Radiative lifetime of the A Π1/22 state in RaF with relevance to laser cooling

M Athanasakis-Kaklamanakis,S G Wilkins,P Lassègues,L Lalanne,J R Reilly,O Ahmad,M Au,S W Bai,J Berbalk,C Bernerd,A Borschevsky,A A Breier,K Chrysalidis,T E Cocolios,R P De Groote,C M Fajardo-Zambrano,K T Flanagan,S Franchoo,R F Garcia Ruiz,D Hanstorp,R Heinke,P Imgram,Á Koszorús,A A Kyuberis,J Lim,Y C Liu,K M Lynch,A Mcglone,W C Mei,G Neyens,L Nies,A V Oleynichenko,A Raggio,S Rothe,L V Skripnikov,E Smets,B Van Den Borne,J Warbinek,J Wessolek,X F Yang

doi:10.1103/physreva.110.l010802

Abstract

The radiative lifetime of the AΠ1/22 (v=0) state in radium monofluoride (RaF) is measured to be 35(1) ns. The lifetime of this state and the related decay rate Γ=2.86(8)×107 s−1 are of relevance to the laser cooling of RaF via the optically closed AΠ1/22←XΣ1/22 transition, which makes the molecule a promising probe to search for new physics. RaF is found to have a comparable photon-scattering rate to homoelectronic laser-coolable molecules. Owing to its highly diagonal Franck-Condon matrix, it is expected to scatter an order of magnitude more photons than other molecules when using just three cooling lasers, before it decays to a dark state. The lifetime measurement in RaF is benchmarked by measuring the lifetime of the 8P3/2 state in Fr to be 83(3) ns, in agreement with literature. Published by the American Physical Society 2024

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