Arithmetic Symmetry in Ideal Prouhet-Tarry-Escott Solutions

Abstract

Motivated in part by anomaly cancellation for integral charge spectra in chiral gauge theory, we study the symmetric locus in the ideal degree-three Prouhet-Tarry-Escott problem. A symmetric integer solution is one whose entries are paired about a common center c∈ 12 Z. This symmetry reduces the problem to a sum-of-two-squares equation, x2+y2=u2+v2, in integer variables, subject to the appropriate parity conditions. Thus the problem is governed by representations as sums of two squares. For the full symmetric locus, let Nsym(H) denote the number of nontrivial symmetric integer solutions of height at most H, counted with unordered multiset conventions and summed over the admissible centers. Then align* Nsym(H) = 4 23π2H3 H+O(H3). align* The logarithmic enhancement comes from the second moment of the sum-of-two-squares representation function. In particular, the symmetric locus is larger than one would expect from the naive H3 degree-weighted box-counting scale alone. This asymptotic identifies a large arithmetically structured subfamily of the ideal degree-three solution space, and suggests that paired anomaly-free integral charge spectra reflect a fundamental number-theoretic structure.