Absorbing state transitions with discrete symmetries (2502.08702v1)

Abstract: Recent progress in interactive quantum dynamics has inspired the study of fundamentally out-of-equilibrium dynamical phase transitions of quantum and classical many-body systems. Motivated by these developments, we study nonequilibrium phase transitions to absorbing states in one-dimensional systems that can model certain quantum circuits. Specifically, we consider dynamics for which the absorbing states are not unique due to a discrete symmetry: Z2 for two-state models and S3 or Z3 for three-state models. Under time evolution, domain walls in these models perform random walks and coarsen under local feedback, which, if perfect, reduces their number over time, driving the system to an absorbing state in polynomial time. Imperfect feedback, however, introduces domain wall multiplication (branching), potentially leading to an active phase. For Z2-symmetric two-state models, starting from a single domain wall, we find distinct absorbing and active phases as in previous studies. Extending this analysis to local three-state models shows that any nonzero branching rate drives the system into the active phase. However, we demonstrate that incorporating nonlocal classical information into the feedback can stabilize the absorbing phase against branching. By tuning the level of nonlocality, we observe a transition from the active to the absorbing phase, which belongs to a new universality class.