Dynamical density wave order in an atom-cavity system
Abstract
We theoretically and experimentally explore the emergence of a dynamical density wave order in a driven dissipative atom-cavity system. A Bose-Einstein condensate is placed inside a high finesse optical resonator and pumped sideways by an optical standing wave. The pump strength is chosen to induce a stationary superradiant checkerboard density wave order of the atoms stabilized by a strong intracavity light field. We show theoretically that, when the pump is modulated with sufficient strength at a frequency close to a systemic resonance frequency , a dynamical density wave order emerges, which oscillates at the two frequencies and . This order is associated with a characteristic momentum spectrum, also found in experiments in addition to remnants of the oscillatory dynamics presumably damped by on-site interaction and heating, not included in the calculations. The oscillating density grating, associated with this order, suppresses pump-induced light scattering into the cavity. Similar mechanisms might be conceivable in light-driven electronic matter.
Cite
@article{arxiv.2003.14135,
title = {Dynamical density wave order in an atom-cavity system},
author = {Christoph Georges and Jayson G. Cosme and Hans Keßler and Ludwig Mathey and Andreas Hemmerich},
journal= {arXiv preprint arXiv:2003.14135},
year = {2021}
}
Comments
8 pages, 9 figures