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Band inversion at critical magnetic fields in a silicene quantum dot

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 Added by Manuel Calixto
 Publication date 2017
  fields Physics
and research's language is English




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We have found out that the band inversion in a silicene quantum dot (QD), in perpendicular magnetic $B$ and electric $Delta_z$ fields, drastically depends on the strength of the magnetic field. We study the energy spectrum of the silicene QD where the electric field provides a tunable band gap $Delta$. Boundary conditions introduce chirality, so that negative and positive angular momentum $m$ zero Landau level (ZLL) edge states show a quite different behavior regarding the band-inversion mechanism underlying the topological insulator transition. We show that, whereas some ZLLs suffer band inversion at $Delta=0$ for any $B>0$, other ZLLs only suffer band inversion above critical values of the magnetic field at nonzero values of the gap.



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