NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = M.Cavinato Found 41 matches. 2004BA23 Braz.J.Phys. 34, 897 (2004) G.Battistoni, M.Cavinato, F.Cerutti, A.Clivio, E.Fabrici, E.Gadioli, E.Gadioli Erba, M.V.Garzelli, A.Mairani, A.Empl, L.S.Pinsky, F.Ballarini, A.Ottolenghi, A.Fasso, A.Ferrari, J.Ranft, P.R.Sala Heavy Ion Interactions from Coulomb Barrier to Few GeV/n: Boltzmann Master Equation Theory and FLUKA Code Performances NUCLEAR REACTIONS 165Ho(20Ne, nX), E=11-30 MeV/nucleon; Al(Fe, nX), E=400 MeV/nucleon; calculated neutron spectra, σ(E, θ). 93Nb(16O, BX), E=400 MeV; calculated boron fragment spectra, σ(E, θ). Boltzmann master equation theory, comparison with data.
doi: 10.1590/s0103-97332004000500051
2004BB23 Braz.J.Phys. 34, 897 (2004) G.Battistoni, M.Cavinato, F.Cerutti, A.Clivio, E.Fabrici, E.Gadioli, E.Gadioli Erba, M.V.Garzelli, A.Mairani, A.Empl, L.S.Pinsky, F.Ballarini, A.Ottolenghi, A.Fasso, A.Ferrari, J.Ranft, P.R.Sala Heavy Ion Interactions from Coulomb Barrier to Few GeV/n: Boltzmann Master Equation Theory and FLUKA Code Performances NUCLEAR REACTIONS 165Ho(20Ne, nX), E=11-30 MeV/nucleon; Al(Fe, nX), E=400 MeV/nucleon; calculated neutron spectra, σ(E, θ). 93Nb(16O, BX), E=400 MeV; calculated boron fragment spectra, σ(E, θ). Boltzmann master equation theory, comparison with data.
doi: 10.1590/S0103-97332004000500051
2004BU09 Nucl.Phys. A734, 553 (2004) E.Z.Buthelezi, E.Gadioli, G.F.Steyn, F.Albertini, C.Birattari, M.Cavinato, F.Cerutti, S.H.Connell, A.A.Cowley, E.Fabrici, E.Gadioli Erba Incomplete fusion of projectile fragments in the interaction of 12C with 103Rh up to 33 MeV per nucleon NUCLEAR REACTIONS 103Rh(12C, X)105Ag/104Ag/101Pd/100Pd/102Rh/99Rh/97Ru/95Ru/95Tc/94Tc/93mMo/90Mo/90Nb/86Zr/87Y, E=70-400 MeV; analyzed excitation functions; deduced reaction mechanism features.
doi: 10.1016/j.nuclphysa.2004.01.103
2003BE62 Eur.Phys.J. A 18, 639 (2003) B.Becker, F.Albertini, E.Gadioli, G.F.Steyn, M.Cavinato, S.H.Connell, A.A.Cowley, E.Fabrici, S.V.Fortsch, E.Gadioli Erba, J.J.Lawrie, E.Sideras-Haddad Emission of Li, 7, 9Be and B fragments in the interaction of 12C with 93Nb between 200 and 400 MeV NUCLEAR REACTIONS 93Nb(12C, X), E=200-400 MeV; measured intermediate mass fragments σ(E, θ); deduced binary fragmentation contribution, other reaction mechanism features.
doi: 10.1140/epja/i2003-10091-5
2003GA15 Eur.Phys.J. A 17, 195 (2003) E.Gadioli, G.F.Steyn, F.Albertini, C.Birattari, M.Cavinato, S.H.Connell, A.A.Cowley, E.Fabrici, S.V.Fortsch, E.Gadioli Erba, J.J.Lawrie, M.Pigni, J.P.F.Sellschop, E.Sideras-Haddad Emission of intermediate-mass fragments in the interaction of 16O with 59Co, 93Nb and 197Au NUCLEAR REACTIONS 59Co, 93Nb, 197Au(16O, X), E=6-25 MeV/nucleon; measured intermediate mass fragment yields, spectra, σ(E, θ); deduced reaction mechanism features.
