Application of a polynomial sieve: beyond separation of variables

Abstract

Let a polynomial f ∈ Z[X1,…,Xn] be given. The square sieve can provide an upper bound for the number of integral x ∈ [-B,B]n such that f(x) is a perfect square. Recently this has been generalized substantially: first to a power sieve, counting x ∈ [-B,B]n for which f(x)=yr is solvable for y ∈ Z; then to a polynomial sieve, counting x ∈ [-B,B]n for which f(x)=g(y) is solvable, for a given polynomial g. Formally, a polynomial sieve lemma can encompass the more general problem of counting x ∈ [-B,B]n for which F(y,x)=0 is solvable, for a given polynomial F. Previous applications, however, have only succeeded in the case that F(y,x) exhibits separation of variables, that is, F(y,x) takes the form f(x) - g(y). In the present work, we present the first application of a polynomial sieve to count x ∈ [-B,B]n such that F(y,x)=0 is solvable, in a case for which F does not exhibit separation of variables. Consequently, we obtain a new result toward a question of Serre, pertaining to counting points in thin sets.