Abstract
We investigate the Hall conductivity in a Sierpinski carpet, a fractal of Hausdorff dimension ´ df = ln(8)/ ln(3) ≈ 1.893, subject to a perpendicular magnetic field. We compute the Hall conductivity using linear response and the recursive Green function method. Our main finding is that edge modes, corresponding to
a maximum Hall conductivity of at least σxy = ±e2 h , seem to be generically present for arbitrary finite field strength, no matter how one approaches the thermodynamic limit of the fractal. We discuss a simple counting rule to determine the maximal number of edge modes in terms of paths through the system with a fixed width. This quantized edge conductance, as in the case of the conventional Hofstadter problem, is stable with respect to disorder and thus a robust feature of the system.
a maximum Hall conductivity of at least σxy = ±e2 h , seem to be generically present for arbitrary finite field strength, no matter how one approaches the thermodynamic limit of the fractal. We discuss a simple counting rule to determine the maximal number of edge modes in terms of paths through the system with a fixed width. This quantized edge conductance, as in the case of the conventional Hofstadter problem, is stable with respect to disorder and thus a robust feature of the system.
Original language | English |
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Article number | 013044 |
Number of pages | 5 |
Journal | Physical Review Research |
Volume | 2 |
DOIs | |
Publication status | Published - 13 Jan 2020 |
Keywords
- Chern insulators
- Integer quantum Hall effect
- Quantum Hall effect
- Topological Hall effect
- Topological insulators
- Fractals
- Fractal dimension characterization
- Green's function methods
- Linear response theory