doi: 10.1140/epja/i2003-10007-5
2002GA32 Nucl.Phys. A708, 391 (2002) E.Gadioli, G.F.Steyn, C.Birattari, C.Catarisano, M.Cavinato, S.H.Connell, A.A.Cowley, E.Fabrici, S.V.Fortsch, E.Gadioli Erba, J.J.Lawrie, J.P.F.Sellschop, E.Sideras-Haddad Interplay of Mean Field and Nucleon-Nucleon Interactions in the Production of Carbon Fragments in 16O Induced Reactions at Incident Energies up to 25 MeV/amu NUCLEAR REACTIONS 59Co, 93Nb(16O, X), E=100, 250, 400 MeV; measured carbon fragments spectra, σ(θ); deduced projectile breakup and nucleon coalescence contributions.
doi: 10.1016/S0375-9474(02)01021-7
2002GA51 Acta Phys.Hung.N.S. 16, 359 (2002) E.Gadioli, G.F.Steyn, C.Birattari, C.Catarisano, M.Cavinato, S.H.Connell, E.Fabrici, S.V.Fortsch, E.Gadioli Erba, J.J.Lawrie, F.M.Nortier, J.P.F.Sellschop, E.Sideras-Haddad Nucleon Coalescence in the Interaction of 16O with 59Co at an Incident Energy of 250 MeV NUCLEAR REACTIONS 59Co(16O, X), E=250 MeV; measured intermediate mass fragment yields, energy and angular distributions; deduced nucleon coalescence, related reaction mechanism features.
doi: 10.1556/APH.16.2002.1-4.38
2001CA02 Nucl.Phys. A679, 753 (2001) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, G.Riva Monte Carlo Calculations of Heavy Ion Cross-Sections Based on the Boltzmann Master Equation Theory NUCLEAR REACTIONS 165Ho(12C, X), E=25 MeV/nucleon; calculated Ep, En, σ(E, θ), fragment charge and mass distributions. 28Si(28Si, X), E=19.7 MeV/nucleon; calculated proton spectra, σ(E, θ). Ni, 92Mo, 122Sn(40Ar, X), E=26 MeV/nucleon; calculated neutron spectra, σ(E, θ). Monte Carlo calculations, coupled Boltzmann master equations. Comparisons with data.
doi: 10.1016/S0375-9474(00)00357-2
2001GA47 Eur.Phys.J. A 11, 161 (2001) E.Gadioli, G.F.Steyn, C.Birattari, M.Cavinato, S.H.Connell, A.A.Cowley, E.Fabrici, S.V.Fortsch, E.Gadioli Erba, J.J.Lawrie, F.M.Nortier, J.P.F.Sellschop, E.Sideras-Haddad Emission of 8Begs in the Interaction of 12C with Nuclei at Incident Energies up to 33 MeV/amu NUCLEAR REACTIONS 59Co, 93Nb, 197Au(12C, X), E=100-400 MeV; measured σ(θ) vs 8Be energy for 8Be emission, break-up and coalescence contributions. Breakup mechanisms discussed.
doi: 10.1007/s100500170082
2000GA39 Eur.Phys.J. A 8, 373 (2000) E.Gadioli, M.Cavinato, E.Fabrici, E.Gadioli Erba, R.Bassini, C.Birattari, S.Crippa, G.F.Steyn, S.V.Fortsch, J.J.Lawrie, F.M.Nortier, S.H.Connell, E.Sideras-Haddad, J.P.F.Sellschop, A.A.Cowley Evidence for a Dissipative Friction Mechanism Based on 8Be Fragments from the Interaction of 12C with 59Co NUCLEAR REACTIONS 59Co(12C, 8Be), E=8.3-33.3 MeV/nucleon; measured σ(θ), αα-coin. Effect of projectile break up discussed. Comparison with model predictions.
