We generalize the simplest kinetically constrained model of a glassforming liquid by softening kinetic constraints, allowing them to be violated with a small rate. We demonstrate that this model supports a first-order dynamical (space-time) phase transition between active (fluid) and inactive (glass) phases. The first-order phase boundary in this softened model ends in a finite-temperature dynamical critical point, which may be present in natural systems. In this case, the glass phase has a very large but finite relaxation time. We discuss links between the dynamical critical point and quantum phase transitions, showing that dynamical phase transitions in d dimensions map to quantum transitions in the same dimension, and hence to classical thermodynamic phase transitions in d þ 1 dimensions.
critical behavior | supercooled liquidsA s a liquid is cooled through its glass transition, it freezes into an amorphous solid state, known as a glass (1, 2). The transition from fluid to solid typically requires only a small change in temperature and is accompanied by characteristic large fluctuations, known as dynamical heterogeneity (3). Based on these observations, several theories invoke analogies between the glass transition and phase transitions that occur in model systems (4-8). Some theories are based on equilibrium phase transitions at finite temperatures (4, 5, 7), although these seem to be unobservable in experiments and computer simulations. An alternative idea (8) is that supercooled liquids and certain model systems both exhibit dynamical phase transitions (9-14), controlled by biasing fields that drive the system away from equilibrium. Here, we demonstrate the existence of a nontrivial critical point associated with such a dynamical transition.The phase transition that we consider occurs in trajectory space. We bias the system toward an "ideal glass" phase by enhancing the probability of trajectories where particle motion is slow. The parameter that controls this bias-the field s-can be varied continuously in computer simulations. For models of glass-forming liquids, the response to this change can be large and discontinuous, corresponding to a first-order phase transition. Such transitions between an active state (analogous to a fluid) and an inactive state (analogous to a glass) were first demonstrated (11) for kinetically constrained lattice models (KCMs) (15). More recently, evidence for such a transition has been found in the molecular dynamics of an atomistic model of a supercooled liquid (13).In KCMs, the transition to the inactive phase takes place when the biasing field s is infinitesimally small, and this result is independent of the temperature. However, very general arguments based on ergodicity breaking, e.g., refs. 14, 16 and 17, indicate that transitions in ergodic molecular fluids should take place at nonzero s. In this context, the essential difference between KCMs and molecular systems is that forces constraining dynamics in the former are infinite (i.e., hard) whereas those in the latter ar...
