Solving and classifying the solutions of the Yang-Baxter equation through a differential approach. Two-state systems

TL;DR

This paper introduces a differential method to systematically solve and classify regular solutions of the Yang-Baxter equation for two-state systems, including the eight-vertex model, by transforming it into polynomial systems and analyzing solution branches.

Contribution

It presents a novel differential approach that simplifies solving the Yang-Baxter equation and enables complete classification of its regular solutions for two-state models.

Findings

Successfully solved the Yang-Baxter equation for two-state systems.

Provided a systematic classification of regular solutions.

Demonstrated the method's effectiveness up to the eight-vertex model.

Abstract

The formal derivatives of the Yang-Baxter equation with respect to its spectral parameters, evaluated at some fixed point of these parameters, provide us with two systems of differential equations. The derivatives of the $R$ matrix elements, however, can be regarded as independent variables and eliminated from the systems, after which two systems of polynomial equations are obtained in place. In general, these polynomial systems have a non-zero Hilbert dimension, which means that not all elements of the $R$ matrix can be fixed through them. Nonetheless, the remaining unknowns can be found by solving a few number of simple differential equations that arise as consistency conditions of the method. The branches of the solutions can also be easily analyzed by this method, which ensures the uniqueness and generality of the solutions. In this work we considered the Yang-Baxter equation for two-state systems, up to the eight-vertex model. This differential approach allowed us to solve the Yang-Baxter equation in a systematic way and also to completely classify its regular solutions.