doi: 10.1007/s100500070089
1999GA39 Nucl.Phys. A654, 523 (1999) E.Gadioli, M.Cavinato, E.Fabrici, E.Gadioli Erba, C.Birattari, I.Mica, S.Solia, G.F.Steyn, S.V.Fortsch, J.J.Lawrie, F.M.Nortier, T.G.Stevens, S.H.Connell, J.P.F.Sellschop, A.A.Cowley Alpha Particle Emission in the Interaction of 12C with 59Co and 93Nb at Incident Energies of 300 and 400 MeV NUCLEAR REACTIONS 59Co, 93Nb(12C, αX), E=300, 400 MeV; measured α spectra, σ(Eα, θ); deduced reaction mechanism features.
doi: 10.1016/S0375-9474(00)88492-4
1998CA44 Nucl.Phys. A643, 15 (1998) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, E.Risi Boltzmann Master Equation Theory of Angular Distributions in Heavy-Ion Reactions NUCLEAR REACTIONS 165Ho(20Ne, X), E=600 MeV; calculated neutron, alpha angular distributions. Ag(36S, X), (16O, X), E=30 MeV/nucleon; calculated light charged particles σ(E, θ). Ni, 92Mo, 122Sn(40Ar, X), E=26 MeV/nucleon; 165Ho(12C, X), E=25 MeV/nucleon; calculated σ(En, θ). Boltzmann master equation theory. Comparison with data.
doi: 10.1016/S0375-9474(98)00545-4
1998GA32 Acta Phys.Hung.N.S. 7, 275 (1998) E.Gadioli, C.Birattari, M.Cavinato, E.Fabrici, E.Gadioli Erba, V.Allori, G.Bello, F.Cerutti, A.Di Filippo, T.G.Stevens, S.H.Connell, J.P.F.Sellschop, F.M.Nortier, G.F.Steyn, C.Marchetta The Interaction of 12C and 16O with 103Rh NUCLEAR REACTIONS 103Rh(12C, X)113Sn/111In/110Sn/108In/105Ag/102Rh, E=50-400 MeV; 103Rh(16O, X)115Sb/113Sn/110Sn/111In/108In/105Ag/103Ag/101Pd/101Rh/100Rh/95Ru/94Tc, E=50-400 MeV; calculated excitation functions; deduced pre-equilibrium emission, other reaction mechanism features. Comparison with data.
1998GA36 Nucl.Phys. A641, 271 (1998) E.Gadioli, C.Birattari, M.Cavinato, E.Fabrici, E.Gadioli Erba, V.Allori, F.Cerutti, A.Di Filippo, S.Vailati, T.G.Stevens, S.H.Connell, J.P.F.Sellschop, F.M.Nortier, G.F.Steyn, C.Marchetta Angular Distributions and Forward Recoil Range Distributions of Residues Created in the Interaction of 12C and 16O Ions with 103Rh NUCLEAR REACTIONS 103Rh(12C, X), E=151, 228 MeV; measured residual nuclei angular distributions, yields; 103Rh(12C, X), E=402 MeV; 103Rh(16O, X), E=303 MeV; measured residual nudlei yields, recoil range distributions; deduced reaction mechanism features, incomplete fusion. Activation technique.
doi: 10.1016/S0375-9474(98)00472-2
1997CA34 Phys.Lett. 405B, 219 (1997) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, E.Risi Ejectile Angular Distributions in Boltzmann Master Equation Theory of Nuclear Reactions NUCLEAR REACTIONS 165Ho(20Ne, X), E=220, 292, 402, 600 MeV; 197Au(36Ar, X), E=35 MeV/nucleon; analyzed α-, n-ejectile σ(θ, E). Boltzmann master equation theory.
