The Nash-Tognoli theorem over the rationals and its version for isolated singularities

Abstract

Let Q be the field of rational numbers and let X be a subset of Rn. We say that X is Q-algebraic if it is the common zero set in Rn of a family of polynomials in Q[x1,…,xn]. If X is Q-algebraic and of dimension d, then we say that X is Q-nonsingular if, for all a∈ X, there exist a neighborhood U of a in Rn and f1,…,fn-d∈Q[x1,…,xn] such that ∇ f1(a),…,∇ fn-d(a) are linearly independent and X U=\x∈ U:f1(x)=0,·s,fn-d(x)=0\. The celebrated Nash-Tognoli theorem asserts the following: if M is a compact smooth manifold of dimension d and :M2d+1 is a smooth embedding, then can be approximated by an arbitrarily close smooth embedding φ:M2d+1 whose image φ(M) is a nonsingular algebraic subset of R2d+1. In this article, we prove that φ can be chosen in such a way that φ(M) is a Q-nonsingular Q-algebraic subset of R2d+1. This guarantees for the first time that, up to smooth diffeomorphisms, every compact smooth manifold M can be described both globally and locally by means of finitely many exact data, such as a finite system of generators of the ideal of polynomials in Q[x1,…,x2d+1] vanishing on φ(M). We extend our result to the singular setting by proving that every real algebraic set with finitely many singularities is semialgebraically homeomorphic to a Q-algebraic set with the same number of singularities.