Mixed-State Measurement-Induced Phase Transitions in Imaginary-Time Dynamics

TL;DR

This paper introduces a new framework called measurement-dressed imaginary-time evolution (MDITE) to study mixed-state quantum phase transitions and decoherence-driven criticality, revealing novel critical behavior in quantum many-body systems.

Contribution

The paper presents MDITE as a novel approach to explore mixed-state phases, differing from monitored unitary circuits, and demonstrates its effectiveness through numerical simulations of key models.

Findings

Existence of mixed-state phase transitions in quantum models.

Transitions show critical behavior outside known universality classes.

Diagrammatic representation enables efficient large-scale studies.

Abstract

Mixed-state phase transitions have recently attracted growing attention as a new frontier in nonequilibrium quantum matter and quantum information. In this work, we introduce the measurement-dressed imaginary-time evolution (MDITE) as a novel framework to explore mixed-state quantum phases and decoherence-driven criticality. In this setup, alternating imaginary-time evolution and projective measurements generate a competition between coherence-restoring dynamics and decoherence-inducing events. While reminiscent of monitored unitary circuits, MDITE fundamentally differs in that the physics is encoded in decoherent mixed states rather than in quantum trajectories. Using numerical simulations of the one-dimensional transverse-field Ising model and the two-dimensional columnar dimerized Heisenberg model, we demonstrate the existence of this kind of mixed-state phase transitions. Notably, these transitions appear to exhibit critical behavior inconsistent with known universality classes. In addition, we provide a diagrammatic representation of the evolving state, which naturally enables efficient studies of MDITE with quantum Monte Carlo and other many-body numerical methods, thereby extending investigations of mixed-state phase transitions to large-scale and higher-dimensional systems. Our results establish MDITE as a versatile platform for investigating mixed-state criticality and uncover new classes of decoherence-driven nonequilibrium phase transitions.