NSR Query Results
Output year order : Descending NSR database version of April 24, 2024. Search: Author = R.G.Markham Found 20 matches. 1979AU05 Phys.Rev. C19, 1186 (1979) S.M.Austin, E.Kashy, C.H.King, R.G.Markham, I.Redmount, R.M.Ronningen Ratios of Cross Sections for Elastic Scattering of 30.3 MeV Protons from 40,44,48Ca NUCLEAR REACTIONS 40,44,48Ca(p, p), E=30.3 MeV; measured ratios of σ(θ). Mixed target, kinematic shift technique with split-pole spectrograph. Optical model analysis.
doi: 10.1103/PhysRevC.19.1186
1979BA11 Nucl.Phys. A315, 493 (1979) A.M.Bastawros, C.L.Bennett, H.W.Fulbright, R.G.Markham The 64Ni(6Li, d)68Zn Reaction NUCLEAR REACTIONS 64Ni(6Li, d), E=28 MeV; measured σ(θ). 68Zn levels deduced S. DWBA analysis. Compared with shell model, interacting boson approximation model.
doi: 10.1016/0375-9474(79)90625-0
1979IW01 Lett.Nuovo Cim. 26, 138 (1979) Y.Iwasaki, E.Kashy, R.G.Markham The (p, t0) Angular Distribution with Deep Minima and the Geometrical Aspect of the DWBA Calculation NUCLEAR REACTIONS 54Fe, 50Ti(p, t), E=40 MeV; 48Ca(p, t), E=39 MeV; calculated σ(θ); deduced optical model parameters, reaction parameters. DWBA analysis.
doi: 10.1007/BF02746599
1979IW03 Phys.Rev. C20, 861 (1979) Y.Iwasaki, G.M.Crawley, R.G.Markham, J.E.Finck, J.H.Kim Octupole States in 63Cu and the Weak-Coupling Picture NUCLEAR REACTIONS 63Cu(p, p'), E=400 MeV; measured σ(Ep', θ). 63Cu deduced levels, octupole transitions. Weak coupling model.
doi: 10.1103/PhysRevC.20.861
1978SM05 Phys.Rev. C18, 2065 (1978) P.A.Smith, J.A.Nolen, Jr., R.G.Markham, M.A.M.Shahabuddin 52Cr(p, α)49V Reaction NUCLEAR REACTIONS 52Cr(p, α), E=35 MeV; measured σ(θ). 49V deduced levels. Studied reaction mechanism.
doi: 10.1103/PhysRevC.18.2065
1977FU03 Nucl.Phys. A284, 329 (1977) H.W.Fulbright, C.L.Bennett, R.A.Lindgren, R.G.Markham, S.C.McGuire, G.C.Morrison, U.Strohbusch, J.Toke Four-Nucleon Transfer via the (6Li, d) Reaction NUCLEAR REACTIONS 40,42,44,48Ca, 50Ti, 50,52,54Cr, 54,56Fe, 58,60,62Ni, 90Zr(6Li, d), E=28-38 MeV; measured σ(Ed, θ). 44Ti, 54,58,56Fe, 58,60Ni, 62,64,66Zn deduced levels, Sα, L, J, π. DWBA analysis.
doi: 10.1016/0375-9474(77)90127-0
1977PA27 Phys.Lett. 71B, 301(1977) R.Pardo, R.G.Markham, W.Benenson, A.I.Galonsky, E.Kashy Excitation of Giant Resonance in 90Zr by Inelastic 6Li Scattering NUCLEAR REACTIONS 90Zr(6Li, 6Li'), E=74 MeV; measured σ(θ). 90Zr deduced giant resonance, width.
doi: 10.1016/0370-2693(77)90221-0
1976GU03 Phys.Rev. C13, 540 (1976) A.Guichard, W.Benenson, R.G.Markham, H.Nann 48Ti(p, 3He)46Sc Reaction NUCLEAR REACTIONS 48Ti(p, 3He), E=40.2 MeV; measured σ(E(3He), θ). 46Sc deduced levels, L, J, π.
doi: 10.1103/PhysRevC.13.540
1976MA46 Nucl.Phys. A270, 489 (1976) R.G.Markham, S.M.Austin, M.A.M.Shahabuddin A Measurement of Γ(rad)/Γ for the 7.654 MeV State of 12C and the Rate Of the Stellar 3α Reaction NUCLEAR REACTIONS 12C(α, α'), E=40.2 MeV; measured 12C'α-coin, recoil 12C(θ). 12C level deduced Γrad/Γ. Stellar He burning. Enriched target.
doi: 10.1016/0375-9474(76)90458-9
1976MA50 Phys.Rev. C14, 2037 (1976) R.G.Markham, M.A.M.Shahabuddin Finite-Range Distorted-Wave Born-Approximation Study of the (4He, 6Li) Reaction on 12C, 24Mg, and 40Ca NUCLEAR REACTIONS 12C, 24Mg, 40Ca(α, 6Li), E=46 MeV; measured σ(E(6Li), θ). Finite-range DWBA analysis with microscopic wave functions.
