Narrowline Laser Cooling and Spectroscopy of Molecules via Stark States

Abstract: The electronic energy level structure of yttrium monoxide (YO) provides long-lived excited $^{2}\Delta$ states ideal for high-precision molecular spectroscopy, narrowline laser cooling at the single photon-recoil limit, and studying dipolar physics with unprecedented interaction strength. We use ultracold laser-cooled YO molecules to study the Stark effect in the metastable A$^{\prime}\,^{2}\Delta_{3/2}\,J=3/2$ state by high-resolution laser spectroscopy. We determined the absolute transition frequency from this metastable state to the X$\,^2\Sigma^+$ electronic ground state with a fractional uncertainty of 9 $\times$ 10$^{-12}$. In the presence of weak electric fields a linear Stark effect is observed in the A$^{\prime}\,^{2}\Delta_{3/2}$ state owing to the large electric dipole moment and near degenerate $\Lambda$-doublet states. A quasi-closed photon cycling scheme is identified involving a narrowline transition to a single Stark state, and implemented in free space to demonstrate the first narrowline laser cooling of a molecule, reducing the temperature of sub-Doppler cooled YO in two dimensions.