# The structure monoid and algebra of a non-degenerate set-theoretic   solution of the Yang-Baxter equation

**Authors:** Eric Jespers, {\L}ukasz Kubat, Arne Van Antwerpen

arXiv: 1812.02026 · 2019-11-20

## TL;DR

This paper extends the understanding of the algebraic structure of the monoid and algebra associated with non-degenerate set-theoretic solutions of the Yang-Baxter equation, revealing their properties, radicals, and representations.

## Contribution

It generalizes known results from involutive solutions to arbitrary non-degenerate solutions, providing new insights into their algebraic and ring-theoretic structure.

## Key findings

- K[M(X,r)] is a Noetherian PI-algebra with finite Gelfand--Kirillov dimension
- Characterization of involutive solutions via ring-theoretic properties
- Embedding of K[M(X,r)] into matrix products over abelian-by-finite groups

## Abstract

For a finite involutive non-degenerate solution $(X,r)$ of the Yang--Baxter equation it is known that the structure monoid $M(X,r)$ is a monoid of I-type, and the structure algebra $K[M(X,r)]$ over a field $K$ share many properties with commutative polynomial algebras, in particular, it is a Noetherian PI-domain that has finite Gelfand--Kirillov dimension. In this paper we deal with arbitrary finite (left) non-degenerate solutions. Although the structure of both the monoid $M(X,r)$ and the algebra $K[M(X,r)]$ is much more complicated than in the involutive case, we provide some deep insights.   In this general context, using a realization of Lebed and Vendramin of $M(X,r)$ as a regular submonoid in the semidirect product $A(X,r)\rtimes\mathrm{Sym}(X)$, where $A(X,r)$ is the structure monoid of the rack solution associated to $(X,r)$, we prove that $K[M(X,r)]$ is a module finite normal extension of a commutative affine subalgebra. In particular, $K[M(X,r)]$ is a Noetherian PI-algebra of finite Gelfand--Kirillov dimension bounded by $|X|$. We also characterize, in ring-theoretical terms of $K[M(X,r)]$, when $(X,r)$ is an involutive solution. This characterization provides, in particular, a positive answer to the Gateva-Ivanova conjecture concerning cancellativity of $M(X,r)$.   These results allow us to control the prime spectrum of the algebra $K[M(X,r)]$ and to describe the Jacobson radical and prime radical of $K[M(X,r)]$. Finally, we give a matrix-type representation of the algebra $K[M(X,r)]/P$ for each prime ideal $P$ of $K[M(X,r)]$. As a consequence, we show that if $K[M(X,r)]$ is semiprime then there exist finitely many finitely generated abelian-by-finite groups, $G_1,\dotsc,G_m$, each being the group of quotients of a cancellative subsemigroup of $M(X,r)$ such that the algebra $K[M(X,r)]$ embeds into $\mathrm{M}_{v_1}(K[G_1])\times\dotsb\times \mathrm{M}_{v_m}(K[G_m])$.

## Full text

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## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1812.02026/full.md

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Source: https://tomesphere.com/paper/1812.02026