Unrestricted Quantum Moduli Algebras. I. The Case of Punctured Spheres

Abstract

Let be a finite type surface, and G a complex algebraic simple Lie group with Lie algebra g. The quantum moduli algebra of (,G) is a quantization of the ring of functions of XG(), the variety of G-characters of π1(), introduced by Alekseev-Grosse-Schomerus and Buffenoir-Roche in the mid '90s. It can be realized as the invariant subalgebra of so-called graph algebras, which are Uq(g)-module-algebras associated to graphs on , where Uq(g) is the quantum group corresponding to G. We study the structure of the quantum moduli algebra in the case where is a sphere with n+1 open disks removed, n≥ 1, using the graph algebra of the "daisy" graph on to make computations easier. We provide new results that hold for arbitrary G and generic q, and develop the theory in the case where q=ε, a primitive root of unity of odd order, and G= SL(2, C). In such a situation we introduce a Frobenius morphism that provides a natural identification of the center of the daisy graph algebra with a finite extension of the coordinate ring O(Gn). We extend the quantum coadjoint action of De-Concini-Kac-Procesi to the daisy graph algebra, and show that the associated Poisson structure on the center corresponds by the Frobenius morphism to the Fock-Rosly Poisson structure on O(Gn). We show that the set of fixed elements of the center under the quantum coadjoint action is a finite extension of C[XG()] endowed with the Atiyah-Bott-Goldman Poisson structure. Finally, by using Wilson loop operators we identify the Kauffman bracket skein algebra Kζ() at ζ:= iε1/2 with this quantum moduli algebra specialized at q=ε.