English

Tensor Models, Kronecker coefficients and Permutation Centralizer Algebras

High Energy Physics - Theory 2020-04-27 v2 Mathematical Physics Combinatorics math.MP

Abstract

We show that the counting of observables and correlators for a 3-index tensor model are organized by the structure of a family of permutation centralizer algebras. These algebras are shown to be semi-simple and their Wedderburn-Artin decompositions into matrix blocks are given in terms of Clebsch-Gordan coefficients of symmetric groups. The matrix basis for the algebras also gives an orthogonal basis for the tensor observables which diagonalizes the Gaussian two-point functions. The centres of the algebras are associated with correlators which are expressible in terms of Kronecker coefficients (Clebsch-Gordan multiplicities of symmetric groups). The color-exchange symmetry present in the Gaussian model, as well as a large class of interacting models, is used to refine the description of the permutation centralizer algebras. This discussion is extended to a general number of colors dd: it is used to prove the integrality of an infinite family of number sequences related to color-symmetrizations of colored graphs, and expressible in terms of symmetric group representation theory data. Generalizing a connection between matrix models and Belyi maps, correlators in Gaussian tensor models are interpreted in terms of covers of singular 2-complexes. There is an intriguing difference, between matrix and higher rank tensor models, in the computational complexity of superficially comparable correlators of observables parametrized by Young diagrams.

Keywords

Cite

@article{arxiv.1708.03524,
  title  = {Tensor Models, Kronecker coefficients and Permutation Centralizer Algebras},
  author = {Joseph Ben Geloun and Sanjaye Ramgoolam},
  journal= {arXiv preprint arXiv:1708.03524},
  year   = {2020}
}

Comments

81 pages; 5 figures; 5 tables; references updated and added

R2 v1 2026-06-22T21:12:29.958Z