NSR Query Results
Output year order : Descending NSR database version of April 11, 2024. Search: Author = S.Zagromski Found 24 matches. 1998MO01 Phys.Rev. C57, 602 (1998) M.Moosburger, E.Aschenauer, H.Dennert, W.Eyrich, A.Lehmann, N.Scholz, H.Wirth, H.J.Gils, H.Rebel, S.Zagromski Excitation and Decay of the Gamow-Teller Giant Resonance in 90Nb NUCLEAR REACTIONS 90Zr(6Li, 6He), E=156 MeV; measured σ(θ), p(6He)-coin following residual nucleus decay. 90Nb deduced Gamow-Teller giant resonance E, Γ, decay branching ratios, statistical damping.
doi: 10.1103/PhysRevC.57.602
1995DE53 Phys.Rev. C52, 3195 (1995) H.Dennert, E.Aschenauer, W.Eyrich, A.Lehmann, M.Moosburger, N.Scholz, H.Wirth, H.J.Gils, H.Rebel, S.Zagromski Excitation of Giant Monopole Resonance in 24Mg using 6Li Scattering NUCLEAR REACTIONS 24Mg(6Li, 6Li'), E=156 MeV; measured σ(θ) at extreme forward angles. 24Mg deduced electric giant monopole resonance, strength distribution, centroid energy, width, sum rule values. DWBA calculations.
doi: 10.1103/PhysRevC.52.3195
1993SC02 Z.Phys. A344, 269 (1993) N.Scholz, E.Aschenauer, H.Dennert, W.Eyrich, A.Lehmann, M.Moosburger, H.Wirth, H.J.Gils, H.Rebel, S.Zagromski Proton Decay of Spin Isospin Modes Excited by the 12C(6Li, 6He)12N Reaction NUCLEAR REACTIONS 12C(6Li, 6He), (6Li, p6He), E=156 MeV; measured particle spectra, p(6He)-coin, σ(θp, θ(6He)). 12N levels deduced proton decay spin, isospin modes features.
doi: 10.1007/BF01303020
1992PA20 Rev.Roum.Phys. 37, 121 (1992) M.Parlog, D.Popescu, J.Wentz, S.Zagromski, I.M.Brancus, V.Corcalciuc, M.Duma, H.J.Gils, H.Rebel Intermediate Mass Fragment Emission in 104 MeV α + 46-Ti Reactions NUCLEAR REACTIONS 46Ti(α, X), E=104 MeV; measured σ(fragment θ, E), σ vs charge number; deduced intermediate fragment emission mechanism. Extended sum rule model analysis.
1991AS05 Phys.Rev. C44, 2771 (1991) E.Aschenauer, H.Dennert, W.Eyrich, A.Lehmann, M.Moosburger, H.Wirth, H.J.Gils, H.Rebel, S.Zagromski (6Li, 6He) Measurements as an Alternative Calibration for Solar Neutrino Detectors NUCLEAR REACTIONS 37Cl, 71Ga(6Li, 6He), E=156 MeV; measured σ(θ) vs E. 37Ar, 71Ge level deduced Gamow-Teller transition strength distribution. Solar neutrino detectors targets, magnetic spectrograph.
doi: 10.1103/PhysRevC.44.2771
1991KI07 Phys.Rev. C44, 2195 (1991) J.Kiener, H.J.Gils, H.Rebel, S.Zagromski, G.Gsottschneider, N.Heide, H.Jelitto, J.Wentz, G.Baur Measurements of the Coulomb Dissociation Cross Section of 156 MeV 6Li Projectiles at Extremely Low Relative Fragment Energies of Astrophysical Interest NUCLEAR REACTIONS 208Pb(6Li, dα), E=156 MeV; measured σ(θα, θd, E(dα)); deduced radiative capture σ, astrophysical S-factor. Coincidence measurements with magnetic spectrometer.
doi: 10.1103/PhysRevC.44.2195
1990MO13 Phys.Rev. C41, 2925 (1990) M.Moosburger, E.Aschenauer, H.Dennert, W.Eyrich, A.Lehmann, R.Rudeloff, H.Schlosser, H.Wirth, H.J.Gils, H.Rebel, S.Zagromski (6Li, 6He) Reaction and Gamow-Teller β Decay NUCLEAR REACTIONS 12C, 18O, 26Mg, 42Ca(6Li, 6He), E=156 MeV; measured σ(E, θ), σ(θ=0°); deduced relation between Gamow-Teller transition strength (β-decay), zero degree cross section. DWBA calculations. Magnetic spectrograph.
doi: 10.1103/PhysRevC.41.2925
1990WI08 Phys.Rev. C41, 2698 (1990) H.Wirth, E.Aschenauer, W.Eyrich, A.Lehmann, M.Moosburger, H.Schlosser, H.J.Gils, H.Rebel, S.Zagromski Investigation of Spin-Isospin Strength in 48Ca → 48Sc and 90Zr → 90Nb Using the (6Li, 6He) Reaction NUCLEAR REACTIONS 90Zr, 48Ca(6Li, 6He), E=156 MeV; measured σ(E, θ). 48Sc, 90Nb deduced Gamow-Teller strength, sum rule values. DWBA calculations. Magnetic spectrograph.
