Universal scaling in one-dimensional non-reciprocal matter (2503.14384v1)

Abstract: Unveiling universal non-equilibrium scaling laws has been a central theme in modern statistical physics, with recent attention increasingly directed toward nonequilibrium phases that exhibit rich dynamical phenomena. A striking example arises in nonreciprocal systems, where asymmetric interactions between components lead to inherently dynamic phases and unconventional criticality near a critical exceptional point (CEP), where the criticality arises from the coalescence of collective modes to the Nambu-Goldstone mode. However, the universal scaling behavior that should emerge in this system with full consideration of many-body effects and stochastic noise remains largely elusive. Here, we establish a dynamical scaling law in a generic one-dimensional stochastic nonreciprocal $O(2)$-symmetric system. Through large-scale simulations, we uncover a new nonequilibrium scaling in the vicinity of transition, distinct from any previously known equilibrium or nonequilibrium universality classes. In regimes where the system breaks into domains with opposite chirality, we demonstrate that fluctuations are strongly suppressed, leading to a logarithmic scaling as a function of system size $L$, in contrast to the conventional power-law scaling expected from dynamical scaling theory. This work elucidates the beyond-mean-field dynamics of non-reciprocal matter, thereby sheding light on the exploration of criticality in nonreciprocal phase transition across diverse physical contexts, from active matter and driven quantum systems to biological pattern formation and non-Hermitian physics.