Structure theory for the group algebra of the symmetric group, with applications to polynomial identities for the octonions

Abstract

In part 1, we review the structure theory of F Sn, the group algebra of the symmetric group Sn over a field of characteristic 0. We define the images (Eλij) of the matrix units Eλij (1 i, j dλ), where dλ is the number of standard tableaux of shape λ, and obtain an explicit construction of Young's isomorphism λ Mdλ(F) F Sn. We then present Clifton's algorithm for the construction of the representation matrices Rλ(p) ∈ Mdλ(F) for all p ∈ Sn, and obtain the reverse isomorphism φ F Sn λ Mdλ(F). In part 2, we apply the structure theory of F Sn to the study of multilinear polynomial identities of degree n 7 for the algebra O of octonions over a field of characteristic 0. We compare our results with earlier work of Racine, Hentzel & Peresi, and Shestakov & Zhukavets on the identities of degree n 6. We use computational linear algebra to verify that every identity in degree 7 is a consequence of the known identities of lower degrees: there are no new identities in degree 7. We conjecture that the known identities of degree 6 generate all octonion identities in characteristic 0.