Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems

M. Widmann; S. L. Portalupi; P. Michler; J. Wrachtrup; I. Gerhardt

doi:10.1109/LPT.2018.2871770

Details

Original language	English
Article number	8470115
Pages (from-to)	2083-2086
Number of pages	4
Journal	Photonic Technology Letters
Volume	30
Issue number	24
Publication status	Published - 15 Dec 2018
Externally published	Yes

Abstract

Narrow-band filtering of light is widely used in optical spectroscopy. Atomic filters, which rely on the Faraday effect, allow for GHz-wide transmission spectra, which are intrinsically matched to an atomic transition. We present an experimental realization and a theoretical study of a Faraday filter based on cesium and its D ₁-line-transition ( $6{2}S-{1/2}\rightarrow 6{2}P-{1/2}$ ) around 894 nm. We also present the prospects and visions for combining this filter with the single photon emission of a single quantum dot, which matches with the atomic transition. The option to lock the spectral position of a quantum dot is discussed at the end of this letter.

Keywords

Photonics, Cesium, Atom optics, Optical polarization, Temperature measurement, Magnetic flux, Amplitude modulation, Atomic filter, Faraday filter, Quantum dots, Quantum Hybrid Devices, quantum hybrid devices, quantum dots

ASJC Scopus subject areas

Materials Science(all)
Electronic, Optical and Magnetic Materials
Physics and Astronomy(all)
Atomic and Molecular Physics, and Optics
Engineering(all)
Electrical and Electronic Engineering

Cite this

Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems. / Widmann, M.; Portalupi, S. L.; Michler, P. et al.
In: Photonic Technology Letters, Vol. 30, No. 24, 8470115, 15.12.2018, p. 2083-2086.

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

Widmann, M, Portalupi, SL, Michler, P, Wrachtrup, J & Gerhardt, I 2018, 'Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems', Photonic Technology Letters, vol. 30, no. 24, 8470115, pp. 2083-2086. https://doi.org/10.1109/LPT.2018.2871770

Widmann, M., Portalupi, S. L., Michler, P., Wrachtrup, J., & Gerhardt, I. (2018). Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems. Photonic Technology Letters, 30(24), 2083-2086. Article 8470115. https://doi.org/10.1109/LPT.2018.2871770

Widmann M, Portalupi SL, Michler P, Wrachtrup J, Gerhardt I. Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems. Photonic Technology Letters. 2018 Dec 15;30(24):2083-2086. 8470115. doi: 10.1109/LPT.2018.2871770

Widmann, M. ; Portalupi, S. L. ; Michler, P. et al. / Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems. In: Photonic Technology Letters. 2018 ; Vol. 30, No. 24. pp. 2083-2086.

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abstract = "Narrow-band filtering of light is widely used in optical spectroscopy. Atomic filters, which rely on the Faraday effect, allow for GHz-wide transmission spectra, which are intrinsically matched to an atomic transition. We present an experimental realization and a theoretical study of a Faraday filter based on cesium and its D 1-line-transition ( $6{2}S-{1/2}\rightarrow 6{2}P-{1/2}$ ) around 894 nm. We also present the prospects and visions for combining this filter with the single photon emission of a single quantum dot, which matches with the atomic transition. The option to lock the spectral position of a quantum dot is discussed at the end of this letter. ",

keywords = "Photonics, Cesium, Atom optics, Optical polarization, Temperature measurement, Magnetic flux, Amplitude modulation, Atomic filter, Faraday filter, Quantum dots, Quantum Hybrid Devices, quantum hybrid devices, quantum dots",

author = "M. Widmann and Portalupi, {S. L.} and P. Michler and J. Wrachtrup and I. Gerhardt",

note = "Funding Information: Manuscript received July 2, 2018; revised August 23, 2018; accepted September 13, 2018. Date of publication September 24, 2018; date of current version November 28, 2018. This work was supported in part by the MPG, in part by the DFG under Project MI 500/30-1 and Project GE 2737/5-1, and in part by the project Q.COM. (Corresponding author: Ilja Gerhardt.) M. Widmann is with the Institute of Physics, University of Stuttgart, 70569 Stuttgart, Germany. ",

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AU - Portalupi, S. L.

AU - Michler, P.

AU - Wrachtrup, J.

AU - Gerhardt, I.

N1 - Funding Information: Manuscript received July 2, 2018; revised August 23, 2018; accepted September 13, 2018. Date of publication September 24, 2018; date of current version November 28, 2018. This work was supported in part by the MPG, in part by the DFG under Project MI 500/30-1 and Project GE 2737/5-1, and in part by the project Q.COM. (Corresponding author: Ilja Gerhardt.) M. Widmann is with the Institute of Physics, University of Stuttgart, 70569 Stuttgart, Germany.

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AB - Narrow-band filtering of light is widely used in optical spectroscopy. Atomic filters, which rely on the Faraday effect, allow for GHz-wide transmission spectra, which are intrinsically matched to an atomic transition. We present an experimental realization and a theoretical study of a Faraday filter based on cesium and its D 1-line-transition ( $6{2}S-{1/2}\rightarrow 6{2}P-{1/2}$ ) around 894 nm. We also present the prospects and visions for combining this filter with the single photon emission of a single quantum dot, which matches with the atomic transition. The option to lock the spectral position of a quantum dot is discussed at the end of this letter.

KW - Photonics

KW - Cesium

KW - Atom optics

KW - Optical polarization

KW - Temperature measurement

KW - Magnetic flux

KW - Amplitude modulation

KW - Atomic filter

KW - Faraday filter

KW - Quantum dots

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KW - quantum hybrid devices

KW - quantum dots

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Research@Leibniz University

Faraday Filtering on the Cs-D1-Line for Quantum Hybrid Systems

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ASJC Scopus subject areas

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