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Observation of quantum multi-Mpemba effect in a trapped-ion system

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abstract

The quantum Mpemba effect (ME) in Markovian systems is conventionally explained by a smaller overlap between the initial state and the slowest decay mode (SDM). Such state, initially farther away from equilibrium or steady state, relaxes faster than closer ones, resulting to a crossing of their trajectories. This picture, by neglecting the transient dynamics, holds in the long-time limit. Here we experimentally observe multiple trajectory crossings (multi-ME) in the relaxation dynamics of a trapped ion. Such novel dynamics takes place in a unusual scenario where the initial state instead has a larger overlap with the SDM. We develop a theoretical framework based on relaxation speed to understand the multi-ME. We show that the initial relaxation speed is governed by the fastest decay mode, which together with the SDM overlap gives a phase diagram that reveals both the occurrence and the types of quantum ME observed in our experiment. Our study goes beyond the simple picture based on the long-time limit, tracks continuously the quantum ME dynamics, and establishes a comprehensive framework to describe the transient quantum relaxation.

years

2026 1

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UNVERDICTED 1

representative citing papers

Asymmetry dynamics and nonequilibrium symmetry-breaking phase transitions

cond-mat.stat-mech · 2026-06-05 · unverdicted · novelty 6.0

In open quantum many-body systems with symmetry-breaking transitions, asymmetry dynamics produce a quantum Mpemba effect in the symmetric phase via non-monotonic evolution and an imbalance between increasing and decreasing asymmetry in the broken phase.

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  • Asymmetry dynamics and nonequilibrium symmetry-breaking phase transitions cond-mat.stat-mech · 2026-06-05 · unverdicted · none · ref 22 · internal anchor

    In open quantum many-body systems with symmetry-breaking transitions, asymmetry dynamics produce a quantum Mpemba effect in the symmetric phase via non-monotonic evolution and an imbalance between increasing and decreasing asymmetry in the broken phase.