English

Modular Invariants from Subfactors: Type I Coupling Matrices and Intermediate Subfactors

Operator Algebras 2009-10-31 v2 High Energy Physics - Theory Mathematical Physics math.MP Quantum Algebra

Abstract

A braided subfactor determines a coupling matrix Z which commutes with the S- and T-matrices arising from the braiding. Such a coupling matrix is not necessarily of "type I", i.e. in general it does not have a block-diagonal structure which can be reinterpreted as the diagonal coupling matrix with respect to a suitable extension. We show that there are always two intermediate subfactors which correspond to left and right maximal extensions and which determine "parent" coupling matrices Z^\pm of type I. Moreover it is shown that if the intermediate subfactors coincide, so that Z^+=Z^-, then Z is related to Z^+ by an automorphism of the extended fusion rules. The intertwining relations of chiral branching coefficients between original and extended S- and T-matrices are also clarified. None of our results depends on non-degeneracy of the braiding, i.e. the S- and T-matrices need not be modular. Examples from SO(n) current algebra models illustrate that the parents can be different, Z^+\neq Z^-, and that Z need not be related to a type I invariant by such an automorphism.

Keywords

Cite

@article{arxiv.math/9911239,
  title  = {Modular Invariants from Subfactors: Type I Coupling Matrices and Intermediate Subfactors},
  author = {J. Böckenhauer and D. E. Evans},
  journal= {arXiv preprint arXiv:math/9911239},
  year   = {2009}
}

Comments

25 pages, latex, a new Lemma 6.2 added to complete an argument in the proof of the following lemma, minor changes otherwise