Root systems and diagram calculus. III. Semi-Coxeter orbits of linkage diagrams and the Carter theorem

Abstract

A diagram obtained from the Carter diagram by adding one root together with its bonds such that the resulting subset of roots is linearly independent is said to be the linkage diagram. Given a linkage diagram, we associate the linkage labels vector, which is introduced like the vector of Dynkin labels. Similarly to the dual Weyl group, we introduce the group WL associated with , and we call it the dual partial Weyl group. The linkage labels vectors connected under the action of WL constitute the linkage system L(), which is similar to the weight system arising in the representation theory of the semisimple Lie algebras. The Carter theorem states that every element of a Weyl group W is expressible as the product of two involutions. We give the proof of this theorem based on the description of the linkage system L() and semi-Coxeter orbits of linkage labels vectors for any Carter diagram . The main idea of the proof is based on the fact that, with a few exceptions, in each semi-Coxeter orbit there is a special linkage diagram -- called unicolored, for which the decomposition into the product of two involutions is trivial.