The local solubility for homogeneous polynomials with random coefficients over thin sets

Abstract

Let d and n be natural numbers greater or equal to 2. Let a, d,n(x)∈ Z[x] be a homogeneous polynomial in n variables of degree d with integer coefficients a, where ·,· denotes the inner product, and d,n: Rn→ RN denotes the Veronese embedding with N=n+d-1d. Consider a variety Va in Pn-1, defined by a, d,n(x)=0. In this paper, we examine a set of these varieties defined by VPd,n(A)=\ Va⊂ Pn-1|\ P(a)=0,\ \|a\|∞≤ A\, where P∈ Z[x] is a non-singular form in N variables of degree k with 2 k≤ C(n,d) for some constant C(n,d) depending at most on n and d. Suppose that P(a)=0 has a nontrivial integer solution. We confirm that the proportion of varieties Va in VPd,n(A), which are everywhere locally soluble, converges to a constant cP as A→ ∞. In particular, if there exists b∈ ZN such that P(b)=0 and the variety Vb in Pn-1 admits a smooth Q-rational point, the constant cP is positive.