Non-Existence of Linear-Quartic Factorization for the Second Cuboid Quintic

Abstract

Let Qp,q(t)∈Z[t] be Sharipov's even monic degree-10 second cuboid polynomial depending on coprime integers p≠ q>0. Writing Qp,q(t) as a quintic in t2 produces an associated monic quintic polynomial. After the weighted normalization r=p/q and s=r2 we obtain a one-parameter family Ps(x)∈Q[x] such that \[ Qp,q(t)=q20\,Ps\!(t2q4) s=(pq)2. \] We show that for every rational s>0 with s≠ 1 the equation Ps(x)=0 has no rational solutions. Equivalently, Ps admits no 1+4 factorization over Q. The proof uses an explicit quotient by the inversion involution (s,y)(1/s,1/y) and reduces the rational-root problem for Ps to rational points on the fixed genus-2 hyperelliptic curve \[ C: w2=t5+21t4+26t3+10t2+5t+1=(t+1)(t4+20t3+6t2+4t+1). \] Using Magma and Chabauty's method on the Jacobian of C, we compute C(Q) exactly and conclude that the only parameter value producing a rational root is the excluded case s=1 (equivalently p=q). As a consequence, for coprime p≠ q>0 the polynomial Qp,q(t) has no rational roots (hence no linear factor over Q, and in particular no linear factor over Z).