An Observation on Hofstadter’s Butterfly

Abstract

Joseph Avron, Daniel Osadchy, and Ruedi Seiler have nicely highlighted the relevance of topological invariants, or Chern numbers, to the integer quantum Hall effect and to the conductance of a Hofstadter model when the Fermi energy lies in a gap (Physics Today, Physics Today 0031-9228 56 8 2003 38 https://doi.org/10.1063/1.1611351. August 2003, page 38 ).As an addition to their remarks, it is intriguing and suggestive that one can go beyond these facts and construct, for the quantum Hall effect, a mean-field theory that has the unique property of covering both the integer and fractional regimes in a single framework. In such a model, Hofstadter’s butterfly (figure 5 in the article) maps out the essence of what is observed in the lab: the odd-denominator selection rule and hierarchy in the plateau widths and resolution. 1 1. F. Claro, Phys. Rev. B 35, 7980 (1987). https://doi.org/10.1103/PhysRevB.35.7980 The surprising unity of the effect results simply from the unity of the butterfly spectrum, with its self similar features reflecting the hierarchies seen at very low temperatures.As Douglas Hofstadter mentioned in his PhD thesis, his friend David Jennings, on seeing the spectrum, described it as “a picture of God.” 2 2. D. D. Hofstadter, “The Energy Levels of Bloch Electrons in a Magnetic Field,” PhD thesis, U. of Oregon (1975), p. vii. Perhaps that is going too far, but one can certainly see this particular butterfly flying very high.REFERENCESSection:ChooseTop of pageREFERENCES <<CITING ARTICLES1. F. Claro, Phys. Rev. B 35, 7980 (1987). https://doi.org/10.1103/PhysRevB.35.7980 , Google ScholarCrossref, ISI2. D. D. Hofstadter, “The Energy Levels of Bloch Electrons in a Magnetic Field,” PhD thesis, U. of Oregon (1975), p. vii. Google Scholar© 2004 American Institute of Physics.