Physics – Condensed Matter – Mesoscale and Nanoscale Physics
Scientific paper
1999-09-10
Nucl.Phys. B562 (1999) 445-476
Physics
Condensed Matter
Mesoscale and Nanoscale Physics
33 pages, 5 eps-figures; Nucl. Physics B, to appear
Scientific paper
10.1016/S0550-3213(99)00543-X
The random flux model (defined here as a model of lattice fermions hopping under the influence of maximally random link disorder) is analysed field theoretically. It is shown that the long range physics of the model is described by the supersymmetric version of a field theory that has been derived earlier in connection with lattice fermions subject to weak random hopping. More precisely, the field theory relevant for the behaviour of n-point correlation functions is of non-linear sigma model type, where the group GL(n|n) is the global invariant manifold. It is argued that the model universally describes the long range physics of random phase fermions and provides further evidence in favour of the existence of delocalised states in the middle of the band in two dimensions. The same formalism is applied to the study of non-Abelian generalisations of the random flux model, i.e. N-component fermions whose hopping is mediated by random U(N) matrices. We discuss some physical applications of these models and argue that, for sufficiently large N, the existence of long range correlations in the band center (equivalent to metallic behaviour in the Abelian case) can be safely deduced from the RG analysis of the model.
Altland Alexander
Simons Benjamin D.
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