Subfield-algebraic geometry
Abstract
In this monograph, we lay the foundations for a new theory that generalizes real algebraic geometry. Let R|K be a field extension, where R is a real closed field and K is an ordered subfield of R. The main objective is to study K-algebraic subsets of Rn, i.e., those subsets of Rn that are the zero loci of polynomials with coefficients in K. Real algebraic geometry already covers the case when K is also a real closed field. Our goal is to extend real algebraic geometry to the case when K is not real closed, for example when K is the field 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 C|K is a field extension with C algebraically closed and X is a K-algebraic subset of Cn, then Hilbert's Nullstellensatz implies that the ideal of polynomials with coefficients in C that vanish on~X is generated by the ideal of polynomials with coefficients in K that vanish on X. In the real realm, this is false in general, for example when we consider field extensions R|K with R real closed and K=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 M is diffeomorphic to a nonsingular real algebraic set M', called algebraic model of M. The theory developed here provides the theoretical basis to prove that the algebraic model M' of M can be chosen to be Q-algebraic and 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.
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