Diffuse Laser Cooling Based on the $6\mathrm{P}_{3/2}$ Excited State of Rubidium Atoms via 420 nm Blue Light

TL;DR

This paper demonstrates a novel method of laser cooling rubidium atoms directly with 420 nm blue light targeting the high excited state, enabling the creation of a long, cold atomic cloud for advanced quantum applications.

Contribution

It introduces the first successful diffuse laser cooling of rubidium atoms using 420 nm blue light on the $6 ext{P}_{3/2}$ state, expanding cooling techniques to higher excited states.

Findings

Achieved cold rubidium cloud with approximately 4.4×10^7 atoms.

Successfully cooled atoms over a one-meter length using 420 nm light.

Verified the feasibility of blue light cooling compared to traditional methods.

Abstract

To date, the laser cooling of rubidium atoms has inevitably relied on 780 nm cooling light corresponding to the first excited state $5\mathrm{P}_{3/2}$. Surprisingly, we demonstrate laser cooling directly utilizing 420 nm blue light for active optical clock, which corresponds to the high excited state $6\mathrm{P}_{3/2}$ of Rb atom. Experimentally, we successfully apply the 420 nm diffuse laser cooling technique to prepare a cold $^{87}\mathrm{Rb}$ atomic cloud with a length of up to one meter, and measure the cold-atom absorption spectroscopy. The cold atom number is approximately $4.4\times10^{7}$. We systematically compare the cooling effects of 420 nm and 780 nm diffuse laser cooling, and verify the feasibility of blue light cooling using high excited state. This work directly employs blue light to cool and manipulate ground-state Rb atoms to the 6P excited state, providing a new and efficient approach for the cold-atom active optical clock. It is also expected to open up research directions and application prospects in frontier fields such as Rydberg atoms, ultracold quantum gases Bose-Einstein condensation, quantum information, and so on.