Involutive Yang-Baxter: cabling, decomposability, Dehornoy class

V. Lebed; S. Ramírez; L. Vendramin

Involutive Yang-Baxter: cabling, decomposability, Dehornoy class

V. Lebed, S. Ramírez, L. Vendramin

Abstract

We develop new machinery for producing decomposability tests for involutive solutions to the Yang-Baxter equation. It is based on the seminal decomposability theorem of Rump, and on "cabling" operations on solutions and their effect on the diagonal map. Our machinery yields an elementary proof of a recent decomposability theorem of Camp-More and Sastriques, as well as original decomposability results. It also provides a conceptual interpretation (using the braces language) of the Dehornoy class, a combinatorial invariant naturally appearing in the Garside-theoretic approach to involutive solutions.

Involutive Yang-Baxter: cabling, decomposability, Dehornoy class

Abstract

Paper Structure (6 sections, 12 theorems, 36 equations)

This paper contains 6 sections, 12 theorems, 36 equations.

Introduction
Cabling a solution
Properties of cabled solutions
Applications: (in)decomposability results
Primitivity and further (in)decomposability results
Applications: Dehornoy class

Key Result

Theorem A

Take a solution $(X,r)$ and a positive integer $k$. The map $\iota^{(k)}$ above is injective. Its image is a sub-solution of $G{(X,r)}$.

Theorems & Definitions (22)

Theorem A
Theorem B
Theorem C
Theorem D
Theorem E
Theorem F
Theorem G
proof : Proof of Theorem \ref{['T:cablingProperties']}
Proposition 3.1
proof
...and 12 more

Involutive Yang-Baxter: cabling, decomposability, Dehornoy class

Abstract

Involutive Yang-Baxter: cabling, decomposability, Dehornoy class

Authors

Abstract

Table of Contents

Key Result

Theorems & Definitions (22)