Non-Hermitian optical dimers coupled to superfluids enable topological sensing of superfluid winding numbers via exceptional-point eigenmode permutations in optical transmission.
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A globally well-defined phenomenological spectral density is proposed for the bath that reproduces near-resonance non-Ohmic power-law behavior, yields a nonlocal mechanical susceptibility with analytic poles encoding the linewidth, and enables reconstruction of the full susceptibility via homodyne-d
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Topological sensing of superfluid rotation using non-Hermitian optical dimers
Non-Hermitian optical dimers coupled to superfluids enable topological sensing of superfluid winding numbers via exceptional-point eigenmode permutations in optical transmission.
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Modeling the non-Markovian Brownian motion of an optomechanical resonator
A globally well-defined phenomenological spectral density is proposed for the bath that reproduces near-resonance non-Ohmic power-law behavior, yields a nonlocal mechanical susceptibility with analytic poles encoding the linewidth, and enables reconstruction of the full susceptibility via homodyne-d