Two-Photon Pathway to Ultracold Ground State Molecules of 23Na40K

Abstract

We report on high-resolution spectroscopy of ultracold fermionic ~Feshbach molecules, and identify a two-photon pathway to the rovibrational singlet ground state via a resonantly mixed intermediate state. Photoassociation in a 23Na-40K atomic mixture and one-photon spectroscopy on ~Feshbach molecules reveal about 20 vibrational levels of the electronically excited state. Two of these levels are found to be strongly perturbed by nearby states via spin-orbit coupling, resulting in additional lines of dominant singlet character in the perturbed complex B1 |v=4 c3+ | v=25, or of resonantly mixed character in B1 | v=12 c3+ | v=35 . The dominantly singlet level is used to locate the absolute rovibrational singlet ground state X1+ | v=0, J=0 via Autler-Townes spectroscopy. We demonstrate coherent two-photon coupling via dark state spectroscopy between the predominantly triplet Feshbach molecular state and the singlet ground state. Its binding energy is measured to be 5212.0447(1) , a thousand-fold improvement in accuracy compared to previous determinations. In their absolute singlet ground state, ~molecules are chemically stable under binary collisions and possess a large electric dipole moment of 2.72 Debye. Our work thus paves the way towards the creation of strongly dipolar Fermi gases of NaK molecules.