The semiclassical quantization of cyclotron orbits for two-dimensional Bloch electrons in a coupled two band model with a particle-hole symmetric spectrum is considered. As concrete examples, we study graphene (both mono and bilayer) and boron nitride. The main focus is on wave effects - such as Berry phase and Maslov index - occurring at order h in the semiclassical quantization and producing non-trivial shifts in the resulting Landau levels. Specifically, we show that the index shift appearing in the Landau levels is related to a topological part of the Berry phase - which is basically a winding number of the direction of the pseudo-spin 1/2 associated to the coupled bands - acquired by an electron during a cyclotron orbit and not to the complete Berry phase, as commonly stated. As a consequence, the Landau levels of a coupled band insulator are shifted as compared to a usual band insulator. We also study in detail the Berry curvature in the whole Brillouin zone on a specific example (boron nitride) and show that its computation requires care in defining the "k-dependent Hamiltonian" H(k), where k is the Bloch wavevector. © 2010 EDP Sciences, SIF, Springer-Verlag Berlin Heidelberg.
CITATION STYLE
Fuchs, J. N., Piéchon, F., Goerbig, M. O., & Montambaux, G. (2010). Topological Berry phase and semiclassical quantization of cyclotron orbits for two dimensional electrons in coupled band models. European Physical Journal B, 77(3), 351–362. https://doi.org/10.1140/epjb/e2010-00259-2
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