Temperature and wall coating dependence of alkali vapor transport speed in micron-scale capillaries

Giraud-Carrier, Matthieu; Decker, Trevor K.; McClellan, Joshua S.; Bennett, Linsey; Hawkins, Aaron R.; Black, Jennifer A.; Almquist, Soren; Schmidt, Holger

doi:10.1116/1.4978888

Cited by 4 publications

(1 citation statement)

References 17 publications

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“…The angular and velocity distributions of the desorbed atoms from the coating material also influence the behavior of atoms on the coating [23]. From a practical perspective, the angular and velocity distributions provide insight into the transport of atoms inside a confined device that has a coating [24], given that the effect of atom-surface scattering on the atomic flow becomes more pronounced as the device becomes miniaturized. Additionally, a better understanding of atom transport from the coating will be useful for laser cooling and trapping of short-lived radioactive alkali isotopes [25][26][27][28] for electric dipole moment and parity-nonconservation interaction investigations.…”

Section: Introductionmentioning

confidence: 99%

Scattering of an alkali-metal atomic beam on anti-spin-relaxation coatings

et al. 2018

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We performed scattering experiments using a rubidium (Rb) atomic beam on paraffin films and measured the angular and velocity distributions of scattered atoms. The paraffin films were prepared in various ways and characterized by atomic force microscopy and X-ray diffraction. The films exhibited various roughnesses and crystal structures. The paraffin films preserved the spin polarization of the scattered atoms. The measured angular distributions of all prepared films were consistent with Knudsen's cosine law. The velocity distributions were well fitted by Maxwell's distribution, characterized by a temperature much closer to the film temperature than to the atomic-beam temperature. We therefore concluded that the Rb atoms were well thermalized with the paraffin films via single scattering events. * hatakeya@cc.tuat.ac.jp 1 arXiv:1807.02329v1 [physics.atom-ph]

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Section: Introductionmentioning

confidence: 99%

Scattering of an alkali-metal atomic beam on anti-spin-relaxation coatings

et al. 2018

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Analysis of background gas in an alkali-metal vapor cell coated with paraffin

et al. 2019

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Investigation of alkali vapor diffusion characteristics through microchannels

et al. 2022

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We present Rb vapor transport through micro-scale capillaries on the impact of temperature and capillary inner diameters in the limits of Knudsen number Kn>>1. Daily absorption spectral measurements were taken over several months to evaluate the dynamics of transport. We provide new insights into the diffusion mechanism and observe a quasi-single-layer coating on the surface based on the analysis of a slowly increasing absorption signal. The dwell time of the atom on the glass is directly derived from the diffusion dynamics at different temperatures. According to the mass flow rate, higher vapor temperatures caused a faster transport speed, indicating rapid loading in microchannels. We provide a valuable model for future quantum device implementation through the use of miniaturized structures such as photonic crystal fibers and optical waveguides.

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Temperature and wall coating dependence of alkali vapor transport speed in micron-scale capillaries

Cited by 4 publications

References 17 publications

Scattering of an alkali-metal atomic beam on anti-spin-relaxation coatings

Scattering of an alkali-metal atomic beam on anti-spin-relaxation coatings

Analysis of background gas in an alkali-metal vapor cell coated with paraffin

Investigation of alkali vapor diffusion characteristics through microchannels

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