Non-Existence of Quintic Factorization for the Second Cuboid Polynomial Qp,q(t)

Abstract

We consider the even monic degree-10 second cuboid polynomial Qp,q(t)∈Z[t] depending on coprime integers p≠ q>0. We exclude the existence of a splitting of type 5+5 over Q, i.e., a factorization of Qp,q(t) into two irreducible quintic polynomials. Since Qp,q(t) is even and satisfies Qp,q(0)≠ 0, any such 5+5 splitting is necessarily symmetric, meaning that it can be written in the normal form Qp,q(t)=Rp,q(t)· (-Rp,q(-t)). After a weighted normalization reducing to a one-parameter polynomial Qr(u) with r=p/q∈Q>0, coefficient comparison and elimination via resultants show that a 5+5 splitting forces the existence of a rational point on an explicitly defined plane curve F(r,a)=0. Passing to the quotient parameters a=r y and s=r2 yields an affine curve f(s,y)=0 such that, for each fixed s>0, the polynomial f(s,·) is of degree 16. We compute and factor the discriminant Discy(f) and then use Sturm root counts to certify that f(s,·) has no real roots for every rational s>0 with s≠ 1. Hence f(s,y)=0 admits no rational solutions with s>0, s≠ 1, and consequently no quintic 5+5 factorization occurs for Qp,q(t) when p≠ q.