doi: 10.1016/S0370-2693(97)00644-8
1997GA09 Phys.Lett. 394B, 29 (1997) E.Gadioli, C.Birattari, M.Cavinato, E.Fabrici, E.Gadioli Erba, V.Allori, C.Bovati, F.Cerutti, A.Di Filippo, E.Galbiati, T.G.Stevens, S.H.Connell, J.P.F.Sellschop, S.J.Mills, F.M.Nortier, G.F.Steyn, C.Marchetta Comprehensive Study of the Reactions Induced by 12C on 103Rh up to 33 MeV/nucleon NUCLEAR REACTIONS 103Rh(12C, X)113Sb/110In/108In/107In/111In/105Ag/104Ag/103Ag/102Ag/101Pd/100Pd/99Rh/98Rh/97Ru/96Tc/95Ru/94Tc/93Mo/93mMo/90Nb, E=45-400 MeV; measured residuals production σ(E). Activation technique.
doi: 10.1016/S0370-2693(97)00003-8
1996BI19 Phys.Rev. C54, 3051 (1996) C.Birattari, M.Bonardi, M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, F.Groppi, M.Bello, C.Bovati, A.Di Filippo, T.G.Stevens, S.H.Connell, J.P.F.Sellschop, S.J.Mills, F.M.Nortier, G.F.Steyn, C.Marchetta Preequilibrium Processes in the Fusion of 12C with 103Rh up to 20 MeV/nucleon NUCLEAR REACTIONS, ICPND 103Rh(12C, xnyp)113Sb/111Sn/110Sn/109Sn/108Sn/113Sn/111In/110In/110mIn, E=40-210 MeV; measured residuals production σ(E); deduced fusion σ, multiplicity of pre-equilibrium particles, mean-field interaction. Boltzmann master equation calculation.
doi: 10.1103/PhysRevC.54.3051
1996CA15 Phys.Lett. 382B, 1 (1996) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, E.Galbiati Monte Carlo Calculations using the Boltzmann Master Equation Theory of Nuclear Reactions NUCLEAR REACTIONS 107Ag(16O, X), E=480 MeV; calculated mass, charge, excitation energy distributions after thermalization in fusion, angle integrated particle spectra. 165Ho(20Ne, X), E=220-600 MeV; calculated angle integrated neutron spectra. Boltzmann master equation, Monte Carlo calculations.
doi: 10.1016/0370-2693(96)00652-1
1995BO07 Nucl.Phys. A583, 101c (1995) P.F.Bortignon, M.Braguti, D.M.Brink, R.A.Broglia, C.Brusati, F.Camera, W.Cassing, M.Cavinato, N.Giovanardi, F.Gulminelli On the Giant Dipole Resonance Excitation in Very Hot Nuclei NUCLEAR REACTIONS 90Zr(36Ar, X), E at 27 MeV/nucleon; calculated dipole strength function; deduced model impact parameter choice critical role in GDR excitation. BNV model.
doi: 10.1016/0375-9474(94)00639-5
1995BR33 Z.Phys. A353, 57 (1995) C.Brusati, M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba Nuclear Surface, Mean Field and Isospin Effects in Boltzmann Master Equation Theory of Pre-Equilibrium Reactions NUCLEAR STRUCTURE 16O, 40Ca; calculated neutron momentum distribution. Shell, Saxon-Woods wave functions. NUCLEAR REACTIONS 165Ho(20Ne, X), E=292-600 MeV; 165Ho(12C, X), E=300, 379.2 MeV; Ag(16O, X), E=480 MeV; Ag(32S, X), E=960 MeV; 40Ca(40Ar, X), E=800 MeV; calculated average primary collision time, projectile translational momentum, total kinetic energy gain. Boltzmann master equation, nuclear surface, mean field, isospin effects, preequilibrium reactions.
