Mass dependence of the disappearance of flow in nuclear collisions

G. D. Westfall; W. Bauer; D. Craig; M. Cronqvist; E. Gaultieri; S. Hannuschke; D. Klakow; T. Li; T. Reposeur; A. M. Vander Molen; W. K. Wilson; J. S. Winfield; J. Yee; S. J. Yennello; R. Lacey; A. Elmaani; J. Lauret; A. Nadasen; E. Norbeck

doi:10.1103/PhysRevLett.71.1986

Mass dependence of the disappearance of flow in nuclear collisions

G. D. Westfall, W. Bauer, D. Craig, M. Cronqvist, E. Gaultieri, S. Hannuschke, D. Klakow, T. Li, T. Reposeur, A. M. Vander Molen, W. K. Wilson, J. S. Winfield, J. Yee, S. J. Yennello, R. Lacey, A. Elmaani, J. Lauret, A. Nadasen, and E. Norbeck

Phys. Rev. Lett. 71, 1986 – Published 27 September 1993

Abstract

The disappearance of collective flow in nucleus-nucleus collisions occurs at an incident energy ( $E_{bal}$ ) where the attractive scattering dominant at low energies balances the repulsive scattering dominant at high energies. We have performed the first systematic study of the entrance-channel mass dependence of the disappearance of flow and hence $E_{bal}$ . The new data presented for the C+C, Ne+Al, Ar+Sc, and Kr+Nb systems show that $E_{bal}$ scales as $A^{- 1 / 3}$ where A is the mass of the combined system. Boltzmann-Uehling-Uehlenbeck model calculations show trends which are in qualitative agreement with these new results.