doi: 10.1103/PhysRevC.41.2698
1989GI01 Nucl.Instrum.Methods Phys.Res. A276, 169 (1989) H.J.Gils, H.Jelitto, H.Schlosser, S.Zagromski, J.Buschmann, W.Eyrich, A.Hofmann, J.Kiener, A.Lehmann, H.Rebel The QQDS Magnetic Spectrograph ' Little John ' at the Karlsruhe Cyclotron II. Experimental procedures and performance NUCLEAR REACTIONS 12C(6Li, 6Li), E=158 MeV; measured 6Li spectra. 208Pb, 12C(6Li, αX), E=156 MeV; measured σ(θα, Eα). 12C(6Li, 6Li'), E=156 MeV; measured σ(θ), σ(θ(6Li), E(6Li)). 12C(6Li, 6He), E=156 MeV; measured σ(θ(6He), E(6He)).
doi: 10.1016/0168-9002(89)90629-3
1989GR13 Phys.Lett. 223B, 287 (1989) K.Grotowski, J.Ilnicki, T.Kozik, J.Lukasik, S.Micek, Z.Sosin, A.Wieloch, N.Heide, H.Jelitto, J.Kiener, H.Rebel, S.Zagromski, A.J.Cole Compound Nucleus Emission of Intermediate Mass Fragments in the 6Li + Ag Reaction at 156 MeV NUCLEAR REACTIONS 46Ti, Cu, Ag(6Li, X), E=156 MeV; measured σ vs fragment Z, σ(θ) vs fragment Z; deduced reaction mechanism.
doi: 10.1016/0370-2693(89)91603-1
1989HE28 Nucl.Phys. A504, 374 (1989) N.Heide, H.Rebel, V.Corcalciuc, H.J.Gils, H.Jelitto, J.Kiener, J.Wentz, S.Zagromski, D.K.Srivastava Elastic Break-Up of 156 MeV 6Li Projectiles with Large Asymptotic Relative Momenta of the Fragments: Experimental observations and the diffractive disintegration approach NUCLEAR REACTIONS 12C, 208Pb(6Li, dα), E=156 MeV; measured σ(θd, θα, Eα). Diffractive dissociation model analysis.
doi: 10.1016/0375-9474(89)90352-7
1989JE01 Z.Phys. A332, 317 (1989) H.Jelitto, J.Buschmann, V.Corcalciuc, H.J.Gils, N.Heide, J.Kiener, H.Rebel, C.Samanta, S.Zagromski Inclusive Measurements of the Break-Up of 156 MeV 6Li-Ions at Extreme Forward Angles NUCLEAR REACTIONS 12C, 208Pb(6Li, αX), (6Li, dX), E=156 MeV; measured σ(θα), σ(θd), inclusive reaction σ(θα, Eα), σ(θd, Ed); deduced reaction, projectile breakup mechanisms.
1987EY01 Phys.Rev. C36, 416 (1987) W.Eyrich, A.Hofmann, A.Lehmann, B.Muhldorfer, H.Schlosser, H.Wirth, H.J.Gils, H.Rebel, S.Zagromski E0 Strength in 12C from 6Li Scattering NUCLEAR REACTIONS 12C(6Li, 6Li'), E=156 MeV; measured σ(E(6Li), θ), θ=0°-2.5°. 12C deduced E0 transition strength distribution, EWSR fraction. DWBA analysis.
doi: 10.1103/PhysRevC.36.416
1987JE03 Rev.Roum.Phys. 32, 629 (1987) H.Jelitto, H.J.Gils, H.Rebel, S.Zagromski Measurements of Light Particle Emission at very Forward Angles in 6Li Induced Nuclear Reactions at 26 MeV per Nucleon NUCLEAR REACTIONS, MECPD 12C, 208Pb(6Li, X), 208Pb(6Li, dα), E=156 MeV; measured light fragment σ(E(X), θ(X)), σ(θ(X)), αd-coin. Magnetic spectrograph.
1987KO15 Z.Phys. A326, 421 (1987) T.Kozik, J.Buschmann, K.Grotowski, H.J.Gils, N.Heide, J.Kiener, H.Klewe-Nebenius, H.Rebel, S.Zagromski, A.J.Cole, S.Micek Intermediate Mass Fragments in the Reaction 6Li + 46Ti at E/A = 26 MeV NUCLEAR REACTIONS 46Ti(6Li, X), E=156 MeV; measured σ(fragment θ, E) for fragment Z=4-11; deduced reaction mechanism. Enriched target, ΔE-E telescopes. Binary decay model.
1987MI34 Z.Phys. A328, 467 (1987) S.Micek, H.Rebel, H.J.Gils, H.Klewe-Nebenius, S.Zagromski, D.K.Srivastava Single Nucleon Transfer Reactions in 6Li + 6Li Collisions at 156 MeV NUCLEAR REACTIONS, MECPD 6Li(6Li, 7Li), (6Li, 7Be), E=156 MeV; measured σ(E(7Li)), σ(E(7Be)), σ(θ); deduced model parameters. Finite range DWBA calculations.
