A hypothetical upper bound for the solutions of a Diophantine equation with a finite number of solutions

Abstract

We conjecture that if a system S ⊂eq xi=1, xi+xj=xk, xi · xj=xk: i,j,k ∈ 1,...,n has only finitely many solutions in integers x1,...,xn, then each such solution (x1,...,xn) satisfies |x1|,...,|xn| ≤ 22n-1. By the conjecture, if a Diophantine equation has only finitely many solutions in integers (non-negative integers, rationals), then their heights are bounded from above by a computable function of the degree and the coefficients of the equation. The conjecture implies that the set of Diophantine equations which have infinitely many solutions in integers (non-negative integers) is recursively enumerable. The conjecture stated for an arbitrary computable bound instead of 22n-1 remains in contradiction to Matiyasevich's conjecture that each recursively enumerable set M ⊂eq Nn has a finite-fold Diophantine representation.