Geometric heterogeneity in small disordered spin networks with dipolar couplings and dephasing produces separated dynamical timescales, with a parametrically long relaxation time arising from effective detuning in strongly hybridized clusters.
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Nonreciprocity combined with open boundaries and symmetry defects produces a domain-wall traveling-wave phase and anomalous chiral relaxation in open quantum systems.
For n-component conserved fields with nonlinear non-reciprocal coupling, one-loop RG shows that n ≥ 4 yields a fixed point with emergent detailed balance and fewer independent exponents due to conservation.
citing papers explorer
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Quantum Transport in Disordered Spin Networks: Emergent Timescales and Competing Pathways
Geometric heterogeneity in small disordered spin networks with dipolar couplings and dephasing produces separated dynamical timescales, with a parametrically long relaxation time arising from effective detuning in strongly hybridized clusters.
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Nonreciprocity-enriched steady phases in open quantum systems
Nonreciprocity combined with open boundaries and symmetry defects produces a domain-wall traveling-wave phase and anomalous chiral relaxation in open quantum systems.
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Critical Dynamics of Non-Reciprocally Coupled Conserved Systems
For n-component conserved fields with nonlinear non-reciprocal coupling, one-loop RG shows that n ≥ 4 yields a fixed point with emergent detailed balance and fewer independent exponents due to conservation.