Artificial Gauge Fields with Ultracold Atoms in Optical Lattices

March 30, 2019|
Artificial Gauge Fields with Ultracold Atoms in Optical Lattices by Monika Aidelsburger
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This work reports on the generation of artificial magnetic fields with ultracold atoms in optical lattices using laser-assisted tunneling, as well as on the first Chern-number measurement in a non-electronic system.

It starts with an introduction to the Hofstadter model, which describes the dynamics of charged particles on a square lattice subjected to strong magnetic fields. This model exhibits energy bands with non-zero topological invariants called Chern numbers, a property that is at the origin of the quantum Hall effect. The main part of the work discusses the realization of analog systems with ultracold neutral atoms using laser-assisted-tunneling techniques both from a theoretical and experimental point of view. Staggered, homogeneous and spin-dependent flux distributions are generated and characterized using two-dimensional optical super-lattice potentials. Additionally their topological properties are studied via the observation of bulk topological currents.

The experimental techniques presented here offer a unique setting for studying topologically non-trivial systems with ultracold atoms.
Title:Artificial Gauge Fields with Ultracold Atoms in Optical Lattices
Format:Paperback
Product dimensions:172 pages, 9.25 X 6.1 X 0 in
Shipping dimensions:172 pages, 9.25 X 6.1 X 0 in
Published:March 30, 2019
Publisher:Springer Nature
Language:English
Appropriate for ages:All ages
ISBN - 13:9783319798486

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