Trapped-ion experiment reveals multi-Mpemba effect with multiple trajectory crossings, explained by a phase diagram combining SDM overlap and initial relaxation speed from the fastest decay mode.
Experimental observa- tion and application of the genuine quantum mpemba effect
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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.
The quantum Mpemba effect in a three-level system is described using the SEAQT framework with Hilbert space projection and a machine-learning-fitted relaxation parameter.
citing papers explorer
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Observation of quantum multi-Mpemba effect in a trapped-ion system
Trapped-ion experiment reveals multi-Mpemba effect with multiple trajectory crossings, explained by a phase diagram combining SDM overlap and initial relaxation speed from the fastest decay mode.
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Asymmetry dynamics and nonequilibrium symmetry-breaking phase transitions
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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A Description of the Quantum Mpemba Effect using the Steepest-Entropy-Ascent Quantum Thermodynamics Framework
The quantum Mpemba effect in a three-level system is described using the SEAQT framework with Hilbert space projection and a machine-learning-fitted relaxation parameter.