n-Valued Groups, Kronecker Sums, and Wendt's Matrices

Abstract

The article presents results on the well-known problem concerning the structure of integer polynomials pn(z; x, y), which define multiplication laws in n-valued groups Gn over the field of complex numbers C. We show that the n-valued multiplication in the group Gn is realized in terms of the eigenvalues of the Kronecker sum of companion Frobenius matrices for polynomials of the form tn - x in the variable t. The notion of a Wendt (x, y, z)-matrix is introduced. When x = (-1)n, y = z = 1, one recovers the classical Wendt matrix, whose determinant is used in number theory in connection with Fermat's Last Theorem. It is shown that for each positive integer n, the polynomial pn is given by the determinant of a Wendt (x, y, z)-matrix. Iterations of the n-valued multiplication in the group Gn lead to polynomials pn(z; x1, …, xm). We prove the irreducibility of the polynomial pn(z; x1, …, xm) over various fields. For each n, we introduce the notion of classes of symmetric n-algebraic n-valued groups. The group Gn belongs to one of these classes. For n = 2, 3, a description of the universal objects of these classes is obtained.