Perturbation-assisted Observation of the Lowest Vibrational Level of the b30 State of Ultracold LiK Molecules
Abstract
The narrow transition from the lowest rovibrational level of the X1+ electronic ground state to the lowest vibrational level of the b30 potential provides opportunities for achieving magic-wavelength trapping of ultracold bialkali molecules for enhancing their rotational coherence times. Guided by existing spectroscopic data of several perturbed and deeply-bound rovibrational states of the A1+ potential [Grochola et al., Chem. Phys. Lett., 2012, 535, 17-20], we conducted a targeted spectroscopic search and report the first observation of the lowest vibrational level of the b30 state in 6Li40K. The transition frequency from |X1+,\,v=0,\,J=0> to |b30,\,v'=0,\,J'=1> is determined to be 314,230.5(5)GHz. Assisted by microwave spectroscopy, we resolved the rotational structure of |b30,\,v'=0> and extracted a rotational constant of h×8.576(44) GHz for the b30 state. From this, we deducted an energy separation between |b30,v'=0,J'=0> and |X1+,v=0,J=0> of hc×10,481.03(2) cm-1. Our work provides timely and precise information on the deeply-bound region of the b30 triplet excited potential of LiK, and benefits future applications of ultracold LiK isotopologues in quantum simulation and quantum computation that demand long coherence times.
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