Convergence in Energy-Lowering (Disordered) Stochastic Spin Systems
Abstract
We consider stochastic processes, St (Sxt : x ∈ Zd), with each Sxt taking values in some fixed finite set, in which spin flips (i.e., changes of Sxt) do not raise the energy. We extend earlier results of Nanda-Newman-Stein that each site x has almost surely only finitely many flips that strictly lower the energy and thus that in models without zero-energy flips there is convergence to an absorbing state. In particular, the assumption of finite mean energy density can be eliminated by constructing a percolation-theoretic Lyapunov function density as a substitute for the mean energy density. Our results apply to random energy functions with a translation-invariant distribution and to quite general (not necessarily Markovian) dynamics.
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