doi: 10.1007/BF01297728
1995CA32 Phys.Rev. C52, 2577 (1995) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, P.Vergani, M.Crippa, G.Colombo, I.Redaelli, M.Ripamonti Study of the Reactions Occurring in the Fusion of 12C and 16O with Heavy Nuclei at Incident Energies Below 10 MeV/Nucleon NUCLEAR REACTIONS, ICPND 181Ta, 197Au(12C, X), E=54-98 MeV; 165Ho, 181Ta(16O, X), E=75-125 MeV; measured evaporation residues production σ(E); deduced fusion (without fission) σ.
doi: 10.1103/PhysRevC.52.2577
1994CA29 Acta Phys.Pol. B25, 475 (1994) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, M.Galmarini, P.Vergani Non Equilibrium Particle Emission in Nuclear Reactions NUCLEAR REACTIONS 165Ho(12C, X), E=25 MeV/nucleon; 40Ca(40Ar, X), E=20 MeV/nucleon; 107Ag(16O, X), E=30 MeV/nucleon; 197Au(36Ar, X), E=35 MeV/nucleon; compiled, reviewed data, analyses; deduced new mechanism evidence. Boltzmann master equation approach.
1994CA49 Z.Phys. A347, 237 (1994) M.Cavinato, E.Fabrici, E.Gadioli, E.Gadioli Erba, M.Galmarini, A.Gritti Intermediate Mass Fragment Emission in Boltzmann Master Equation Theory of Pre-Equilibrium Reactions NUCLEAR REACTIONS 197Au(36Ar, X), E=35 MeV/nucleon; calculated intermediate mass fragments angle integrated multiplicity spectra. 54Fe(p, X), E=62 MeV; calculated light charged particle spectra. Ag(32S, X), E=30 MeV/nucleon; calculated light particles multiplicity spectra. Coalescence model.
doi: 10.1007/BF01289790
1991AD02 Nucl.Phys. A529, 565 (1991) A.Adorno, A.Bonasera, M.Cavinato, M.Colonna, A.Cunsolo, G.C.Di Leo, M.Di Toro, F.Gulminelli Complex Fragment Production in Kr-Induced Reactions at Intermediate Energies NUCLEAR REACTIONS 197Au(84Kr, X), E=20-43 MeV/nucleon; 12C, Ti, 27Al(84Kr, X), E=34.4 MeV/nucleon; calculated fragment absolute yields, velocity spectra; deduced complex fragment production features. Statistical decay, entrance channel effects.
doi: 10.1016/0375-9474(91)90585-T
1990BO42 Nucl.Phys. A519, 211c (1990) A.Bonasera, M.Cavinato, M.Colonna, M.Di Toro, F.Gulminelli, G.Russo, H.H.Wolter Microscopic Description of Heavy Ion Collisions NUCLEAR REACTIONS 27Al(16O, pX), E=94 MeV/nucleon; calculated σ(θp, Ep). La(La, X), E=246 MeV/nucleon; calculated inclusive pion spectra. 27Al(40Ar, X), E=44 MeV/nucleon; calculated fragment production σ vs mass. Boltzmann-Nordheim-Vlasov equation.
doi: 10.1016/0375-9474(90)90628-Y
1990CA05 Phys.Lett. 235B, 15 (1990) M.Cavinato, M.Marangoni, A.M.Saruis The One-Nucleon Energy Continuum in RPA-SK3 40Ca(e, e') Nuclear Responses at q ≤ 550 MeV/c NUCLEAR REACTIONS 40Ca(e, e'), E not given; calculated longitudinal, transverse response functions. RPA, continuum, Skyrme interactions.
doi: 10.1016/0370-2693(90)90088-N
1990CA14 Z.Phys. A335, 401 (1990) M.Cavinato, M.Marangoni, A.M.Saruis 12C(e, e'p) Missing Momentum Distributions in HF-Sk3 and RPA-Sk3 Continuum Theories NUCLEAR REACTIONS 12C(e, e'p), E not given; calculated momentum distribution. 12C(e, e'), E not given; calculated response functions. Hartree-Fock, RPA, Skyrme forces.
