Topological atom optics and beyond with knotted quantum wavefunctions
Abstract
Atom optics demonstrates optical phenomena with coherent matter waves, providing a foundational connection between light and matter. Significant advances in optics have followed the realisation of structured light fields hosting complex singularities and topologically non-trivial characteristics. However, analogous studies are still in their infancy in the field of atom optics. Here, we investigate and experimentally create knotted quantum wavefunctions in spinor Bose--Einstein condensates which display non-trivial topologies. In our work we construct coordinated orbital and spin rotations of the atomic wavefunction, engineering a variety of discrete symmetries in the combined spin and orbital degrees of freedom. The structured wavefunctions that we create map to the surface of a torus to form torus knots, M\"obius strips, and a twice-linked Solomon's knot. In this paper we demonstrate striking connections between the symmetries and underlying topologies of multicomponent atomic systems and of vector optical fields--a realization of topological atom-optics.
Keywords
Cite
@article{arxiv.2312.09619,
title = {Topological atom optics and beyond with knotted quantum wavefunctions},
author = {Maitreyi Jayaseelan and Joseph D. Murphree and Justin T. Schultz and Janne Ruostekoski and Nicholas P. Bigelow},
journal= {arXiv preprint arXiv:2312.09619},
year = {2024}
}
Comments
10 pages, 7 figures, 5 pages Supplementary information