English

Subfield-algebraic geometry

Algebraic Geometry 2025-12-11 v1 Commutative Algebra

Abstract

In this monograph, we lay the foundations for a new theory that generalizes real algebraic geometry. Let RKR|K be a field extension, where RR is a real closed field and KK is an ordered subfield of RR. The main objective is to study KK-algebraic subsets of RnR^n, i.e., those subsets of RnR^n that are the zero loci of polynomials with coefficients in KK. Real algebraic geometry already covers the case when KK is also a real closed field. Our goal is to extend real algebraic geometry to the case when KK is not real closed, for example when KK is the field Q\mathbb{Q} of rational numbers. Several new geometric phenomena appear. There is no complex counterpart to this generalized real algebraic geometry. The reason is as follows. If CKC|K is a field extension with CC algebraically closed and XX is a KK-algebraic subset of CnC^n, then Hilbert's Nullstellensatz implies that the ideal of polynomials with coefficients in CC that vanish on~XX is generated by the ideal of polynomials with coefficients in KK that vanish on XX. In the real realm, this is false in general, for example when we consider field extensions RKR|K with RR real closed and K=QK=\mathbb{Q}. This monograph also presents some applications of the theory developed. Here is an example. The celebrated Nash-Tognoli theorem states that every compact smooth manifold MM is diffeomorphic to a nonsingular real algebraic set MM', called algebraic model of MM. The theory developed here provides the theoretical basis to prove that the algebraic model MM' of MM can be chosen to be Q\mathbb{Q}-algebraic and Q\mathbb{Q}-nonsingular. This guarantees for the first time that, up to smooth diffeomorphisms, every compact smooth manifold can be encoded both globally and locally involving only finitely many exact data.

Keywords

Cite

@article{arxiv.2512.08975,
  title  = {Subfield-algebraic geometry},
  author = {José F. Fernando and Riccardo Ghiloni},
  journal= {arXiv preprint arXiv:2512.08975},
  year   = {2025}
}

Comments

124 pages, 5 figures

R2 v1 2026-07-01T08:17:40.768Z