Integrability of planar-algebraic models

Abstract

The Quantum Inverse Scattering Method is a scheme for solving integrable models in 1+1 dimensions, building on an R-matrix that satisfies the Yang--Baxter equation and in terms of which one constructs a commuting family of transfer matrices. In the standard formulation, this R-matrix acts on a tensor product of vector spaces. Here, we relax this tensorial property and develop a framework for describing and analysing integrable models based on planar algebras, allowing non-separable R-operators satisfying generalised Yang--Baxter equations. We also re-evaluate the notion of integrals of motion and characterise when an (algebraic) transfer operator is polynomial in a single integral of motion. We refer to such models as polynomially integrable. In an eight-vertex model, we demonstrate that the corresponding transfer operator is polynomial in the natural hamiltonian. In the Temperley--Lieb loop model with loop fugacity β∈C, we likewise find that, for all but finitely many β-values, the transfer operator is polynomial in the usual hamiltonian element of the Temperley--Lieb algebra TLn(β), at least for n≤17. Moreover, we find that this model admits a second canonical hamiltonian, and that this hamiltonian also acts as a polynomial integrability generator for small n and all but finitely many β-values.