Adiabatic passage of 205TlF with microwaves in a cryogenic beam

Abstract

We present a hyperfine-resolved state preparation scheme for thallium fluoride (TlF) molecules based on microwave-driven adiabatic passage (AP) in a spatially varying electric field. This method enables efficient and robust population transfer between selected |J,mJ=0 hyperfine sublevels of the X\,1+0 ground state in a cryogenic molecular beam, a key requirement for the CeNTREX search for nuclear time-reversal symmetry violation. Two sequential stages of AP are implemented. The first transfers population from J=0 to J=1 at a local field of 173~V/cm, and the second transfers from J=1 to J=2 at 110~V/cm. Transfer efficiencies are quantified through laser-induced fluorescence, and accounting for residual population in excited rotational levels after a prior stage of rotational cooling. We achieve state transfer efficiencies of 0.92(6) and 1.05(5) for the first and second states of AP, respectively. This corresponds to a total efficiency of 0.97(8) for population transfer from J=0 to J=2. These results demonstrate robust and high-fidelity preparation of specific rotational/hyperfine states in TlF.

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