Abstract
Understanding nonequilibrium systems and the consequences of irreversibility for the system’s behavior as compared to the equilibrium case, is a fundamental question in statistical physics. Here, we investigate two types of nonequilibrium phase transitions, a second-order and an infinite-order phase transition, in a prototypical q-state vector Potts model which is driven out of equilibrium by coupling the spins to heat baths at two different temperatures. We discuss the behavior of the quantities that are typically considered in the vicinity of (equilibrium) phase transitions, like the specific heat, and moreover investigate the behavior of the entropy production (EP), which directly quantifies the irreversibility of the process. For the second-order phase transition, we show that the universality class remains the same as in equilibrium. Further, the derivative of the EP rate with respect to the temperature diverges with a power-law at the critical point, but displays a non-universal critical exponent, which depends on the temperature difference, i.e., the strength of the driving. For the infinite-order transition, the derivative of the EP exhibits a maximum in the disordered phase, similar to the specific heat. However, in contrast to the specific heat, whose maximum is independent of the strength of the driving, the maximum of the derivative of the EP grows with increasing temperature difference. We also consider entropy fluctuations and find that their skewness increases with the driving strength, in both cases, in the vicinity of the second-order transition, as well as around the infinite-order transition.
Highlights
Phase transitions are ubiquitous in nature and generally occur in equilibrium as well as nonequilibrium systems
To characterize the critical behavior, we study the specific heat and the entropy production (EP), and we compare the results in the vicinity of the critical point for both kinds of phase transition
Phase transition in the discrete vector Potts model with q = 4 Before we numerically investigate the phase transition of our nonequilibrium model, let us briefly review some important properties of the equilibrium version of the four-state vector Potts model
Summary
Phase transitions are ubiquitous in nature and generally occur in equilibrium as well as nonequilibrium systems. It is well established that continuous (second-order) phase transitions are accompanied by power-law divergences of multiple measurable quantities, such as the magnetic susceptibility or the spin–spin correlation length (for Ising-like models) and there are already numerous examples for nonequilibrium systems that can be characterized in this manner as well [14,15,16,17,18,19,20]. A general theory for nonequilibrium phase transitions is still missing, and it is not per se clear whether the critical exponents of a system stay the same (i.e., the system remains in the same universality class) when driven away from equilibrium
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