In the Zeno regime of a continuously monitored Aubry-André-Harper chain, an effective non-Hermitian Hamiltonian derived from self-consistent measurement potentials yields a Lyapunov exponent whose predicted localization length quantitatively matches numerical quantum-state-diffusion trajectories.
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Finite temperature strongly enhances low-frequency optical conductivity near the localization transition in the Aubry-André model via thermal activation of Pauli-blocked transitions between resonant van Hove singularities.
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Controlled Zeno-Induced Localization of Free Fermions in a Quasiperiodic Chain
In the Zeno regime of a continuously monitored Aubry-André-Harper chain, an effective non-Hermitian Hamiltonian derived from self-consistent measurement potentials yields a Lyapunov exponent whose predicted localization length quantitatively matches numerical quantum-state-diffusion trajectories.
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Temperature-induced optical enhancement near a localization transition
Finite temperature strongly enhances low-frequency optical conductivity near the localization transition in the Aubry-André model via thermal activation of Pauli-blocked transitions between resonant van Hove singularities.