Commutative algebras satisfying univariate identities with vanishing Peirce polynomial

Abstract

We introduce and study (2,3)-palintropic algebras, a class of commutative algebras defined by the identity (x3)2 - (x2)3 = 0. This specific relation is the simplest generator of the 2-dimensional space of minimal-degree evanescent identities in degree 6, and encompasses several well-studied structures, including Jordan and medial algebras. The primary motivation for investigating these algebras lies in their trivial Peirce polynomials, which removes a priori restrictions on the spectrum of the multiplication operator associated with an idempotent. In this paper, we review and further develop the theory of Peirce operators, Peirce polynomials, and second-order linearizations. We demonstrate that despite the triviality of the Peirce polynomial, any idempotent c admits well-behaved, explicit fusion rules for multiplication between its λ-Peirce spaces for λ≠ 12. Furthermore, we prove that multiplication by such an idempotent always constitutes an algebra homomorphism. Finally, we present concrete examples of (2,3)-palintropic algebras and provide applications of these algebraic structures to commutative polynomial maps.