Surface scattering of atoms for high-sensitivity spectroscopy

TL;DR

This paper demonstrates that PDMS-coated surfaces can effectively cool atoms through surface scattering, enabling high-sensitivity spectroscopy applications by producing colder, more collimated atomic beams at room temperature.

Contribution

It reveals that PDMS surfaces can cool atoms from high temperatures to room temperature with a single scattering, and shows potential for improved atomic sources in spectroscopy.

Findings

PDMS coating cools atoms from ~1400 K to room temperature.

Single scattering equilibrates atoms with surface temperature.

Surface scattering can produce collimated, low-velocity atomic beams.

Abstract

High-sensitivity laser spectroscopy is integral to applications like atomic clocks, quantum computers, and chemical sensing. Lowering atomic temperature decreases spectral Doppler broadening and increases transit time across the excitation laser. We find that a polydimethylsiloxane (PDMS) coated surface can cool iron atoms from ~1400 K to room temperature by surface scattering. It is also apparent that a single scattering event is enough for atoms to equilibrate with the PDMS surface temperature. Further, we show the very low adsorption of iron and ytterbium atoms on PDMS, an effect that persists to surface temperatures of 200 K. Through numerical simulation, we demonstrate the potential use of surface scattering in making a room temperature source of collimated atoms with enhanced flux and reduced velocity compared to that without surface scattering.