Anomalous Behavior of Dark States in Quantum Gases of 6Li

Abstract

We create atom-molecule dark states in a degenerate Fermi gas of 6Li in both weakly and strongly interacting regimes using two-photon Raman scattering to couple fermion pairs to bound molecular states in the ground singlet and triplet potential. Near the unitarity point in the BEC-BCS crossover regime, the atom number revival height associated with the dark state abruptly and unexpectedly decreases and remains low for magnetic fields below the Feshbach resonance center at 832.2~G. With a weakly interacting Fermi gas at 0~G we perform precision dark-state spectroscopy of the least-bound vibrational levels of the lowest singlet and triplet potentials. From these spectra, we obtain binding energies of the v''=9, N''=0 level of the a(13u+) potential and the v''=38, N''=0 level of the X(11g+) potential with absolute uncertainty as low as 20 kHz. For the triplet potential we resolve the molecular hyperfine structure.