The Evolution of Nuclear Multifragmentation in the Temperature-Density Plane

P. Warren,S. Albergo,J. Alexander,F. Bieser,F.P. Brady,Z. Caccia,D. Cebra,A. D. Chacon,J. L. Chance,Y. Choi,Salvatore Costa,J. B. Elliott,M. L. Gilkes,J. A. Hauger,A. Hirsch,E. Hjort,A. Insolia,M. Justice,D. Keane,J. C. Kitner,Roy A. Lacey,J. Lauret,V. Lindenstruth,M. A. Lisa,H. S. Matis,R. McGrath,M. A. McMahan,C. McParlan,W.F.J. Mueller,D. Olson,M. D. Partlan,N. Porile,R. Potenza,G. Rai,J. O. Rasmussen,H. G. Ritter,J. Romanski,J. L. Romero,G. V. Russo,H. Sann,R. P. Scharenberg,A. Scott,Y. Shao,B. Srivastava,T. J. M. Symons,M. Tincknell,C. Tuvè,S. Wang,H. Wieman,T. Wienold,K. Wolf

The Evolution of Nuclear Multifragmentation in the Temperature-Density Plane

1996

The mean transverse kinetic energies of the fragments formed in the interaction of 1 A GeV Au+C have been determined. An energy balance argument indicates the presence of a collective energy which increases in magnitude with increasing multiplicity and accounts for nearly half of the measured mean transverse kinetic energy. The radial flow velocity associated with the collective energy yields estimates for the time required to expand to the freeze-out volume. Isentropic trajectories in the temperature-density plane are shown for the expansion and indicate that the system goes through the critical region at the same multiplicities as deduced from a statistical analysis. Here, the expansion time is approximately 70 fm/c.

Keywords:

Particle physics
Physics
Energy balance
Flow velocity
Kinetic energy
Classical mechanics
Transverse plane
Magnitude (mathematics)
Isentropic process
Multiplicity (mathematics)
radial flow
statistical analysis
Nuclear physics

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