We present an all-optical method for achieving molecular Bose-Einstein condensates of ${}^6\mathrm{Li}$. We demonstrate this with mixtures in the lowest two (1-2), and second lowest two (2-3) hyperfine states. For the 1-2 mixture, we can achieve condensate fractions of 36%, with $9\times {10}^4$ atoms at $0.05\mu \mathrm{K}$ temperature. For the 2-3 mixture, we have 28% condensed with $3.2\times {10}^4$ atoms at $0.05\mu \mathrm{K}$ temperature. We use mostly standard methods, but make a number of refinements in the magnetic bias coils compared with earlier work. Our method imposes minimal constraints on subsequent experiments by allowing plenty of optical access while requiring only one high-vacuum chamber. We use an optical system designed around minimizing the number of active elements, and we can accomplish slowing and sub-Doppler cooling with a single tapered amplifier.

• Received 20 August 2018

DOI:https://doi.org/10.1103/PhysRevA.98.043626