Establishing a nonzero measurement of the electron Electric Dipole Moment (eEDM) has long been a fundamental pursuit in atomic, molecular and optical physics, offering possible insights into new physics beyond the Standard Model. In this regard, lead monofluoride (PbF) has emerged as a potential candidate for measuring eEDM primarily due to its suitable properties such as the strong internal effective electric field, and eEDM-sensitive ground state with large Ω-doubling and small magnetic g factor. In the present work, we realized the production of a buffer-gas-cooled PbF molecular beam and characterized its high-resolution spectroscopy in the BΣ(υ'=0) ← XΠ(υ = 0) transition, including both direct absorption and laser-induced fluorescence spectroscopy. A highly concentrated beam of PbF molecules is obtained with a central forward velocity of 223 ± 17 m/s, while 81, 66 and 24 hyperfine-structure-resolved spectral lines with a frequency accuracy of 40 MHz have been assigned respectively for PbF, PbF and PbF isotopologues. The hyperfine constants due to the F nucleus (A and A) of the B state are reported for the first time, and those of the Pb nucleus have been also updated. Such a cryogenic molecular beam of PbF in association with its hyperfine-structure-resolved spectral atlas of the BΣ(υ'=0) ← XΠ(υ = 0) transition will be essential in developing sensitive detection schemes towards the eEDM measurement.
Download full-text PDF |
Source |
---|---|
http://dx.doi.org/10.1016/j.saa.2024.125508 | DOI Listing |
Enter search terms and have AI summaries delivered each week - change queries or unsubscribe any time!