Quartic reductions and elliptic obstructions for perfect Euler bricks

Abstract

We show that the perfect Euler brick (perfect cuboid) problem is equivalent to the following elementary question: do there exist coprime integers a, b, m, n such that the two expressions (2(a2-b2)mn)2 + ((a2+b2)(m2-n2))2 and (4abmn)2 + ((a2+b2)(m2-n2))2 are simultaneously perfect squares? Despite their near-identical structure (differing only in the first summand), no solution has ever been found. We reduce this quartic pair to a one-parameter family of genus-3 hyperelliptic curves CA w2 = λ8 + Aλ4 + 1 and develop obstructions on the distinguished elliptic quotient EA: the Kummer character f is non-trivial on the 4-torsion, and 2-descent arguments exclude several families of square classes. Computationally, we verify that no solution exists for parameters up to 103. These results do not yet exclude perfect Euler bricks unconditionally; the remaining gap and possible approaches (including a genus-5 covering obstruction and connections to Q(2)) are discussed.