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Pentad and triangular structures behind the Racah matrices

High Energy Physics - Theory 2020-02-05 v1 Mathematical Physics Geometric Topology math.MP Quantum Algebra

Abstract

Somewhat unexpectedly, the study of the family of twisted knots revealed a hidden structure behind exclusive Racah matrices Sˉ\bar S, which control non-associativity of the representation product in a peculiar channel RRˉRRR\otimes \bar R \otimes R \longrightarrow R. These Sˉ\bar S are simultaneously symmetric and orthogonal, and therefore admit two decompositions: as quadratic forms, SˉEtrE\bar S \sim {\cal E}^{tr}{\cal E}, and as operators: TˉSˉTˉ=ST1S1\bar T\bar S\bar T = S T^{-1} S^{-1}. Here Tˉ\bar T and TT consist of the eigenvalues of the quantum R{\cal R}-matrices in channels RRˉR\otimes \bar R and RRR\otimes R respectively, SS is the second exclusive Racah matrix for RˉRRR\bar R\otimes R\otimes R \longrightarrow R (still orthogonal, but no longer symmetric), and E{\cal E} is a {\it triangular} matrix. It can be further used to construct the KNTZ evolution matrix B=ETˉ2E1{\cal B}={\cal E}\bar T^2{\cal E}^{-1}, which is also triangular and explicitly expressible through the skew Schur and Macdonald functions -- what makes Racah matrices calculable. Moreover, B{\cal B} is somewhat similar to Ruijsenaars Hamiltonian, which is used to define Macdonald functions, and gets triangular in the Schur basis. Discovery of this pentad structure (Tˉ,Sˉ,S,E,B)(\bar T,\bar S,S,{\cal E},{\cal B}), associated with the universal R{\cal R}-matrix, can lead to further insights about representation theory, knot invariants and Macdonald-Kerov functions.

Cite

@article{arxiv.1906.09971,
  title  = {Pentad and triangular structures behind the Racah matrices},
  author = {A. Morozov},
  journal= {arXiv preprint arXiv:1906.09971},
  year   = {2020}
}

Comments

8 pages

R2 v1 2026-06-23T10:01:58.660Z