Parameter Permutation Symmetry in Particle Systems and Random Polymers

Abstract

Many integrable stochastic particle systems in one space dimension (such as TASEP - totally asymmetric simple exclusion process - and its various deformations, with a notable exception of ASEP) remain integrable when we equip each particle xi with its own jump rate parameter i. It is a consequence of integrability that the distribution of each particle xn(t) in a system started from the step initial configuration depends on the parameters j, j n, in a symmetric way. A transposition n n+1 of the parameters thus affects only the distribution of xn(t). For q-Hahn TASEP and its degenerations (q-TASEP and directed beta polymer) we realize the transposition n n+1 as an explicit Markov swap operator acting on the single particle xn(t). For beta polymer, the swap operator can be interpreted as a simple modification of the lattice on which the polymer is considered. Our main tools are Markov duality and contour integral formulas for joint moments. In particular, our constructions lead to a continuous time Markov process Q(t) preserving the time t distribution of the q-TASEP (with step initial configuration, where t∈ R>0 is fixed). The dual system is a certain transient modification of the stochastic q-Boson system. We identify asymptotic survival probabilities of this transient process with q-moments of the q-TASEP, and use this to show the convergence of the process Q(t) with arbitrary initial data to its stationary distribution. Setting q=0, we recover the results about the usual TASEP established recently in [arXiv:1907.09155] by a different approach based on Gibbs ensembles of interlacing particles in two dimensions.