About cookies on this site Our websites require some cookies to function properly (required). In addition, other cookies may be used with your consent to analyze site usage, improve the user experience and for advertising. For more information, please review your options. By visiting our website, you agree to our processing of information as described in IBM’sprivacy statement. To provide a smooth navigation, your cookie preferences will be shared across the IBM web domains listed here.
Publication
Physical Review A
Paper
Generic nonergodic behavior in locally interacting continuous systems
Abstract
Certain probabilistic cellular automata (PCA) have been shown to exhibit nonergodic behavior (i.e., possess two or more distinct stable states) over finite regions of their parameter spaces, i.e., generically. To demonstrate that this behavior is a consequence of irreversible (or nonequilibrium) dynamics and not special to the discrete space, time, and variables of PCA, we define and study a class of noisy partial differential equations (Langevin models), which are constructed to have spatially anisotropic domain-wall kinetics. The models are simple nonequilibrium generalizations of ordinary equilibrium time-dependent Ginzburg-Landau theories. We present analytic and numerical arguments to show that these models exhibit the same generic nonergodic behavior as do their discrete PCA counterparts. © 1990 The American Physical Society.