1989CA13 Nucl.Phys. A496, 108 (1989) M.Cavinato, M.Marangoni, A.M.Saruis Response Functions and Charge Transition Densities for Monopole Excitations in (e, e') and (e, e'X) Reactions of 16O and 40Ca NUCLEAR REACTIONS 16O, 40Ca(e, e'), (e, e'X), E not given; calculated response functions, charge transition densities. Self-consistent RPA.
doi: 10.1016/0375-9474(89)90218-2
1988CA07 Z.Phys. A329, 463 (1988) M.Cavinato, M.Marangoni, A.M.Saruis Charge Transition Densities for the Excitation and Nucleon Decay of the Giant Dipole Resonance in 16O NUCLEAR STRUCTURE 16O; calculated GDR excitation charge densities. Skyrme interaction, RPA.
1988CA10 Phys.Rev. C37, 1823 (1988) M.Cavinato, M.Marangoni, A.M.Saruis Coincidence 16O(e(pol), e'x) Reactions with Polarized Electrons at Low Momentum Transfer in Self-Consistent Random-Phase Approximation Theory NUCLEAR REACTIONS 16O(polarized e, e'p), (polarized e, e'n), E=130 MeV; calculated σ(θ(e')), (E(e'), θ(N)), asymmetry. Self-consistent RPA, Hartree-Fock theories.
doi: 10.1103/PhysRevC.37.1823
1988CA20 Phys.Lett. 213B, 111 (1988) M.Cavinato, M.Marangoni, A.M.Saruis Momentum and Density Dependence of the ph Interaction in Continuum RPA Calculations with Skyrme Forces NUCLEAR REACTIONS 12C(e, e'), E not given; calculated longitudinal response function. Self-consistent RPA.
doi: 10.1016/0370-2693(88)91008-8
1987CA16 Z.Phys. A327, 193 (1987) M.Cavinato, M.Marangoni, A.M.Saruis The RPA Nuclear Continuum in 16O(e, e') Reactions at Low Momentum Transfer Decay on (e, e'p) and (e, e'n) Reaction Channels NUCLEAR REACTIONS 16O(e, e'), (e, e'p), (e, e'n), E=67, 130 MeV; calculated response functions, σ(E(e'), θ(e')), multipole components, resonating state microscopic structure. Hartree-Fock, RPA theory, SK3 interaction.
1987FE05 Nucl.Phys. A468, 301 (1987) E.Fein, D.Drechsel, M.Cavinato, M.Marangoni, A.M.Saruis Giant Resonance Studies using the Reaction (e, e'γ) NUCLEAR REACTIONS 12C(γ, γ), E at 60 MeV/c; calculated scalar polarizability. 12C(γ, X), E=15-60 MeV; calculated photoabsorption σ(E). 12C(γ, γ), E=12-35 MeV; calculated σ(θ), σ(E, θ). 12C(e, e'γ), E=300, 400, 800 MeV; calculated σ(E(e'), θ(e')), partial σ(θ(e')). RPA wave functions, Skyrme forces.
doi: 10.1016/0375-9474(87)90519-7
1985CA32 Nucl.Phys. A444, 13 (1985) M.Cavinato, D.Drechsel, E.Fein, M.Marangoni, A.M.Saruis Collective Excitations in 12C(e, e'p0) and 12C(e, e'n0) Reactions at Low Momentum Transfer NUCLEAR REACTIONS 12C(e, e'p), (e, e'n), E=126 MeV; calculated σ(E(e'), θ(e'), θp), σ(E(e'), θ(e'), θn). Self-consisent RPA, Skyrme forces, continuum model.
doi: 10.1016/0375-9474(85)90289-1
1985CA37 Phys.Lett. 163B, 49 (1985) M.Cavinato, M.Marangoni, A.M.Saruis Coincidence 16O(e, e'x) Cross Sections and 16O(e(pol), e'x) Asymmetries in the Random Phase Approximation NUCLEAR REACTIONS 16O(e, e'X), (polarized e, e'X), E=100 MeV; calculated σ(θ, E(e'), fragment θ). 16O(e, e'p), E=130 MeV; calculated σ(E(e'), θ), σ(E(e'), θ, θp). Self-consistent RPA theory, SK3 interaction.
