Quantum geometric Wigner construction for D(G) and braided racks
Abstract
The quantum double D(G)= C(G) C G of a finite group plays an important role in the Kitaev model for quantum computing, as well as in associated TQFT's, as a kind of Poincar\'e group. We interpret the known construction of its irreps, which are quasiparticles for the model, in a geometric manner strictly analogous to the Wigner construction for the usual Poincar\'e group of R1,3. Irreps are labelled by pairs (C, π), where C is a conjugacy class in the role of a mass-shell, and π is a representation of the isotropy group CG in the role of spin. The geometric picture entails D(G) C(CG)\!\!\!\!< C G as a quantum homogeneous bundle where the base is G/CG, and D(G) C(G) as another homogeneous bundle where the base is the group algebra C G as noncommutative spacetime. Analysis of the latter leads to a duality whereby the differential calculus and solutions of the wave equation on C G are governed by irreps and conjugacy classes of G respectively, while the same picture on C(G) is governed by the reversed data. Quasiparticles as irreps of D(G) also turn out to classify irreducible bicovariant differential structures 1C, π on D(G) and these in turn correspond to braided-Lie algebras LC, π in the braided category of G-crossed modules, which we call `braided racks' and study. We show under mild assumptions that U(LC,π) quotients to a braided Hopf algebra BC,π related by transmutation to a coquasitriangular Hopf algebra HC,π.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.