Spatially resolved spectroscopy of alkali metal vapour diffusing inside hollow-core photonic crystal fibres

Häupl D, Weller D, Loew R, Joly N (2022)

Publication Type: Journal article

Publication year: 2022

Journal

New Journal of Physics Institute of Physics: Open Access Journals / Institute of Physics (IoP) and Deutsche Physikalische Gesellschaft

Book Volume: 24

Journal Issue: 11

DOI: 10.1088/1367-2630/ac9db6

Abstract

We present a new type of compact and all-glass based vapour cell integrating hollow-core photonic crystal fibres. The absence of metals, as in a traditional vacuum chamber and the much more compact geometry allows for fast and homogeneous heating. As a consequence we can fill the fibres on much faster timescales, ranging from minutes to hours. Additionally the all-glass design ensures optical access along the fibre. This allows live monitoring of the diffusion of rubidium atoms inside the hollow-core by measuring the frequency-dependent fluorescence from the atoms. The atomic density is numerically retrieved using a five-level system of Bloch-equations.

Authors with CRIS profile

Daniel Häupl Professur für Experimentalphysik (Photonik) Nicolas Joly Professur für Experimentalphysik (Photonik)

Involved external institutions

Universität Stuttgart DE Germany (DE)

How to cite

APA:

Häupl, D., Weller, D., Loew, R., & Joly, N. (2022). Spatially resolved spectroscopy of alkali metal vapour diffusing inside hollow-core photonic crystal fibres. New Journal of Physics, 24(11). https://dx.doi.org/10.1088/1367-2630/ac9db6

MLA:

Häupl, Daniel, et al. "Spatially resolved spectroscopy of alkali metal vapour diffusing inside hollow-core photonic crystal fibres." New Journal of Physics 24.11 (2022).

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