Clock-line-mediated Sisyphus Cooling

Abstract

We demonstrate sub-recoil Sisyphus cooling using the long-lived 3P0 clock state in alkaline-earth-like ytterbium. A 1388 nm optical standing wave nearly resonant with the 3P0\,→\,3D1 transition creates a spatially periodic light shift of the 3P0 clock state. Following excitation on the ultranarrow clock transition, we observe Sisyphus cooling in this potential, as the light shift is correlated with excitation to 3D1 and subsequent spontaneous decay to the 1S0 ground state. We observe that cooling enhances the loading efficiency of atoms into a 759 nm magic-wavelength one-dimensional (1D) optical lattice, as compared to standard Doppler cooling on the 1S0\,→\,3P1 transition. Sisyphus cooling yields temperatures below 200 nK in the weakly confined, transverse dimensions of the 1D optical lattice. These lower temperatures improve optical lattice clocks by facilitating the use of shallow lattices with reduced light shifts, while retaining large atom numbers to reduce the quantum projection noise. This Sisyphus cooling can be pulsed or continuous and is applicable to a range of quantum metrology applications.