Momentum distribution of fragments in heavy-ion reactions: Dependence on the stochastic collision process
- 1 June 1993
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review C
- Vol. 47 (6) , 2652-2660
- https://doi.org/10.1103/physrevc.47.2652
Abstract
Momentum distribution of fragments produced in 12C+12C reaction at 28.7 MeV/nucleon is analyzed with antisymmetrized version of molecular dynamics (AMD). Calculations are made for several cases of stochastic collisions and the projectile fragmentation peak in momentum distribution is reproduced by the incorporation of many-body nature in stochastic collision process. Furthermore the value of the cross section is found to be reflected in the low momentum part of fragments such as alpha particles and 9Be.Keywords
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This publication has 13 references indexed in Scilit:
- Fragment Mass Distribution in Intermediate Energy Heavy-Ion Collisions and the Reaction time ScaleProgress of Theoretical Physics, 1992
- Fragment formation studied with antisymmetrized version of molecular dynamics with two-nucleon collisionsPhysical Review Letters, 1992
- Antisymmetrized Version of Molecular Dynamics with Two-Nucleon Collisions and Its Application to Heavy Ion ReactionsProgress of Theoretical Physics, 1992
- “Quantum” molecular dynamics—a dynamical microscopic n-body approach to investigate fragment formation and the nuclear equation of state in heavy ion collisionsPhysics Reports, 1991
- Fermionic molecular dynamicsNuclear Physics A, 1990
- Quantum molecular dynamics study of fusion and its fade out in theO systemPhysical Review C, 1990
- Quantum molecular dynamics — A novel approach to N-body correlations in heavy ion collisionsPhysics Letters B, 1986
- Cross-section measurements and phase shift analysis of-elastic scattering in the energy range 20-55 MeVPhysical Review C, 1978
- On the interpretation of evaporation residue mass distributions in heavy-ion induced fusion reactionsNuclear Physics A, 1977
- Equilibrium deformation calculations of the ground state energies of 1p shell nucleiNuclear Physics, 1965