Study of nuclear stopping in central collisions at intermediate energies

Nuclear stopping has been investigated in central nuclear collisions at intermediate energies by analyzing kinematically complete events recorded with the help of the 4π multidetector INDRA for a large variety of symmetric systems. It is found that the mean isotropy ratio defined as the ratio of tra...

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Bibliographic Details
Published in:Physical review letters 2010-06, Vol.104 (23), p.232701-232701, Article 232701
Main Authors: Lehaut, G, Durand, D, Lopez, O, Vient, E, Chbihi, A, Frankland, J D, Bonnet, E, Borderie, B, Bougault, R, Galichet, E, Guinet, D, Lautesse, Ph, Le Neindre, N, Napolitani, P, Parlog, M, Rivet, M F, Rosato, E
Format: Article
Language:English
Subjects:
BEAMS
COLLISIONS
COMPARATIVE EVALUATIONS
DATA
EVALUATION
EXPERIMENTAL DATA
INFORMATION
ISOSPIN
ISOTROPY
Nuclear Experiment
NUCLEAR PHYSICS AND RADIATION PHYSICS
NUMERICAL DATA
PARTICLE PROPERTIES
Physics
STOPPING POWER
SYMMETRY
TRANSPORT THEORY
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Summary:Nuclear stopping has been investigated in central nuclear collisions at intermediate energies by analyzing kinematically complete events recorded with the help of the 4π multidetector INDRA for a large variety of symmetric systems. It is found that the mean isotropy ratio defined as the ratio of transverse to parallel momenta (energies) reaches a minimum near the Fermi energy, saturates or slowly increases depending on the mass of the system as the beam energy increases, and then stays lower than unity, showing that significant stopping is not achieved even for the heavier systems. Close to and above the Fermi energy, experimental data show no effect of the isospin content of the interacting system. A comparison with transport model calculations reveals that the latter overestimates the stopping power at low energies.
ISSN:0031-9007
1079-7114
DOI:10.1103/physrevlett.104.232701