Non-commutative Dynamic Approaches to the Kibble-Zurek Scaling Limit with an Initial Gapless Order

Abstract

Nonequilibrium many-body physics is one of the core problems in modern physics, while the dynamical scaling from a gapless phase to the critical point is a most important challenge with very few knowledge so far. In the driven dynamics with a tuning rate R across the quantum critical point (QCP) of a system with size L, the finite-time scaling shows that the square of the order parameter m2 obeys a simple scaling relation m2 R2β/ r in the Kibble-Zurek (KZ) scaling limit with RLr1. Here, by studying the driven critical dynamics from a gapless ordered phase in the bilayer Heisenberg model, we unveil that the approaches to the scaling region dominated by the KZ scaling limit with RLr1 are non-commutative: this scaling region is inaccessible for large R and finite medium L, while merely accessible for large L and moderately finite R. We attribute this to the memory effect induced by the finite-size correction in the gapless ordered phase. This non-commutative property makes m2 still strongly depends on the system size and deviates from m2 R2β/ r even for large R. We further show that a similar correction applies to the imaginary-time relaxation dynamics. Our results establish an essential extension of nonequilibrium scaling theory with a gapless ordered initial state.