Simultaneous Zeeman deceleration of polyatomic free radical with lithium atoms

TL;DR

This paper proposes a novel method to decelerate polyatomic free radicals, specifically , using lithium atoms and a traveling wave magnetic decelerator, enabling future ultracold chemistry studies.

Contribution

It introduces a new deceleration scheme for polyatomic free radicals with lithium, advancing ultracold chemistry research beyond diatomic molecules.

Findings

Proposed a deceleration method for  using lithium atoms.

Paves the way for co-trapping and sympathetic cooling of free radicals.

Enables ultracold chemistry studies of complex molecules.

Abstract

Chemistry in the ultracold regime enables fully quantum-controlled interactions between atoms and molecules, leading to the discovery of the hidden mechanisms in chemical reactions which are usually curtained by thermal averaging in the high temperature. Recently a couple of diatomic molecules have been cooled to ultracold regime based on laser cooling techniques, but the chemistry associated with these simple molecules is highly limited. In comparison, free radicals play a major role in many important chemical reactions, but yet to be cooled to submillikelvin temperature. Here we propose a novel method of decelerating \ce{CH3}, the simplest polyatomic free radical, with lithium atoms simultaneously by travelling wave magnetic decelerator. This scheme paves the way towards co-trapping \ce{CH3} and lithium, so that sympathetical cooling can be used to preparing ultracold free radical sample.