doi: 10.1016/0370-2693(85)90190-X
1984CA18 Nucl.Phys. A422, 237 (1984) M.Cavinato, M.Marangoni, A.M.Saruis Photoreactions of 12C, 16O and 40Ca in Self-Consistent RPA Theory (II). Unpolarized (γ, p) and (γ, n) Angular Distributions below Pion Threshold NUCLEAR REACTIONS 11B(p, γ), E=30-80 MeV; 40Ca(γ, p), (γ, n), E=18-30 MeV; calculated σ(θ) vs E. 16O(γ, n), E=40, 48.4, 60 MeV; 12C, 16O(γ, p), 12C(γ, n), E=60 MeV; calculated σ(θ). Self-consistent RPA.
doi: 10.1016/0375-9474(84)90516-5
1984CA19 Nucl.Phys. A422, 273 (1984) M.Cavinato, M.Marangoni, A.M.Saruis Photoreactions of 16O in Self-Consistent RPA Theory (III). Polarized (γ, p) and (γ, n) Angular Distributions and Inverse Capture Reactions below 60 MeV NUCLEAR REACTIONS 16O(polarized γ, p), (polarized γ, n), E=17.75-45 MeV; calculated σ, amplitude, asymmetry vs E. Self-consistent RPA.
doi: 10.1016/0375-9474(84)90517-7
1984CA22 Nucl.Phys. A423, 376 (1984) M.Cavinato, D.Drechsel, E.Fein, M.Marangoni, A.M.Saruis Continuum RPA Correlations in Quasielastic Electron Scattering from 12C Decay on (e, e'p) and (e, e'n) Reaction Channels NUCLEAR REACTIONS 12C(e, e'), (e, e'p), (e, e'n), E not given; calculated longitudinal, transverse response functions, form factors. Self-consistent continuum RPA theory.
doi: 10.1016/0375-9474(84)90030-7
1983CA17 Phys.Lett. 127B, 295 (1983) M.Cavinato, D.Drechsel, E.Fein, M.Marangoni, A.M.Saruis Resonance and Quasi-Free Electron Scattering on 12C in Self-Consistent RPA Theory NUCLEAR REACTIONS 12C(e, e'), E=148.5 MeV; calculated σ(E(e'), θ(e')). Self-consistent RPA, Skyrme forces, giant resonance, quasifree scattering effects.
doi: 10.1016/0370-2693(83)91003-1
1983CA22 Nuovo Cim. 76A, 197 (1983) M.Cavinato, M.Marangoni, A.M.Saruis Many-Body Effects in Photoreactions of Light Nuclei below Pion Threshold NUCLEAR REACTIONS 16O(γ, p), (γ, n), E=40-100 MeV; 12C(γ, p), E ≈ 30-180 MeV; 12C(γ, n), E=71, 79 MeV; analyzed σ(θ), photonuclear reactions; deduced exchange current, nuclear correlations contributions to reaction mechanism. Self-consistent RPA, Skyrme force.
doi: 10.1007/BF02833719
1982CA01 Nucl.Phys. A373, 445 (1982) M.Cavinato, M.Marangoni, P.L.Ottaviani, A.M.Saruis Photoreactions of 12C, 16O and 40Ca in Self-Consistent RPA Theory (I). The E1 and E2 Giant Resonances, Decay on (γ, p) and (γ, n) Channels NUCLEAR REACTIONS 12C, 16O, 40Ca(γ, X), (γ, p), (γ, n), E=threshold-80 MeV; calculated σ(E). Self-consistent RPA, Skyrme interactions.
doi: 10.1016/0375-9474(82)90544-9
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