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Symmetry Breaking Dynamics in Quantum Many-Body Systems

Huijun Yu, Zixiang Li, Shi‐Xin Zhang

2025Chinese Physics Letters13 citationsDOIOpen Access PDF

Abstract

Abstract Entanglement asymmetry (EA) has emerged as a powerful tool for characterizing symmetry breaking in quantum many-body systems. In this Letter, we explore how symmetry is dynamically broken through the lens of EA in two distinct scenarios: a non-symmetric Hamiltonian quench and a non-symmetric random quantum circuit, with a particular focus on U(1) symmetry. In the former case, symmetry remains broken in the subsystem at late times, whereas in the latter case, the symmetry is initially broken and subsequently restored, consistent with the principles of quantum thermalization. Notably, the growth of EA exhibits unexpected overshooting behavior at early times in both contexts, contrasting with the behavior of charge variance. We also consider dynamics of non-symmetric initial states under the symmetry-breaking evolution. Due to the competition of symmetry-breaking in both the initial state and Hamiltonian, the early-time EA can increase and decrease, while quantum Mpemba effects remain evident despite the weak symmetry-breaking in both settings.

Topics & Concepts

PhysicsAsymmetrySymmetry breakingQuantumHamiltonian (control theory)Spontaneous symmetry breakingSymmetry (geometry)Quantum mechanicsQuantum dynamicsExplicit symmetry breakingCharge (physics)Quantum fluctuationQuantum stateChiral symmetry breakingQuantum processContinuous symmetryDynamics (music)Quantum phasesRotational symmetryQuantum dissipationQuantum systemTheoretical physicsGlobal symmetryT-symmetryQuantum many-body systemsAdvanced Thermodynamics and Statistical MechanicsNeural Networks and Reservoir Computing