Does the Sastry transition control cavitation in simple liquids?

We examine the Sastry (athermal cavitation) transitions for model monatomic liquids interacting via Lennard-Jones as well as shorter- and longer-ranged pair potentials. Low-temperature thermodynamically stable liquids have \(\rho < \rho_S\) except when the attractive forces are long-ranged. For moderate- and short-ranged attractions, stable liquids with \(\rho > \rho_S\) exist at higher temperatures; the pressures in these liquids are high, but the Sastry transition may strongly influence their cavitation under dynamic hydrostatic expansion. The temperature \(T^*\) at which stable \(\rho > \rho_S\) liquids emerge is \(\sim 0.84\epsilon/k_B\) for Lennard-Jones liquids; \(T^*\) decreases (increases) rapidly with increasing (decreasing) pair-interaction range. In particular, for short-ranged potentials, \(T^*\) is above the critical temperature. All liquids' inherent structures are isostructural (isomorphic) for densities below (above) the Sastry density \(\rho_S\). Overall, our results suggest that the barriers to cavitation in most simple liquids under ambient conditions where significant cavitation is likely to occur are primarily vibrational-energetic and entropic rather than configurational-energetic. The most likely exceptions to this rule are liquids with long-ranged pair interactions, such as alkali metals. The most likely exceptions to this rule are liquids with long-ranged pair interactions, such as alkali metals.