Molecular electronic decoherence can qualitatively reverse (suppress versus enhance) the effect of metal nanoparticles on molecular light absorption according to multiscale simulations.
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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.
Numerical simulations of intracavity triplet down conversion identify steady-state regimes with measurable squeezing and entanglement, validated against Monte Carlo wave-function methods for low populations.
citing papers explorer
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Role of coherence in the plasmonic control of molecular absorption
Molecular electronic decoherence can qualitatively reverse (suppress versus enhance) the effect of metal nanoparticles on molecular light absorption according to multiscale simulations.
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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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Steady states, squeezing, and entanglement in intracavity triplet down conversion
Numerical simulations of intracavity triplet down conversion identify steady-state regimes with measurable squeezing and entanglement, validated against Monte Carlo wave-function methods for low populations.