UV light-induced atom desorption for large rubidium and potassium magneto-optical traps

TL;DR

This paper demonstrates that UV light-induced atom desorption (LIAD) effectively provides a controllable atomic source for large rubidium and potassium magneto-optical traps, enabling fast switching and long coherence times.

Contribution

It introduces the use of LIAD at short wavelengths for efficient, rapid control of vapor pressure in large MOTs for Rb-87 and K-40, with detailed wavelength dependence analysis.

Findings

High loading rates achieved without secondary sources

Rapid pressure decay allows long trapping lifetimes

Partial pressures sufficient for large MOTs with minimal light power

Abstract

We show that light-induced atom desorption (LIAD) can be used as a flexible atomic source for large Rb-87 and K-40 magneto-optical traps. The use of LIAD at short wavelengths allows for fast switching of the desired vapor pressure and permits experiments with long trapping and coherence times. The wavelength dependence of the LIAD effect for both species was explored in a range from 630 nm to 253 nm in an uncoated quartz cell and a stainless steel chamber. Only a few mW/cm^2 of near-UV light produce partial pressures that are high enough to saturate a magneto-optical trap at 3.5 x 10^9 Rb atoms or 7 x 10^7 K atoms. Loading rates as high as 1.2 x 10^9 Rb atoms/s and 8 x 10^7 K atoms/s were achieved without the use of a secondary atom source. After the desorption light is turned off, the pressure quickly decays back to equilibrium with a time constant as short as 200 us, allowing for long trapping lifetimes after the MOT loading phase.