Cavity QED with chip-based toroidal microresonators

B. Dayan; T. Aoki; E. Wilcut; S. Kelber; W. P. Bowen; A. S. Parkins; J. R. Petta; T. J. Kippenberg; E. Ostby; K. J. Vahala; H. J. Kimble

doi:10.1117/12.734875

Cavity QED with chip-based toroidal microresonators

B. Dayan^*, T. Aoki, E. Wilcut, S. Kelber, W. P. Bowen, A. S. Parkins, J. R. Petta, T. J. Kippenberg, E. Ostby, K. J. Vahala, H. J. Kimble

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Citation (Scopus)

Abstract

We report the demonstration of strong coupling between single Cesium atoms and a high-Q chip-based microresonator. Our toroidal microresonators are compact, Si chip-based whispering gallery mode resonators that confine light to small volumes with extremely low losses, and are manufactured in large numbers by standard lithographic techniques. Combined with the capability to couple efficiently light to and from these microresonators by a tapered optical fiber, toroidal microresonators offer a promising avenue towards scalable quantum networks. Experimentally, laser cooled Cs atoms are dropped onto a toroidal microresonator while a probe beam is critically coupled to the cavity mode. When an atom interacts with the cavity, it modifies the resonance spectrum of the cavity, leading to rejection of some of the probe light from the cavity, and thus to an increase in the output power. By observing such transit events while systematically detuning the cavity from the atomic resonance, we determine the maximal accessible single-photon Rabi frequency of Ω₀/2π (100 ± 24) MHz. This value puts our system in the regime of strong coupling, being significantly larger than the dissipation rates in our system.

Original language	English
Title of host publication	Quantum Communications and Quantum Imaging V
DOIs	https://doi.org/10.1117/12.734875
Publication status	Published - 2007
Externally published	Yes
Event	Quantum Communications and Quantum Imaging V - San Diego, CA, United States Duration: 2007 Aug 26 → 2007 Aug 28

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	6710
ISSN (Print)	0277-786X

Conference

Conference	Quantum Communications and Quantum Imaging V
Country/Territory	United States
City	San Diego, CA
Period	07/8/26 → 07/8/28

Keywords

Cavity quantum electrodynamics microresonators quantum optics cold atoms

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Computer Science Applications
Applied Mathematics
Electrical and Electronic Engineering

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10.1117/12.734875

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Dayan, B., Aoki, T., Wilcut, E., Kelber, S., Bowen, W. P., Parkins, A. S., Petta, J. R., Kippenberg, T. J., Ostby, E., Vahala, K. J., & Kimble, H. J. (2007). Cavity QED with chip-based toroidal microresonators. In Quantum Communications and Quantum Imaging V Article 67100H (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 6710). https://doi.org/10.1117/12.734875

Dayan, B, Aoki, T, Wilcut, E, Kelber, S, Bowen, WP, Parkins, AS, Petta, JR, Kippenberg, TJ, Ostby, E, Vahala, KJ & Kimble, HJ 2007, Cavity QED with chip-based toroidal microresonators. in Quantum Communications and Quantum Imaging V., 67100H, Proceedings of SPIE - The International Society for Optical Engineering, vol. 6710, Quantum Communications and Quantum Imaging V, San Diego, CA, United States, 07/8/26. https://doi.org/10.1117/12.734875

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abstract = "We report the demonstration of strong coupling between single Cesium atoms and a high-Q chip-based microresonator. Our toroidal microresonators are compact, Si chip-based whispering gallery mode resonators that confine light to small volumes with extremely low losses, and are manufactured in large numbers by standard lithographic techniques. Combined with the capability to couple efficiently light to and from these microresonators by a tapered optical fiber, toroidal microresonators offer a promising avenue towards scalable quantum networks. Experimentally, laser cooled Cs atoms are dropped onto a toroidal microresonator while a probe beam is critically coupled to the cavity mode. When an atom interacts with the cavity, it modifies the resonance spectrum of the cavity, leading to rejection of some of the probe light from the cavity, and thus to an increase in the output power. By observing such transit events while systematically detuning the cavity from the atomic resonance, we determine the maximal accessible single-photon Rabi frequency of Ω0/2π (100 ± 24) MHz. This value puts our system in the regime of strong coupling, being significantly larger than the dissipation rates in our system.",

keywords = "Cavity quantum electrodynamics microresonators quantum optics cold atoms",

author = "B. Dayan and T. Aoki and E. Wilcut and S. Kelber and Bowen, {W. P.} and Parkins, {A. S.} and Petta, {J. R.} and Kippenberg, {T. J.} and E. Ostby and Vahala, {K. J.} and Kimble, {H. J.}",

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AU - Dayan, B.

AU - Aoki, T.

AU - Wilcut, E.

AU - Kelber, S.

AU - Bowen, W. P.

AU - Parkins, A. S.

AU - Petta, J. R.

AU - Kippenberg, T. J.

AU - Ostby, E.

AU - Vahala, K. J.

AU - Kimble, H. J.

PY - 2007

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N2 - We report the demonstration of strong coupling between single Cesium atoms and a high-Q chip-based microresonator. Our toroidal microresonators are compact, Si chip-based whispering gallery mode resonators that confine light to small volumes with extremely low losses, and are manufactured in large numbers by standard lithographic techniques. Combined with the capability to couple efficiently light to and from these microresonators by a tapered optical fiber, toroidal microresonators offer a promising avenue towards scalable quantum networks. Experimentally, laser cooled Cs atoms are dropped onto a toroidal microresonator while a probe beam is critically coupled to the cavity mode. When an atom interacts with the cavity, it modifies the resonance spectrum of the cavity, leading to rejection of some of the probe light from the cavity, and thus to an increase in the output power. By observing such transit events while systematically detuning the cavity from the atomic resonance, we determine the maximal accessible single-photon Rabi frequency of Ω0/2π (100 ± 24) MHz. This value puts our system in the regime of strong coupling, being significantly larger than the dissipation rates in our system.

AB - We report the demonstration of strong coupling between single Cesium atoms and a high-Q chip-based microresonator. Our toroidal microresonators are compact, Si chip-based whispering gallery mode resonators that confine light to small volumes with extremely low losses, and are manufactured in large numbers by standard lithographic techniques. Combined with the capability to couple efficiently light to and from these microresonators by a tapered optical fiber, toroidal microresonators offer a promising avenue towards scalable quantum networks. Experimentally, laser cooled Cs atoms are dropped onto a toroidal microresonator while a probe beam is critically coupled to the cavity mode. When an atom interacts with the cavity, it modifies the resonance spectrum of the cavity, leading to rejection of some of the probe light from the cavity, and thus to an increase in the output power. By observing such transit events while systematically detuning the cavity from the atomic resonance, we determine the maximal accessible single-photon Rabi frequency of Ω0/2π (100 ± 24) MHz. This value puts our system in the regime of strong coupling, being significantly larger than the dissipation rates in our system.

KW - Cavity quantum electrodynamics microresonators quantum optics cold atoms

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Cavity QED with chip-based toroidal microresonators

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