Entanglement Properties of Localized States in 1D Topological Quantum Walks
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The symmetries associated with discrete-time quantum walks (DTQWs) and the flexibilities in controlling their dynamical parameters allow to create a large number of topological phases. An interface in position space, which separates two regions with different topological numbers, can, for example, be effectively modelled using different coin parameters for the walk on either side of the interface. Depending on the neighbouring numbers, this can lead to localized states in one-dimensional configurations and here we carry out a detailed study into the strength of such localized states. We show that it can be related to the amount of entanglement created by the walks, with minima appearing for strong localizations. This feature also persists in the presence of small amounts of $\sigma_x$ (bit flip) noise.
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Quantum walks reveal topological flat bands, robust edge states and topological phase transitions in cyclic graphs
Step-dependent quantum walks on odd and even cyclic graphs produce gapped and gapless topological phases, rotationally symmetric flat bands in 4n-site graphs, and robust edge states at phase interfaces.
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