Jonathan Simon, Harvard
Abstract
Ultracold atoms in optical lattices are a unique testbed for quantum many-body physics. Using these systems it has recently become possible to engineer strongly-correlated materials from the ground up and probe them with single-atom resolution. I will present experiments in which we have synthesized the first magnetic material composed of ultracold atoms, and watched in situ as quantum fluctuations induce a phase transition from a paramagnet to an antiferromagnet. I will then introduce a new algorithmic cooling scheme that we have demonstrated, employing orbital excitations to drive atomic quantum gases to yet-lower temperatures. I will conclude by discussing ways to combine these techniques to address outstanding questions in many-body dynamics, topological physics and beyond.