Local monitoring at a quantum point contact produces linear entanglement growth to a volume-law maximum then slow decay to zero, captured by a quasiparticle picture with an emergent decaying bias voltage.
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Finite direct phonon-phonon coupling in a two-mirror parametrically assisted optomechanical cavity mixes a weakly participating collective mode into the optically visible spectrum, rendering a third resonance resolvable.
Exceptional points in mechanically coupled gain-loss oscillators induce steady quantum phase synchronization and bipartite Gaussian entanglement above a critical driving power in the weak coupling regime.
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Entanglement Dynamics across a Monitored Quantum Point Contact
Local monitoring at a quantum point contact produces linear entanglement growth to a volume-law maximum then slow decay to zero, captured by a quasiparticle picture with an emergent decaying bias voltage.
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Phonon-phonon interaction as a control knob for multimode splitting in a two mirror parametrically assisted optomechanical cavity
Finite direct phonon-phonon coupling in a two-mirror parametrically assisted optomechanical cavity mixes a weakly participating collective mode into the optically visible spectrum, rendering a third resonance resolvable.
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Exceptional point induced quantum phase synchronization and entanglement dynamics in mechanically coupled gain-loss oscillators
Exceptional points in mechanically coupled gain-loss oscillators induce steady quantum phase synchronization and bipartite Gaussian entanglement above a critical driving power in the weak coupling regime.