1986PL01 Nucl.Phys. A448, 110 (1986) R.Planeta, H.Klewe-Nebenius, J.Buschmann, H.J.Gils, H.Rebel, S.Zagromski, T.Kozik, L.Freindl, K.Grotowski The Nonelastic Projectile Break-Up Cross Section from Particle-Gamma Coincidence Measurements for the 6Li + 40Ca Reaction at 156 MeV NUCLEAR REACTIONS 40Ca(6Li, α), (6Li, 3He), (6Li, t), (6Li, d), (6Li, p), E=156 MeV; measured (fragment)γ-coin following breakup, inclusive, exclusive reactions; deduced projectile breakup σ.
doi: 10.1016/0375-9474(86)90183-1
1984BR04 Nucl.Phys. A417, 174 (1984) J.Brzychczyk, L.Freindl, K.Grotowski, Z.Majka, S.Micek, R.Planeta, M.Albinska, J.Buschmann, H.Klewe-Nebenius, H.J.Gils, H.Rebel, S.Zagromski Fusion and Nonfusion Phenomena in the 6Li + 40Ca Reaction at 156 MeV NUCLEAR REACTIONS 40Ca(6Li, X), (6Li, γ), E=156 MeV; measured σ(fragment θ, E), σ(fragment Z); deduced projectile breakup. Calculated σ(fusion).
doi: 10.1016/0375-9474(84)90329-4
1983PE10 Z.Phys. A313, 111 (1983) R.Pesl, H.J.Gils, H.Rebel, E.Friedman, J.Buschmann, H.Klewe-Nebenius, S.Zagromski Optical Potentials and Isoscalar Transition Rates from 104 MeV Alpha-Particle Scattering by the N = 28 Isotones 48Ca, 50Ti and 52Cr NUCLEAR REACTIONS 48Ca, 50Ti, 52Cr(α, α), (α, α'), E=104 MeV; measured σ(θ); deduced optical model, deformation parameters. 50Ti, 52Cr deduced rms charge radii, isoscalar transition rates. 48Ca deduced rms charge radii.
doi: 10.1007/BF02115849
1982CO09 Z.Phys. A305, 351 (1982) V.Corcalciuc, H.J.Gils, H.Rebel, J.Buschmann, R.Pesl, R.Dumitrescu, S.Zagromski, K.Feisst 104 MeV Alpha Particle Scattering from 90,92Zr NUCLEAR REACTIONS 90,92Zr(α, α), (α, α'), E=104 MeV; measured σ(θ). 90,92Zr deduced isoscalar quadrupole, hexadecapole transition rates. Anharmonic vibrator model, coupled-channels method.
doi: 10.1007/BF01419085
1982NE02 Nucl.Phys. A382, 296 (1982) B.Neumann, H.Rebel, H.J.Gils, R.Planeta, J.Buschmann, H.Klewe-Nebenius, S.Zagromski, R.Shyam, H.Machner Inclusive Break-Up Reactions of 6Li at an Incident Energy of 26 MeV/Nucleon NUCLEAR REACTIONS 40Ca(6Li, p), (6Li, d), (6Li, t), (6Li, 3He), (6Li, α), E=156 MeV; measured σ(θ) versus particle energy. DWBA, breakup, preequilibrium exciton coalescence models.
doi: 10.1016/0375-9474(82)90138-5
1980CO13 Rev.Roum.Phys. 25, 471 (1980) V.Corcalciuc, R.Dumitrescu, A.Ciocanel, H.J.Gils, H.Rebel, W.Stach, S.Zagromski On the Fine Structure of Inelastic Scattering Angular Distributions NUCLEAR REACTIONS 68Zn(3He, 3He), (3He, 3He'), E=29 MeV; measured σ(θ); deduced no fine structure.
1980GI02 Phys.Rev. C21, 1239 (1980) H.J.Gils, E.Friedman, H.Rebel, J.Buschmann, S.Zagromski, H.Klewe-Nebenius, B.Neumann, R.Peel, G.Bechtold Nuclear Sizes of 40,42,44,48Ca from Elastic Scattering of 104 MeV Alpha Particles. I. Experimental Results and Optical Potentials NUCLEAR REACTIONS 40,42,44,48Ca(α, α), E=104 MeV; measured σ(θ); deduced real potential isotopic dependence. Optical model analysis, Fourier-Bessel method.
doi: 10.1103/PhysRevC.21.1239
1980NE05 Z.Phys. A296, 113 (1980) B.Neumann, H.Rebel, J.Buschmann, H.J.Gils, H.Klewe-Nebenius, S.Zagromski Projectile Break-Up in Continuous Particle Spectra from Nuclear Reactions Induced by 156 MeV 6Li NUCLEAR REACTIONS 12C, 60Ni, 90Zr, 120Sn, 208Pb(6Li, p), (6Li, d), (6Li, 3He), (6Li, α), E=156 MeV; measured σ(θ, Ep), σ(θ, Ed), σ(θ, E(3He)), σ(θ, Eα), projectile breakup; deduced reaction mechanism, cluster momentum distribution. Plane wave model.
doi: 10.1007/BF01412652
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