Generation and dynamics of entangled fermion-photon-phonon states in nanocavities

Mikhail Tokman, Maria Erukhimova, Yongrui Wang, Qianfan Chen, Alexey Belyanin

Research output: Chapter in Book/Report/Conference proceedingChapterpeer-review

Abstract

We develop the analytic theory describing the formation and evolution of entangled quantum states for a fermionic quantum emitter coupled simultaneously to a quantized electromagnetic field in a nanocavity and quantized phonon or mechanical vibrational modes. The theory is applicable to a broad range of cavity quantum optomechanics problems and emerging research on plas-monic nanocavities coupled to single molecules and other quantum emitters. The optimal conditions for a tripartite entanglement are realized near the parametric resonances in a coupled system. The model includes dissipation and decoherence effects due to coupling of the fermion, photon, and phonon subsystems to their dissipative reservoirs within the stochastic evolution approach, which is derived from the Heisenberg-Langevin formalism. Our theory provides analytic expressions for the time evolution of the quantum state and observables and the emission spectra. The limit of a classical acoustic pumping and the interplay between parametric and standard one-photon resonances are analyzed.

Original languageEnglish
Title of host publicationFrontiers in Optics and Photonics
Publisherde Gruyter
Pages505-525
Number of pages21
ISBN (Electronic)9783110710687
ISBN (Print)9783110709735
DOIs
StatePublished - 8 Jun 2021
Externally publishedYes

Keywords

  • Cavity optomechanics
  • Cavity quantum electrodynamics
  • Entanglement
  • Quantum acoustics
  • Quantum information
  • Quantum optics

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