Root systems and diagram calculus. I. Regular extensions of Carter diagrams and the uniqueness of conjugacy classes

Abstract

In 1972, R. Carter introduced admissible diagrams to classify conjugacy classes in a finite Weyl group W. We say that an admissible diagram is a Carter diagram if any edge α, β with inner product (α, β) > 0 (resp. (α, β) < 0) is drawn as dotted (resp. solid) edge. We construct an explicit transformation of any Carter diagram containing long cycles (with the number of vertices l > 4) into another Carter diagram containing only 4-cycles. Thus, all Carter diagrams containing long cycles can be eliminated from the classification list. There exist diagrams determining two conjugacy classes in W.It is shown that any connected Carter diagram containing a 4-vertex pattern D4 or D4(a1) determines a single conjugacy class. The main approach is studying different extensions of Carter diagrams. Let be the Carter diagram obtained from a certain Carter diagram by adding a single vertex α connected to at n points, n ≤ 3. Let a socket be the set of vertices of connected to α. If the number of sockets available for extensions is equal to 2, then there is a pair of extensions < L and < R, called mirror extensions and the pair elements wL and wR associated with L and R. We show that wR = T-1wLT for some T ∈ W, where the map T is explicitly constructed for all mirror extensions. In Carter's description of the conjugacy classes in a Weyl group a key result (Carter's theorem) states that every element in a Weyl group is a product of two involutions. One of the goals of this paper and its sequels is to prepare the notions and framework in which we give the proof of this fact without appealing to the classification of conjugacy classes.