Weyl group orbits on Kac--Moody root systems

Abstract

Let D be a Dynkin diagram and let =\α1,… ,α\ be the simple roots of the corresponding Kac--Moody root system. Let h denote the Cartan subalgebra, let W denote the Weyl group and let denote the set of all roots. The action of W on h, and hence on , is the discretization of the action of the Kac--Moody algebra. Understanding the orbit structure of W on is crucial for many physical applications. We show that for i≠ j, the simple roots αi and αj are in the same W--orbit if and only if vertices i and j in the Dynkin diagram corresponding to αi and αj are connected by a path consisting only of single edges. We introduce the notion of `the Cayley graph P of the Weyl group action on real roots' whose connected components are in one-to-one correspondence with the disjoint orbits of W. For a symmetric hyperbolic generalized Cartan matrix A of rank ≥ 4 we prove that any 2 real roots of the same length lie in the same W--orbit. We show that if the generalized Cartan matrix A contains zeros, then there are simple roots that are stabilized by simple root reflections in W, that is, W does not act simply transitively on real roots. We give sufficient conditions in terms of the generalized Cartan matrix A (equivalently D) for W to stabilize a real root. Using symmetry properties of the imaginary light cone in the hyperbolic case, we deduce that the number of W--orbits on imaginary roots on a hyperboloid of fixed radius is bounded above by the number of root lattice points on the hyperboloid that intersect the closure of the fundamental region for W.