Sisyphus Cooling of Electrically Trapped Polyatomic Molecules

TL;DR

This paper demonstrates a novel opto-electrical cooling method for polyatomic molecules, achieving significant temperature reduction and phase-space density increase, paving the way for ultracold polyatomic molecular research.

Contribution

The authors experimentally realize a new cooling technique that efficiently cools polyatomic molecules in a trap, overcoming previous intractability and enabling ultracold molecular applications.

Findings

Reduced temperature of CH3F molecules by a factor of 13.5

Increased phase-space density by a factor of 29 (or 70 accounting for trap losses)

Achieved long trapping times up to 27 seconds

Abstract

The rich internal structure and long-range dipole-dipole interactions establish polar molecules as unique instruments for quantum-controlled applications and fundamental investigations. Their potential fully unfolds at ultracold temperatures, where a plethora of effects is predicted in many-body physics, quantum information science, ultracold chemistry, and physics beyond the standard model. These objectives have inspired the development of a wide range of methods to produce cold molecular ensembles. However, cooling polyatomic molecules to ultracold temperatures has until now seemed intractable. Here we report on the experimental realization of opto-electrical cooling, a paradigm-changing cooling and accumulation method for polar molecules. Its key attribute is the removal of a large fraction of a molecule's kinetic energy in each step of the cooling cycle via a Sisyphus effect, allowing cooling with only few dissipative decay processes. We demonstrate its potential by reducing the temperature of about 10^6 trapped CH_3F molecules by a factor of 13.5, with the phase-space density increased by a factor of 29 or a factor of 70 discounting trap losses. In contrast to other cooling mechanisms, our scheme proceeds in a trap, cools in all three dimensions, and works for a large variety of polar molecules. With no fundamental temperature limit anticipated down to the photon-recoil temperature in the nanokelvin range, our method eliminates the primary hurdle in producing ultracold polyatomic molecules. The low temperatures, large molecule numbers and long trapping times up to 27 s will allow an interaction-dominated regime to be attained, enabling collision studies and investigation of evaporative cooling toward a BEC of polyatomic molecules.