A combinatorial approach to the set-theoretic solutions of the Yang-Baxter equation
Abstract
A bijective map r: X2 X2, where X = \x1, ..., xn \ is a finite set, is called a set-theoretic solution of the Yang-Baxter equation (YBE) if the braid relation r12r23r12 = r23r12r23 holds in X3. A non-degenerate involutive solution (X,r) satisfying r(xx)=xx, for all x ∈ X, is called square-free solution. There exist close relations between the square-free set-theoretic solutions of YBE, the semigroups of I-type, the semigroups of skew polynomial type, and the Bieberbach groups, as it was first shown in a joint paper with Michel Van den Bergh. In this paper we continue the study of square-free solutions (X,r) and the associated Yang-Baxter algebraic structures -- the semigroup S(X,r), the group G(X,r) and the k- algebra A(k, X,r) over a field k, generated by X and with quadratic defining relations naturally arising and uniquely determined by r. We study the properties of the associated Yang-Baxter structures and prove a conjecture of the present author that the three notions: a square-free solution of (set-theoretic) YBE, a semigroup of I type, and a semigroup of skew-polynomial type, are equivalent. This implies that the Yang-Baxter algebra A(k, X,r) is Poincar\'e-Birkhoff-Witt type algebra, with respect to some appropriate ordering of X. We conjecture that every square-free solution of YBE is retractable, in the sense of Etingof-Schedler.
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