QHI Theory, I: 3-Manifolds Scissors Congruence Classes and Quantum Hyperbolic Invariants

Abstract

For any triple (W,L,), where W is a closed connected and oriented 3-manifold, L is a link in W and is a flat principal B-bundle over W (B is the Borel subgroup of SL(2,)), one constructs a -scissors congruence class (W,L,) which belongs to a (pre)-Bloch group (). The class (W,L,) may be represented by -triangulations =(T,H,) of (W,L,). For any and any odd integer N>1, one defines a ``quantization'' N of based on the representation theory of the quantum Borel subalgebra N of Uq(sl(2,)) specialized at the root of unity ωN = (2π i/N). Then one defines an invariant state sum KN(W,L,):= K(N) called a quantum hyperbolic invariant (QHI) of (W,L,). One introduces the class of hyperbolic-like triples. They carry also a classical scissors congruence class (W,L,), that belongs to the classical (pre)-Bloch group () and may be represented by explicit idealizations of some -triangulations of a special type. One shows that (W,L,) lies in the kernel of a generalized Dehn homomorphism defined on (), and that it induces an element of H3δ(PSL(2,);) (discrete homology). One proves that N ∞ (2iπ/N2) [KN(W,L,)] = G(W,L,) essentially depends of the geometry of the ideal triangulations representing (W,L,), and one motivates the strong reformulation of the Volume Conjecture, which would identify G(W,L,) with the evaluation R((W,L,)) of a certain refinement of the classical Rogers dilogarithm on the -scissors class.

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