Micro-fabricated caesium vapour cell with 5mm optical path length

Terry Dyer; S.J. Ingleby; Camelia Dunare; K. Dodds; Peter Lomax; P.F.  Griffin; E. Riis

doi:10.1063/5.0125490

Micro-fabricated caesium vapour cell with 5mm optical path length

Terry Dyer, S.J. Ingleby, Camelia Dunare, K. Dodds, Peter Lomax, P.F. Griffin, E. Riis

School of Engineering

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

Abstract

Micro-fabricated vapor cells have applications in a number of emerging quantum technology-based devices including miniaturized atomic magnetometers, atomic clocks, and frequency references for laser systems. Increasing the cell optical path length (OPL) and smallest cell dimension are normally desirable to increase the signal to noise ratio (SNR) and minimize the de-polarization rate due to collisions between atomic or molecular species and the cell walls. This paper presents a fully wafer-level scalable fabrication process to manufacture vapor cells with dimensions approaching those of glass-blown cells. The fabrication process is described, and spectroscopic measurements (optical absorption and magnetic resonance) are reported. A magnetic resonance linewidth of 350 Hz is demonstrated, and this is the smallest linewidth reported to date for a micro-fabricated vapor cell.

Original language	English
Article number	204401
Journal	Journal of applied physics
Volume	132
Issue number	20
Early online date	22 Nov 2022
DOIs	https://doi.org/10.1063/5.0125490
Publication status	Published - 28 Nov 2022

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10.1063/5.0125490Licence: Creative Commons: Attribution (CC-BY)

JAP22-MD-05029Accepted author manuscript, 1.9 MB

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title = "Micro-fabricated caesium vapour cell with 5mm optical path length",

abstract = "Micro-fabricated vapor cells have applications in a number of emerging quantum technology-based devices including miniaturized atomic magnetometers, atomic clocks, and frequency references for laser systems. Increasing the cell optical path length (OPL) and smallest cell dimension are normally desirable to increase the signal to noise ratio (SNR) and minimize the de-polarization rate due to collisions between atomic or molecular species and the cell walls. This paper presents a fully wafer-level scalable fabrication process to manufacture vapor cells with dimensions approaching those of glass-blown cells. The fabrication process is described, and spectroscopic measurements (optical absorption and magnetic resonance) are reported. A magnetic resonance linewidth of 350 Hz is demonstrated, and this is the smallest linewidth reported to date for a micro-fabricated vapor cell.",

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note = "Funding Information: The authors would like to thank Dr. Jonathan Pritchard for his work on the optical absorption spectroscopy setup. This work was funded in part by the UK Quantum Technology Hub in Sensing and Timing, EPSRC (Grant No EP/T001046/1). Publisher Copyright: {\textcopyright} 2022 Author(s).",

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AU - Dyer, Terry

AU - Ingleby, S.J.

AU - Dunare, Camelia

AU - Dodds, K.

AU - Lomax, Peter

AU - Griffin, P.F.

AU - Riis, E.

N1 - Funding Information: The authors would like to thank Dr. Jonathan Pritchard for his work on the optical absorption spectroscopy setup. This work was funded in part by the UK Quantum Technology Hub in Sensing and Timing, EPSRC (Grant No EP/T001046/1). Publisher Copyright: © 2022 Author(s).

PY - 2022/11/28

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N2 - Micro-fabricated vapor cells have applications in a number of emerging quantum technology-based devices including miniaturized atomic magnetometers, atomic clocks, and frequency references for laser systems. Increasing the cell optical path length (OPL) and smallest cell dimension are normally desirable to increase the signal to noise ratio (SNR) and minimize the de-polarization rate due to collisions between atomic or molecular species and the cell walls. This paper presents a fully wafer-level scalable fabrication process to manufacture vapor cells with dimensions approaching those of glass-blown cells. The fabrication process is described, and spectroscopic measurements (optical absorption and magnetic resonance) are reported. A magnetic resonance linewidth of 350 Hz is demonstrated, and this is the smallest linewidth reported to date for a micro-fabricated vapor cell.

AB - Micro-fabricated vapor cells have applications in a number of emerging quantum technology-based devices including miniaturized atomic magnetometers, atomic clocks, and frequency references for laser systems. Increasing the cell optical path length (OPL) and smallest cell dimension are normally desirable to increase the signal to noise ratio (SNR) and minimize the de-polarization rate due to collisions between atomic or molecular species and the cell walls. This paper presents a fully wafer-level scalable fabrication process to manufacture vapor cells with dimensions approaching those of glass-blown cells. The fabrication process is described, and spectroscopic measurements (optical absorption and magnetic resonance) are reported. A magnetic resonance linewidth of 350 Hz is demonstrated, and this is the smallest linewidth reported to date for a micro-fabricated vapor cell.

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Micro-fabricated caesium vapour cell with 5mm optical path length

Abstract

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