Quantum theory of collective strong coupling of molecular vibrations with a microcavity mode

Quantum theory of collective strong coupling of molecular vibrations with a microcavity mode

We develop a quantum mechanical formalism to treat the strong coupling between an electromagnetic mode and a vibrational excitation of an ensemble of organic molecules. By employing a Bloch-Redfield-Wangsness approach, we show that the influence of dephasing-type interactions, i.e., elastic collisio...

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Bibliographic Details
Published in:New journal of physics Vol. 17; no. 5; pp. 53040 - 53049
Main Authors: Pino, Javier del, Feist, Johannes, Garcia-Vidal, Francisco J
Format: Journal Article
Language:English
Published: Bristol IOP Publishing 22-05-2015
Subjects:
Coupled modes
Coupling (molecular)
Dynamical systems
Dynamics
Eigenvectors
Elastic scattering
Energy transfer
Frequency ranges
Holes
Microcavities
Opto-mechanics
Organic chemistry
organic molecules
Phonons
Photonics
Physics
polaritons
Quantum mechanics
quantum optics
Quantum theory
Room temperature
strong coupling
Vibration
vibrational modes
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Summary:We develop a quantum mechanical formalism to treat the strong coupling between an electromagnetic mode and a vibrational excitation of an ensemble of organic molecules. By employing a Bloch-Redfield-Wangsness approach, we show that the influence of dephasing-type interactions, i.e., elastic collisions with a background bath of phonons, critically depends on the nature of the bath modes. In particular, for long-range phonons corresponding to a common bath, the dynamics of the 'bright state' (the collective superposition of molecular vibrations coupling to the cavity mode) is effectively decoupled from other system eigenstates. For the case of independent baths (or short-range phonons), incoherent energy transfer occurs between the bright state and the uncoupled dark states. However, these processes are suppressed when the Rabi splitting is larger than the frequency range of the bath modes, as achieved in a recent experiment (Shalabney et al 2015 Nat. Commun. 6 5981). In both cases, the dynamics can thus be described through a single collective oscillator coupled to a photonic mode, making this system an ideal candidate to explore cavity optomechanics at room temperature.
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ISSN:1367-2630
1367-2630
DOI:10.1088/1367-2630/17/5/053040