Fe, Ni, Cu, 93Nb, Mo, Ag, Sn, 197Au, Pb(p, X), E=2.5 MeV; measured X-ray spectra; deduced photoelectric σ, X-ray attenuation coefficient. ATOMIC PHYSICS 27Al, Si, K, I, Ti, 51V, Fe, Ni, Cu, 93Nb, Mo, Ag, Sn, 197Au, Pb(p, X), E=2.5 MeV; measured X-ray spectra; deduced photoelectric σ, X-ray attenuation coefficient.
doi: 10.1016/0168-583X(92)95395-8
1992WA32 Nucl.Instrum.Methods Phys.Res. B71, 249 (1992) Measurements of Mass Attenuation Coefficients of Yttrium with Characteristic Lines from Elements Excited by Energetic Protons NUCLEAR REACTIONS 27Al, Si, K, Cl, 51V, Fe, Cu, Ni, Pb, 197Au, 89Y, 93Nb, Mo, Ag, In, Sb(p, X), E=2.5 MeV; measured X-ray spectra; deduced mass attenuation coefficients for Y. ATOMIC PHYSICS 27Al, Si, K, Cl, 51V, Fe, Cu, Ni, Pb, 197Au, 89Y, 93Nb, Mo, Ag, In, Sb(p, X), E=2.5 MeV; measured X-ray spectra; deduced mass attenuation coefficients for Y.
doi: 10.1016/0168-583X(92)95320-Q
1989ZH12 Chin.J.Nucl.Phys. 11, No.2, 63 (1989) H.Zhou, Y.Yan, L.Tang, C.Wen, S.Zhang, M.Hua, C.Han, X.Ding, L.Lan, G.Fan, H.Yan, X.Wang, Q.Wang, S.Sun, Y.Rong, S.Liu Production Cross Section Measurement of Discrete Gamma-Ray at 90° for Interactions of 14.9 MeV Neutrons with Carbon and Niobium NUCLEAR REACTIONS 93Nb, 12C(n, xγ), E=14.9 MeV; measured Eγ, Iγ, σ(θγ=90°); deduced γ production σ.
1988DI06 Chin.J.Nucl.Phys. 10, 222 (1988) F-Spin Wavefunction and Electromagnetic Transition in IBM-II NUCLEAR STRUCTURE 154Sm, 156,160,162Gd, 164Dy, 168Er, 174Yb; calculated levels, B(λ). Interacting boson model.
1988YA04 Chin.J.Nucl.Phys. 10, 166 (1988) Yan Yiming, Zhou Hongyu, Tang Lin, Wen Chenlin, Zhang Shengji, Hua Ming, Ding Xiaoji, Rong Yaning, Liu Shuzhen, Fu Jingquan, Lu Ting, Wang Qi, Sun Suxu, Lan Liqiao, Xu Jinkui, Wang Wanhong, Yang Hua, Han Chongzhan, He Peilun, Ye Wenxiang, Han Xiuqing A Facility for Measurements of γ-Ray Production Cross Sections from (n, xγ) Reactions using the Pulsed Neutron Source NUCLEAR REACTIONS 56Fe(n, n'γ), E=14.9 MeV; measured γγ(t), nγ(t); deduced γ production σ. Pulsed beam. Data from this article have been entered in the EXFOR database. For more information, access X4 dataset30904. 1987XI02 Chin.J.Nucl.Phys. 9, 94 (1987) Xia Yuanfu, Ruan Xiangdong, Ding Xiaoqi, Liu Rongchuan, Wang Shuxin A Mossbauer Research of Natural Iron with Applied High Field at Very Low Temperature NUCLEAR REACTIONS 57Fe(γ, γ), E=14.4 keV; measured Mossbauer spectra; deduced effective, hyperfine magnetic field relation. High field, very low temperature.
1986DI14 Chin.J.Nucl.Phys. 8, 234 (1986) F-Spin Breaking and Gd Isotopes Energy Spectra NUCLEAR STRUCTURE 154,156,158Gd; calculated levels. Interacting boson model.
1981SU10 Chin.J.Nucl.Phys. 3, 97 (1981) Su Zongdi, Ma Zhongyu, Zhou Chunmei, Ding Xunliang, Lu Zhongdao, Ding Dazhao The Measurements, Evaluations and the Theoretical Analyses of the Cross Sections for the Neutron Radiative Capture Reactions NUCLEAR REACTIONS 235,236,238U, 239Pu(n, γ), E ≈ 0.001-10 MeV; 238,240Pu(n, γ), E ≈ 0.001-0.3 MeV; 233U(n, γ), E ≈ 0.002-1 MeV; measured σ(E). 234,236,237,239U, 239,240,241Pu deduced neutron binding energy, average level widths. Statistical, direct semi-direct models.
Back to query form Note: The following list of authors and aliases matches the search parameter X.Ding: , X.B.DING, X.F.DING, X.L.DING, X.X.DING |