English

Multi-frequency optical lattice for dynamic lattice-geometry control

Quantum Gases 2022-11-10 v1 Quantum Physics

Abstract

Ultracold atoms in optical lattices are pristine model systems with a tunability and flexibility that goes beyond solid-state analogies, e.g., dynamical lattice-geometry changes allow tuning a graphene lattice into a boron-nitride lattice. However, a fast modulation of the lattice geometry remains intrinsically difficult. Here we introduce a multi-frequency lattice for fast and flexible lattice-geometry control and demonstrate it for a three-beam lattice, realizing the full dynamical tunability between honeycomb lattice, boron-nitride lattice and triangular lattice. At the same time, the scheme ensures intrinsically high stability of the lattice geometry. We introduce the concept of a geometry phase as the parameter that fully controls the geometry and observe its signature as a staggered flux in a momentum space lattice. Tuning the geometry phase allows to dynamically control the sublattice offset in the boron-nitride lattice. We use a fast sweep of the offset to transfer atoms into higher Bloch bands, and perform a new type of Bloch band spectroscopy by modulating the sublattice offset. Finally, we generalize the geometry phase concept and the multi-frequency lattice to three-dimensional optical lattices and quasi-periodic potentials. This scheme will allow further applications such as novel Floquet and quench protocols to create and probe, e.g., topological properties.

Keywords

Cite

@article{arxiv.2207.03811,
  title  = {Multi-frequency optical lattice for dynamic lattice-geometry control},
  author = {Marcel N. Kosch and Luca Asteria and Henrik P. Zahn and Klaus Sengstock and Christof Weitenberg},
  journal= {arXiv preprint arXiv:2207.03811},
  year   = {2022}
}

Comments

18 pages, 13 figures

R2 v1 2026-06-25T00:45:03.883Z