The Askey--Wilson algebras, the Lie algebra so3, and their fermionic realizations
Abstract
This paper establishes a comprehensive algebraic framework linking the Lie algebra so3 to the Askey--Wilson algebras. First, we provide a manifestly symmetric reformulation of the algebra homomorphism from the universal Racah algebra to U(sl2) by exploiting a Lie algebra isomorphism between sl2 and so3. This perspective facilitates a natural extension to the quantum setting, where we construct an explicit algebra homomorphism from the universal Askey--Wilson algebra q4 to the nonstandard quantum algebra Uq(so3). By viewing the finite-dimensional irreducible Uq(so3)-modules of classical type as q4-modules, we demonstrate that the decomposition patterns perfectly parallel the branching rules of U(so3) over . Furthermore, we extend this correspondence to the fermionic setting by establishing algebra isomorphisms between the skew group rings over U(so3) and Uq'(so3) and their associated anticommutator spin algebras. Collectively, these results provide a unified correspondence that bridges the gap between integrable algebraic structures, quantum groups, and their fermionic analogues.
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