J. Kondev, J. B. Marston
Published 1996-12-24, updated 1997-02-28Version 2
We study the localization transition in the integer quantum Hall effect as described by the network model of quantum percolation. Starting from a path integral representation of transport Green's functions for the network model, which employs both complex (bosonic) and Grassman (fermionic) fields, we map the problem of localization to the problem of diagonalizing a one-dimensional non-Hermitian Hamiltonian of interacting bosons and fermions. An exact solution is obtained in a restricted subspace of the Hilbert space which preserves boson-fermion supersymmetry. The physically relevant regime is investigated using the density matrix renormalization group (DMRG) method, and critical behavior is found at the plateau transition.
Comments: 14 RevTex pages, 3 eps figures; This revised version contains an extended disussion of supersymmetry and improved numerical results
Phase Diagram for the Hofstadter butterfly and integer quantum Hall effect in three dimensions
Microscopic Details of the Integer Quantum Hall Effect in an Anti-Hall Bar
Semiclassical analysis of edge state energies in the integer quantum Hall effect
