Stochastic noise constructively enhances edge self-healing in non-Hermitian systems: weak noise aligns finite-time Lyapunov exponents to prolong healing, while strong noise induces effective non-unitary drift-diffusion for universal asymptotic recovery.
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Ornstein-Uhlenbeck noise resurrects the dynamical skin effect in quasiperiodic non-Hermitian systems by mapping the dynamics to a non-reciprocal master equation with a noise-induced point gap.
The phase of the two-photon drive tunes Liouvillian exceptional points of order 2 and 3 in a cat qubit, identified by a winding-number topological invariant while preserving logical subspace fidelity.
citing papers explorer
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Noise-Enhanced Self-Healing Dynamics in Non-Hermitian Systems
Stochastic noise constructively enhances edge self-healing in non-Hermitian systems: weak noise aligns finite-time Lyapunov exponents to prolong healing, while strong noise induces effective non-unitary drift-diffusion for universal asymptotic recovery.
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Noise-Induced Resurrection of Dynamical Skin Effects in Quasiperiodic Non-Hermitian Systems
Ornstein-Uhlenbeck noise resurrects the dynamical skin effect in quasiperiodic non-Hermitian systems by mapping the dynamics to a non-reciprocal master equation with a noise-induced point gap.
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Controllable non-Hermitian topology in a dynamically protected cat qubit
The phase of the two-photon drive tunes Liouvillian exceptional points of order 2 and 3 in a cat qubit, identified by a winding-number topological invariant while preserving logical subspace fidelity.