Hamiltonian quantization of complex Chern-Simons theory at level-k

Abstract

This paper develops a framework for the Hamiltonian quantization of complex Chern-Simons theory with gauge group SL(2,C) at an even level k∈Z+. Our approach follows the procedure of combinatorial quantization to construct the operator algebras of quantum holonomies on 2-surfaces and develop the representation theory. The *-representation of the operator algebra is carried by the infinite dimensional Hilbert space Hλ and closely connects to the infinite-dimensional *-representation of the quantum deformed Lorentz group Uq(sl2) Uq(sl2), where q=[2π ik(1+b2)] and q=[2π ik(1+b-2)] with |b|=1. The quantum group Uq(sl2) Uq(sl2) also emerges from the quantum gauge transformations of the complex Chern-Simons theory. Focusing on a m-holed sphere 0,m, the physical Hilbert space Hphys is identified by imposing the gauge invariance and the flatness constraint. The states in Hphys are the Uq(sl2) Uq(sl2)-invariant linear functionals on a dense domain in Hλ. Finally, we demonstrate that the physical Hilbert space carries a Fenchel-Nielsen representation, where a set of Wilson loop operators associated with a pants decomposition of 0,m are diagonalized.

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