NSR Query Results
Output year order : Descending NSR database version of April 27, 2024. Search: Author = M.Lassaut Found 20 matches. 2020CA05 Rom.J.Phys. 65, 301 (2020) F.Carstoiu, M.Lassaut, L.Trache Rainbow Extinction, Orbiting and Regge Poles NUCLEAR REACTIONS 24Mg(α, α), E=50 MeV; calculated σ, Regge poles, folding form factors.
2016CA36 Rom.J.Phys. 61, 1180 (2016) F.Carstoiu, M.Lassaut, L.Trache, V.Balanica Heavy Ion Orbiting and Regge Poles (III) NUCLEAR REACTIONS 12C(6Li, 6Li), E=30.6 MeV; 13C(6Li, 6Li), E=54 MeV; calculated σ, form factors. Comparison with available data.
2016CA37 Rom.J.Phys. 61, 400 (2016) F.Carstoiu, M.Lassaut, L.Trache, V.Balanica Heavy Ion Orbiting and Regge Poles (I)
2016CA45 Rom.J.Phys. 61, 857 (2016) F.Carstoiu, M.Lassaut, L.Trache, V.Balanica Heavy Ion Orbiting and Regge Poles (ii) NUCLEAR REACTIONS 16O(α, α), E=54.1 MeV;28Si(α, α), E=18.0 MeV; calculated formfactors, σ(θ) using Regge poles, two different WS potentials, one of them allowing for orbiting, and several different interactions. Compared to data.
2013LA28 Rom.J.Phys. 58, 913 (2013) M.Lassaut, F.Carstoiu, V.Balanica Low Energy α-α Semimicroscopic Potentials NUCLEAR REACTIONS 12C(α, α), E=120, 145 MeV; calculated σ. D1 parametrization of the Gogny effective interaction, comparison with available data.
2012DI01 Rom.J.Phys. 57, 159 (2012) A.Diaf, M.Lassaut, R.J.Lombard Approximate Centrifugal Barriers and Critical Angular Momentum
2011CA15 Int.J.Mod.Phys. E20, 885 (2011) F.Carstoiu, S.Misicu, M.Rizea, M.Lassaut Bare α-α potential and implications on α-matter properties
doi: 10.1142/S0218301311018897
1999LA04 Eur.Phys.J. A 4, 111 (1999) Bounds to the Size of Halo Nuclei NUCLEAR STRUCTURE 2H, 11Be, 8,15B, 15,17,19C; calculated halo nuclei radius lower, upper bounds. Dimensional relationship for weakly-bound two-body systems.
doi: 10.1007/s100500050211
1996BR02 Nucl.Phys. A596, 199 (1996) R.Brizzi, M.Fabre de la Ripelle, M.Lassaut Model Calculations of Doubly Closed-Shell Nuclei in the Integro-Differential Equation Approach NUCLEAR STRUCTURE 4He, 12C, 16O, 40Ca; calculated binding energy, radii. Integro-differential equation approach, weight-function approximation.
doi: 10.1016/0375-9474(95)00418-1
1996CA01 Nucl.Phys. A597, 269 (1996) Microscopic Description of Elastic Scattering and Reaction Cross Sections of 6Li and 11Li NUCLEAR REACTIONS 12C(α, α), E=104-172.5 MeV; 28Si(6Li, 6Li), E=75.6-318 MeV; 12C(6Li, 6Li), E=99-318 MeV; 12C(11Li, 11Li), E=637 MeV; 28Si(11Li, 11Li), E=319 MeV; calculated σ(θ); deduced model parameters features. Optical model potentials from double folding with G-matrix.
doi: 10.1016/0375-9474(95)00449-1
1994CA07 Phys.Rev. C49, 2248 (1994) F.Carstoiu, M.Lassaut, R.J.Lombard Checking a Neutron Halo from Elastic Scattering NUCLEAR REACTIONS 12C(11C, 11C), (11Li, 11Li), E=60 MeV/nucleon; calculated σ(θ) difference vs q; deduced suitability for exhibiting matter distribution changes.