doi: 10.1103/PhysRevC.14.2037
1975DE03 Phys.Lett. 55B, 33 (1975) R.M.DeVries, H.W.Fulbright, R.G.Markham, U.Strohbusch Possible Nuclear Structure Effects Seen in (6Li, d) f-p Shell Reactions NUCLEAR REACTIONS 40,42,44,48Ca, 50Ti, 90Zr(6Li, d), E=32 MeV; 50Cr, 54,56Fe, 58,60,62Ni(6Li, d), E=28 MeV; calculated σ.
doi: 10.1016/0370-2693(75)90180-X
1975FU02 Phys.Lett. 53B, 449 (1975) H.W.Fulbright, U.Strohbusch, R.G.Markham, R.A.Lindgren, G.C.Morrison, S.C.McGuire, C.L.Bennett (6Li, d) Spectroscopy in the f-p Shell NUCLEAR REACTIONS 40,42,44,48Ca, 50Ti, 52Cr, 54,56Fe, 58,60,62Ni, 90Zr(6Li, d), E=28, 32 MeV; measured σ(Ed, θ). 58Ni levels deduced J.
doi: 10.1016/0370-2693(75)90215-4
1975GU19 Phys.Rev. C12, 1780 (1975) A.Guichard, W.Benenson, R.G.Markham, H.Nann 52Cr(p, 3He)50V Reaction NUCLEAR REACTIONS 52Cr(p, 3He), E=40.2 MeV; measured σ(E(3He), θ). 50V deduced levels, L, J, π.
doi: 10.1103/PhysRevC.12.1780
1975MO26 Phys.Lett. 58B, 286 (1975) A.Moalem, M.A.M.Shahabuddin, R.G.Markham, H.Nann Splitting of the Lowest T = 2 States in 44Ti, 48Cr and 52Fe NUCLEAR REACTIONS 46Ti, 50Cr, 54Fe(p, t), E=46.0 MeV; measured σ(Et, θ). 44Ti, 48Cr deduced level splitting.
doi: 10.1016/0370-2693(75)90654-1
1974LI01 Phys.Lett. 48B, 209 (1974) R.A.Lindgren, R.G.Markham, H.W.Fulbright The 6Li-Induced Three-Nucleon Transfer Reaction on 40Ca NUCLEAR REACTIONS 40Ca(6Li, 3He), (6Li, t), E=34.0, 36.0 MeV; measured σ(E(3He), E(3H), θ). 43Sc, 43Ti deduced levels, L, J, π, S.
doi: 10.1016/0370-2693(74)90012-4
1974MA09 Phys.Rev. C9, 1633 (1974) Structure of 113In Studied via the Reactions 115In(p, t)113In, 112Cd(3He, d)113In, and 112Cd(4He, t)113In NUCLEAR REACTIONS 115In(p, t), E=17, 19 MeV; 112Cd(3He, d), (α, t), E=27 MeV; measured σ(θ). 113In levels deduced J, π, S. Enriched targets, spectrograph, DWBA analysis.
doi: 10.1103/PhysRevC.9.1633
1974ST03 Phys.Rev. C9, 965 (1974) U.Strohbusch, C.L.Fink, B.Zeidman, R.G.Markham, H.W.Fulbright, R.N.Horoshko (6Li, d) Reaction on 40Ca NUCLEAR REACTIONS 40Ca(6Li, d), E=32 MeV; measured σ(Ed, θ). 44Ti deduced levels, J, π, S.
doi: 10.1103/PhysRevC.9.965
1973MA05 Nucl.Phys. A203, 244 (1973) The 65Cu(p, t)63Cu Reaction and the Structure of 63Cu NUCLEAR REACTIONS 65Cu(p, t)63Cu, E=18.0, 19.5; measured σ(Et, θ). 63Cu deduced J, π for two levels.
doi: 10.1016/0375-9474(73)90133-4
1972GU12 Phys.Rev.Lett. 29, 808 (1972) (6Li, d) on 58Ni and 64Ni NUCLEAR REACTIONS 58,64Ni(6Li, d), E=38 MeV; measured σ(Ed, θ). 62,68Zn deduced levels, J, π.
doi: 10.1103/PhysRevLett.29.808
1972LI24 Phys.Rev.Lett. 29, 798 (1972) R.A.Lindgren, H.H.Gutbrod, H.W.Fulbright, R.G.Markham Odd-Parity Three-Particle, One-Hole Structure in 18F via the Reaction 15N(6Li, t)18F NUCLEAR REACTIONS 15N(6Li, t), E=30 MeV; measured σ(Et, θ). 18F deduced odd-parity, 3p-1h structure.
doi: 10.1103/PhysRevLett.29.798
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