Optical conductivity of a quantum gas

We measure the conductivity of neutral fermions in a cubic optical lattice. A uniform force is applied at a single frequency by periodic displacement of the trapping potential, and the current response is observed though the global displacement of atoms. In the linear response regime, the steady-state ratio between current and force gives the ac conductivity. The tensor properties of the conductivity reveal temporal and spatial symmetries of the sample. Similarly to "optical" conductivity commonly measured in materials with optical reflectivity, exact sum rules relate dynamical measurements to thermodynamic properties. We explore the effect of lattice depth, temperature, interaction strength, and atom number on conductivity. Using a relaxation-time approximation, we extract the transport time of current. Our work enables a direct comparison between cold-atom experiments and conductivity studies of materials.