doi: 10.1103/PhysRevC.49.2248
1993LA27 J.Phys.(London) G19, 2079 (1993) M.Lassaut, R.J.Lombard, J.Van de Wiele The Global Phase of the Nucleon-Nucleon Amplitudes and Proton-Nucleus Scattering NUCLEAR REACTIONS 12C(polarized p, p), E=0.8 GeV; calculated σ(θ), analyzing power vs momentum transfer. 16O(polarized p, p), E=0.8 GeV; calculated spin rotation parameter vs momentum transfer. Kerman-McManus-Thaler approximation to optical potential.
doi: 10.1088/0954-3899/19/12/013
1992LA13 Z.Phys. A341, 125 (1992) Influence of the Separation Energy on the Radius of Neutron Rich Nuclei NUCLEAR STRUCTURE 4,6,8He, 8,10,11,12,13,14,15B, 6,7,8,9,11Li, 12,13,14,15,16,17,18,19C, 7,9,10,11,12,14Be; calculated matter rms radii; deduced separation energy role. Hefter, de Llano and Mitropolsky model.
doi: 10.1007/BF01298471
1990LA17 Nucl.Phys. A518, 441 (1990) l-Dependent Local Potentials Equivalent to a Non-Local Potential NUCLEAR REACTIONS 4He(n, n), (p, p), E not given; calculated equivalent local potential parameter features. Peierls-Vinh Mau local approximation.
doi: 10.1016/0375-9474(90)90139-D
1985LA18 Nucl.Phys. A442, 1 (1985) Microscopic Optical-Model Analysis of α - 40Ca Elastic Scattering at 104 MeV through the Near/Far Decomposition NUCLEAR REACTIONS 40Ca(α, α), E=104 MeV; 58Ni(α, α), E=140 MeV; calculated σ(θ). Microscopic optical model, near, far component decomposition.
doi: 10.1016/0375-9474(85)90129-0
1982LA17 Nucl.Phys. A386, 29 (1982) Description of α-Elastic Scattering and (3He, α) Reaction at Intermediate Energy with a Microscopic α-Nucleus Potential NUCLEAR REACTIONS 58Ni(α, α), E=104, 140, 166 MeV; 90Zr(α, α), E=166 MeV; 208Pb(α, α), E=140, 166, 218 MeV; 58Ni(3He, α), E=132, 205 MeV; 90Zr(3He, α), E=205 MeV; 208Pb(3He, α), E=205, 283 MeV; analyzed data; deduced potential parameters. 57Ni, 89Zr, 207Pb deduced spectroscopic factors. DWBA, microscopic α-nucleus potential.
doi: 10.1016/0375-9474(82)90399-2
1982LA24 Nucl.Phys. A391, 118 (1982) The Imaginary Part of the Local Potential Equivalent to the Non-Local α-Nucleus Optical Potential NUCLEAR REACTIONS 40Ca(α, α), E=50, 100 MeV; calculated local equivalent potential imaginary part. Feshbach formalism.
doi: 10.1016/0375-9474(82)90222-6
1981DU07 Nucl.Phys. A355, 141 (1981) F.Duggan, M.Lassaut, F.Michel, N.Vinh Mau Antisymmetrization and Density-Dependent Effects within the Folding Model Approach to α-Nucleus Scattering NUCLEAR REACTIONS 40Ca(α, α), E=104 MeV; calculated σ(θ). Folding model, α-nucleus potential from Hartree-Fock approximation, antisymmetrization, density dependent forces.
doi: 10.1016/0375-9474(81)90135-4
1981LA19 Phys.Lett. 105B, 252 (1981) A Microscopic Calculation of Absorption in Low-Energy Alpha - 40Ca Scattering NUCLEAR REACTIONS 40Ca(α, α), E=20-50 MeV; calculated imaginary potential. Microscopic model.
doi: 10.1016/0370-2693(81)90882-0
1980LA20 Nucl.Phys. A349, 372 (1980) Low-Energy Nucleon-Alpha Scattering: Microscopic potentials and phase shifts NUCLEAR REACTIONS 4He(n, n), E<25 MeV; calculated phase shifts. Antisymmetrized folding model, effective interactions, local equivalent potentials.
doi: 10.1016/0375-9474(80)90295-X
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