Topological invariants for Floquet-Bloch systems with chiral, time-reversal, or particle-hole symmetry

We introduce $\mathbb Z_2$-valued bulk invariants for symmetry-protected topological phases in $2+1$ dimensional driven quantum systems. These invariants adapt the $W_3$-invariant, expressed as a sum over degeneracy points of the propagator, to the respective symmetry class of the Floquet-Bloc...

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Veröffentlicht in:	arXiv.org 2018-01
Hauptverfasser:	Höckendorf, Bastian, Alvermann, Andreas, Fehske, Holger
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Sprache:	eng
Schlagworte:	Graphene Invariants Physics - Mesoscale and Nanoscale Physics Symmetry Topology
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description	We introduce $\mathbb Z_2$-valued bulk invariants for symmetry-protected topological phases in $2+1$ dimensional driven quantum systems. These invariants adapt the $W_3$-invariant, expressed as a sum over degeneracy points of the propagator, to the respective symmetry class of the Floquet-Bloch Hamiltonian. The bulk-boundary correspondence that holds for each invariant relates a non-zero value of the bulk invariant to the existence of symmetry-protected topological boundary states. To demonstrate this correspondence we apply our invariants to a chiral Harper, time-reversal Kane-Mele, and particle-hole symmetric graphene model with periodic driving, where they successfully predict the appearance of boundary states that exist despite the trivial topological character of the Floquet bands. Especially for particle-hole symmetry, combination of the $W_3$ and the $\mathbb Z_2$-invariants allows us to distinguish between weak and strong topological phases.
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title	Topological invariants for Floquet-Bloch systems with chiral, time-reversal, or particle-hole symmetry
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