A general non-equilibrium formalism for optomechanical forces on lossy bodies recovers Casimir and radiation pressure limits and predicts a purely quantum force from anisotropic squeezed vacuum relying only on second-order field correlations.
Title resolution pending
2 Pith papers cite this work. Polarity classification is still indexing.
2
Pith papers citing it
years
2026 2verdicts
UNVERDICTED 2representative citing papers
A timed-Dicke state of emitters hybridizes with a delocalized surface-plasmon mode to form a directional plasmon-polariton that shows Rabi oscillations, normal-mode splitting, three distinct decay regimes via Lyapunov analysis, and anticrossing in the emission spectrum from quantum vacuum effects.
citing papers explorer
-
Quantum optomechanics of lossy bodies: general approach and structured squeezed vacuum effects
A general non-equilibrium formalism for optomechanical forces on lossy bodies recovers Casimir and radiation pressure limits and predicts a purely quantum force from anisotropic squeezed vacuum relying only on second-order field correlations.
-
Collective light-matter interaction in plasmonic waveguide quantum electrodynamics
A timed-Dicke state of emitters hybridizes with a delocalized surface-plasmon mode to form a directional plasmon-polariton that shows Rabi oscillations, normal-mode splitting, three distinct decay regimes via Lyapunov analysis, and anticrossing in the emission spectrum from quantum vacuum effects.