Fisher information approach to non-equilibrium phase transitions in quantum XXZ spin chain with boundary noise

TL;DR

This paper uses Fisher information to identify non-equilibrium quantum phase transitions in a boundary-driven XXZ spin chain, revealing critical behavior and non-local order parameters, with implications for quantum sensing.

Contribution

It introduces a Fisher information-based method to detect non-equilibrium quantum phase transitions and characterizes their non-local nature in the XXZ spin chain with boundary noise.

Findings

Superextensive Fisher information at |elta|\u2264, irrational rccoselta/

Evidence of a non-equilibrium quantum phase transition without local order parameters

Enhanced parameter estimation sensitivity near critical points

Abstract

We investigated quantum critical behaviours in the non-equilibrium steady state of a $XXZ$ spin chain with boundary Markovian noise using the Fisher information. The latter represents the distance between two infinitesimally close states, and its superextensive size scaling witnesses a critical behaviour due to a phase transition, since all the interaction terms are extensive. Perturbatively in the noise strength, we found superextensive Fisher information at anisotropy $|\Delta|\leqslant1$ and irrational $\frac{\arccos\Delta}{\pi}$ irrespective of the order of two non-commuting limits, i.e. the thermodynamic limit and the limit of sending $\frac{\arccos\Delta}{\pi}$ to an irrational number via a sequence of rational approximants. From this result we argue the existence of a non-equilibrium quantum phase transition with a critical phase $|\Delta|\leqslant1$. From the non-superextensivity of the Fisher information of reduced states, we infer that this non-equilibrium quantum phase transition does not have local order parameters but has non-local ones, at least at $|\Delta|=1$. In the non-perturbative regime for the noise strength, we numerically computed the reduced Fisher information which lower bounds the full state Fisher information, and is superextensive only at $|\Delta|=1$. Form the latter result, we derived local order parameters at $|\Delta|=1$ in the non-perturbative case. The existence of critical behaviour witnessed by the Fisher information in the phase $|\Delta|<1$ is still an open problem. The Fisher information also represents the best sensitivity for any estimation of the control parameter, in our case the anisotropy $\Delta$, and its superextensivity implies enhanced estimation precision which is also highly robust in the presence of a critical phase.