nLab real closed field

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Contents

Definition
Properties
Examples
Infinites and infinitesimals
In constructive mathematics
Related concepts
References

Definition

An ordered field $F$ is real closed if it satisfies the following two properties:

Any non-negative element $x \geq 0$ in $F$ has a square root in $F$ ;
Any odd-degree polynomial with coefficients in $F$ has a root in $F$ .

Notice that the order on a real closed field is definable from the algebraic structure: $x \leq y$ if and only if $\exists_z x + z^2 = y$ . (In particular, there is a unique ordering on a real closed field, defined by taking the positive elements to be precisely the nonzero squares.) In fact, the category of real closed fields and order-preserving field homomorphisms is a full subcategory of the category Field of fields and field homomorphisms.

Properties

Real closed fields can be equivalently characterized by any of the following properties:

$F$ is not algebraically closed, but some finite extension is. This extension is necessarily $F[\sqrt{-1}]$ . See also fundamental theorem of algebra.
As a field, $F$ is elementarily equivalent to the field of real numbers.
The intermediate value theorem holds for all polynomial functions with coefficients in $F$ .
$F$ is an ordered field that has no ordered algebraic extension.

In fact, there is a completion of any ordered field to a real closed field, in the following sense:

Theorem

The full inclusion of the category of real closed fields and field homomorphisms to the category of ordered fields and ordered field homomorphisms has a left adjoint.

Proof

We give a brief sketch of proof, referring to Lang’s Algebra ( $3^{rd}$ edition), section IX.2, for more details.

First, for each ordered field $F$ , there is a real closed algebraic extension $F \to R$ that is order-preserving (theorem 2.11). This is called a real closure of the ordered field $F$ .

Second, any two real closures of $F$ are uniquely isomorphic (theorem 2.9); in fact, the proof shows there is at most one order-preserving homomorphism over $F$ between any two real closures. Therefore we may speak of the real closure of $F$ , which we denote as $\widebar{F}$ .

Finally, let $F \to R$ be any order-preserving field homomorphism to a real closed field $R$ . We must show that $F \to R$ extends uniquely to a homomorphism $i: \widebar{F} \to R$ . Any such homomorphism $i$ must factor through the subfield $R' \hookrightarrow R$ consisting of elements $\alpha \in R$ that are algebraic over $F$ , since $\widebar{F}$ is algebraic over $F$ . But this subfield is also real closed. Therefore, by the preceding paragraph, there is at most one homomorphism $\widebar{F} \to R'$ extending $F \to R'$ , and the proof is complete.

Examples

The real numbers form a real closed field.
Real algebraic numbers form a real closed field, which is the real closure of the ordered field of rational numbers.
A field of nonstandard real numbers (as in Robinson nonstandard analysis) is real closed.
Surreal numbers form a (large) real closed field.
If $F$ is real closed, then the field of Puiseux series over $F$ is also real closed.
More generally, given a real closed field $F$ , the field of Hahn series over $F$ with value group $G$ (a linearly ordered group) is real closed provided that $G$ is divisible.
Any o-minimal ordered ring structure $R$ is a real closed field.
Given an o-minimal ordered ring $R$ , the field of germs at infinity of definable functions $R \to R$ in any o-minimal expansion of $(R, 0, 1, +, -, \cdot, \lt)$ is real closed. (By “germ at infinity”, we mean an equivalence class of functions for which $f \equiv g$ if and only if $f(x) = g(x)$ for all sufficiently large $x$ .)

Infinites and infinitesimals

Each real closed field $R$ contains a valuation subring $B \hookrightarrow R$ consisting of the “bounded” or archimedean elements, i.e., elements $x \in R$ such that $-n \leq x \leq n$ for some integer multiple $n$ of the identity. An element in the complement of $B$ is an infinite element of $R$ , and the reciprocal of an infinite element is an infinitesimal element. The field of fractions of $B$ is clearly $R$ .

We remark that any real closed field contains a copy of the field of real algebraic numbers, which as before we denote by $\widebar{\mathbb{Q}}$ (not to be confused with the algebraic closure of $\mathbb{Q}$ ). Each of the elements of $\widebar{\mathbb{Q}}$ is archimedean.

Let $B^\ast$ be the group of units of $B$ . The quotient $R^\ast/B^\ast$ is the value group of $R$ . It can be viewed as the “group of orders of infinities and infinitesimals” of $R$ . If $R$ is real closed, then the value group is a linearly ordered divisible group (divisible because we can take $n^{th}$ roots of positive elements in $R$ ). The structure of the value group as ordered group is an important invariant of the real closed field.

In the other direction, to each ordered divisible abelian group $G$ , there exists a real closed field having $G$ as its value group. For example, one may form the Hahn series over $\widebar{\mathbb{Q}}$ with value group $G$ .

In constructive mathematics

In constructive mathematics, the various definitions of real closed field bifurcate, because of different definitions of an odd-degree polynomial. One could define an odd-degree polynomial as a polynomial whose coefficient for an odd number $n$ is not equal to zero and whose coefficient for all $i \gt n$ for is equal to zero. On the other hand, one could also define an odd-degree polynomial as a polynomial whose coefficient for an odd number $n$ is apart from zero and whose coefficient for all $i \gt n$ for is equal to zero. These two definitions are different from each other, the real numbers satisfy the second, while they do not satisfy the first.

Related concepts

Euclidean geometry – Tarski’s axioms

References

Serge Lang, Algebra (3rd edition), Addison-Wesley, 1993.
David Marker, Notes on Real Algebra (link)

Last revised on February 17, 2024 at 12:00:01. See the history of this page for a list of all contributions to it.