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A magnetic Hofstadter butterfly and its topologically quantized Hall conductance

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 Added by Sankalpa Ghosh
 Publication date 2018
  fields Physics
and research's language is English




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The energy spectrum of massless Dirac fermions in graphene under two dimensional periodic magnetic modulation having square lattice symmetry is calculated. We show that the translation symmetry of the problem is similar to that of the Hofstadter or TKNN problem and in the weak field limit the tight binding energy eigenvalue equation is indeed given by Harper Hofstadter hamiltonian. We show that due to its magnetic translational symmetry the Hall conductivity can be identified as a topological invariant and hence quantized. We thus extend the idea of Quantum Hall Effect to magnetically modulated two dimensional electron system. Finally we indicate possible experimental systems where this may be verified.



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We develop a generic $mathbf{k}cdot mathbf{p}$ open momentum space method for calculating the Hofstadter butterfly of both continuum (Moire) models and tight-binding models, where the quasimomentum is directly substituted by the Landau level (LL) operators. By taking a LL cutoff (and a reciprocal lattice cutoff for continuum models), one obtains the Hofstadter butterfly with in-gap spectral flows. For continuum models such as the Moire model for twisted bilayer graphene, our method gives a sparse Hamiltonian, making it much more efficient than existing methods. The spectral flows in the Hofstadter gaps can be understood as edge states on a momentum space boundary, from which one can determine the two integers ($t_ u,s_ u$) of a gap $ u$ satisfying the Diophantine equation. The spectral flows can also be removed to obtain a clear Hofstadter butterfly. While $t_ u$ is known as the Chern number, our theory identifies $s_ u$ as a dual Chern number for the momentum space, which corresponds to a quantized Lorentz susceptibility $gamma_{xy}=eBs_ u$.
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