Artificial topological models based on a one-dimensional spin-dependent optical lattice
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Topological matter is a popular topic in both condensed matter and cold-atom research. In the past decades, a variety of models have been identified with fascinating topological features. Some, but not all, of the models can be found in materials. As a fully controllable system, cold atoms trapped in optical lattices provide an ideal platform to simulate and realize these topological models. Here we present a proposal for synthesizing topological models in cold atoms based on a one-dimensional spin-dependent optical lattice potential. In our system, features such as staggered tunneling, staggered Zeeman field, nearest-neighbor interaction, beyond-near-neighbor tunneling, etc. can be readily realized. They underlie the emergence of various topological phases. Our proposal can be realized with current technology and hence has potential applications in quantum simulation of topological matter.
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Zheng, Zhen, Pu, Han, Zou, Xubo, et al.. "Artificial topological models based on a one-dimensional spin-dependent optical lattice." Physical Review A, 95, no. 1 (2017) American Physical Society: http://dx.doi.org/10.1103/PhysRevA.95.013616.