Silvia Hiebel, Benjamin Nagler, Sian Barbosa, Jennifer Koch, Artur Widera: Â
🔓 arXiv:2306.16099 (2023)
The role of disorder on physical systems has been widely studied in the macroscopic and microscopic world. While static disorder is well understood in many cases, the impact of time-dependent disorder on quantum gases is still poorly investigated. In our experimental setup, we produce and characterize time-dependent optical-speckle disorder for ultracold quantum gases with tunable correlation time. Experimentally, coherent light illuminates a combination of a static and a rotating diffuser, thereby collecting a spatially varying phase due to the diffusers' structure and a temporally variable phase due to the relative rotation. The rotation speed of the diffuser determines a characteristic time scale of the dynamics. It can be tuned within a broad range matching typical time scales of the quantum gases investigated. We characterize the dynamic speckle pattern ex-situ by measuring its intensity distribution and in-situ by observing its impact on a molecular Bose-Einstein condensate. As one diffuser rotates relative to the other around the common optical axis, we trace the optical speckle's intensity correlations and the quantum gas' density-density correlations. Our results show comparable outcomes for both measurement methods. The setup allows us to tune the disorder potential adapted to the characteristics of the quantum gas. These studies pave the way for investigating nonequilibrium physics in interacting quantum gases using controlled dynamical-disorder potentials.