Abstract

The triply differential cross sections $\frac{{d}^{3}\ensuremath{\sigma}}{\mathrm{dA}\mathrm{dE}d\ensuremath{\theta}}$ of binary exit channels in the reactions $^{92}\mathrm{Mo}$ + $^{92}\mathrm{Mo}$ and $^{100}\mathrm{Mo}$ + $^{100}\mathrm{Mo}$ have been measured at energies between 12 and 18.8 MeV/u. Complete relaxation is reached at energy losses up to 650 MeV, corresponding to temperatures in the fragments of up to 5 MeV; the primary mass distributions tend to spread over the full range of mass asymmetries, indicating a loss of the initial target and projectile identity and hence the disappearance of an essential feature of the deep-inelastic process.