Langevin dynamics with generalized time-reversal symmetry (2504.05980v1)

Abstract: When analyzing the equilibrium properties of a stochastic process, identifying the parity of the variables under time-reversal is imperative. This initial step is required to assess the presence of detailed balance, and to compute the entropy production rate, which is, otherwise, ambiguously defined. In this work we deal with stochastic processes whose underlying time-reversal symmetry cannot be reduced to the usual parity rules (namely, flip of the momentum sign). We provide a systematic method to build equilibrium Langevin dynamics starting from their reversible deterministic counterparts: this strategy can be applied, in particular, to all stable one-dimensional Hamiltonian dynamics, exploiting the time-reversal symmetry unveiled in the action-angle framework. The case of the Lotka-Volterra model is discussed as an example. We also show that other stochastic versions of this system violate time-reversal symmetry and are, therefore, intrinsically out of equilibrium.