Spectroscopy of the X2+(v=2) → A21/2(v=1) Transition in MgF: Hyperfine Structures and Spectroscopic Constants
Abstract
We report spectroscopic results of the \(X2+(v=2) → A21/2(v=1)\) transition in magnesium monofluoride (MgF). Using Doppler-free Laser-Induced Fluorescence (LIF) spectroscopy on the \(X2+(v=2) → A21/2(v=1)\) transition, we resolved 47 hyperfine components distributed over 11 transition lines in X and A states. An effective Hamiltonian -- comprising contributions from vibrational, rotational, \(\)-doubling, and hyperfine interactions -- was presented to model the energy structure of the \(A21/2(v=1)\) state. The spectroscopic parameters, including the rotational constant, the \(\)-doubling parameter, and the hyperfine interaction constants, were extracted using a least-square fitting and Markov Chain Monte Carlo (MCMC) procedure. Our study reveals that the spectroscopic constants show subtle changes compared to the \(A21/2(v=0)\) state. These results provide critical spectroscopic benchmarks for optimizing optical cycling schemes in MgF, thereby advancing optical cycling efficiency in the magneto-optical trapping of MgF.
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