Primeness property for regular gradings

Abstract

Let K be an algebraically closed field of characteristic 0 and G a finite abelian group. For a G-graded K-algebra A, we define the primeness property for graded central polynomials: for any graded polynomials f and g in disjoint sets of variables, if fg is graded central, then both f and g are graded central. Let A=g∈ G Ag be its decomposition into homogeneous components. Assume that for every n-tuple (g1,…,gn) in G, there exist ai∈ Agi with a1·s an≠ 0, and that for each g,h∈ G there exists a scalar β(g,h)∈ K such that agah=β(g,h)ahag. Then the grading is regular, and minimal if no distinct g, h∈ G satisfy β(g,x)=β(h,x) for all x∈ G. We prove that G-graded regular algebras, including Mn(K) with the Pauli grading, fail the primeness property. For matrices of orders 2 and 3, no nontrivial gradings satisfy primeness. Finally, for Z2-graded regular algebras, we use the known fact that minimal regular gradings satisfy the graded identities of the infinite-dimensional Grassmann algebra E and contain a copy of E to show that such algebras satisfy the primeness property in the ordinary sense. As a consequence, we show that minimality is not required for the regularity of the grading.