Light-matter interaction in open cavities with dielectric stacks

Astghik Saharyan; Juan Rafael Álvarez; Thomas H. Doherty; Axel Kuhn; Stéphane Guérin

doi:10.1063/5.0047145

Light-matter interaction in open cavities with dielectric stacks

Astghik Saharyan, Juan Rafael Álvarez, Thomas H. Doherty, Axel Kuhn, Stéphane Guérin

Research output: Contribution to journal › Article › peer-review

Abstract

We evaluate the exact dipole coupling strength between a single emitter and the radiation field within an optical cavity, taking into account the effects of multilayer dielectric mirrors. Our model allows one to freely vary the resonance frequency of the cavity, the frequency of light or atomic transition addressing it, and the design wavelength of the dielectric mirror. The coupling strength is derived for an open system with unbound frequency modes. For very short cavities, the effective length used to determine their mode volume and the lengths defining their resonances are different, and also found to diverge appreciably from their geometric length, with the radiation field being strongest within the dielectric mirror itself. Only for cavities much longer than their resonant wavelength does the mode volume asymptotically approach that normally assumed from their geometric length.

Original language	English
Article number	154002
Journal	Applied Physics Letters
Volume	118
Issue number	15
DOIs	https://doi.org/10.1063/5.0047145
Publication status	Published - 12 Apr 2021
Externally published	Yes

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title = "Light-matter interaction in open cavities with dielectric stacks",

abstract = "We evaluate the exact dipole coupling strength between a single emitter and the radiation field within an optical cavity, taking into account the effects of multilayer dielectric mirrors. Our model allows one to freely vary the resonance frequency of the cavity, the frequency of light or atomic transition addressing it, and the design wavelength of the dielectric mirror. The coupling strength is derived for an open system with unbound frequency modes. For very short cavities, the effective length used to determine their mode volume and the lengths defining their resonances are different, and also found to diverge appreciably from their geometric length, with the radiation field being strongest within the dielectric mirror itself. Only for cavities much longer than their resonant wavelength does the mode volume asymptotically approach that normally assumed from their geometric length.",

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AU - Saharyan, Astghik

AU - Álvarez, Juan Rafael

AU - Doherty, Thomas H.

AU - Kuhn, Axel

AU - Guérin, Stéphane

PY - 2021/4/12

Y1 - 2021/4/12

N2 - We evaluate the exact dipole coupling strength between a single emitter and the radiation field within an optical cavity, taking into account the effects of multilayer dielectric mirrors. Our model allows one to freely vary the resonance frequency of the cavity, the frequency of light or atomic transition addressing it, and the design wavelength of the dielectric mirror. The coupling strength is derived for an open system with unbound frequency modes. For very short cavities, the effective length used to determine their mode volume and the lengths defining their resonances are different, and also found to diverge appreciably from their geometric length, with the radiation field being strongest within the dielectric mirror itself. Only for cavities much longer than their resonant wavelength does the mode volume asymptotically approach that normally assumed from their geometric length.

AB - We evaluate the exact dipole coupling strength between a single emitter and the radiation field within an optical cavity, taking into account the effects of multilayer dielectric mirrors. Our model allows one to freely vary the resonance frequency of the cavity, the frequency of light or atomic transition addressing it, and the design wavelength of the dielectric mirror. The coupling strength is derived for an open system with unbound frequency modes. For very short cavities, the effective length used to determine their mode volume and the lengths defining their resonances are different, and also found to diverge appreciably from their geometric length, with the radiation field being strongest within the dielectric mirror itself. Only for cavities much longer than their resonant wavelength does the mode volume asymptotically approach that normally assumed from their geometric length.

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DO - 10.1063/5.0047145

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SN - 0003-6951

VL - 118

JO - Applied Physics Letters

JF - Applied Physics Letters

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ER -

Light-matter interaction in open cavities with dielectric stacks

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