Residue field

Field arising from a quotient ring by a maximal ideal

In mathematics, the residue field is a basic construction in commutative algebra. If $R$ is a commutative ring and ${\mathfrak {m}}$ is a maximal ideal, then the residue field is the quotient ring $k$ = $R/{\mathfrak {m}}$ , which is a field. Frequently, $R$ is a local ring and ${\mathfrak {m}}$ is then its unique maximal ideal.

In abstract algebra, the splitting field of a polynomial is constructed using residue fields. Residue fields also applied in algebraic geometry, where to every point $x$ of a scheme $X$ one associates its residue field $k(x)$ . One can say a little loosely that the residue field of a point of an abstract algebraic variety is the natural domain for the coordinates of the point.

Definition

Suppose that $R$ is a commutative local ring, with maximal ideal ${\mathfrak {m}}$ . Then the residue field is the quotient ring $R/{\mathfrak {m}}$ .

Now suppose that $X$ is a scheme and $x$ is a point of $X$ . By the definition of scheme, we may find an affine neighbourhood ${\mathcal {U}}={\text{Spec}}(A)$ of $x$ , with some commutative ring $A$ . Considered in the neighbourhood ${\mathcal {U}}$ , the point $x$ corresponds to a prime ideal ${\mathfrak {p}}\subseteq A$ (see Zariski topology). The local ring of $X$ at $x$ is by definition the localization $A_{\mathfrak {p}}$ of $A$ by $A\setminus {\mathfrak {p}}$ , and $A_{\mathfrak {p}}$ has maximal ideal ${\mathfrak {m}}$ = ${\mathfrak {p}}A_{\mathfrak {p}}$ . Applying the construction above, we obtain the residue field of the point $x$ :

k(x):=A_{\mathfrak {p}}/{\mathfrak {p}}A_{\mathfrak {p}}

One can prove that this definition does not depend on the choice of the affine neighbourhood ${\mathcal {U}}$ .

A point is called $\color {blue}k$ -rational for a certain field $k$ , if $k(x)=k$ .

Example

Consider the affine line $\mathbb {A} ^{1}(k)={\text{Spec}}(k)$ over a field $k$ . If $k$ is algebraically closed, there are exactly two types of prime ideals, namely

$(t-a),\,a\in k$
$(0)$ , the zero-ideal.

The residue fields are

$k_{(t-a)}/(t-a)k_{(t-a)}\cong k$
$k_{(0)}\cong k(t)$ , the function field over k in one variable.

If $k$ is not algebraically closed, then more types arise, for example if $k=\mathbb {R}$ , then the prime ideal $(x^{2}+1)$ has residue field isomorphic to $\mathbb {C}$ .

Properties

For a scheme locally of finite type over a field $k$ , a point $x$ is closed if and only if $k(x)$ is a finite extension of the base field $k$ . This is a geometric formulation of Hilbert's Nullstellensatz. In the above example, the points of the first kind are closed, having residue field $k$ , whereas the second point is the generic point, having transcendence degree 1 over $k$ .
A morphism ${\text{Spec}}(K)\rightarrow X$ , $K$ some field, is equivalent to giving a point $x\in X$ and an extension $K/k(x)$ .
The dimension of a scheme of finite type over a field is equal to the transcendence degree of the residue field of the generic point.

References

Dummit, D. S.; Foote, R. (2004). Abstract Algebra (3 ed.). Wiley. ISBN 9780471433347.
David Mumford (1999). The Red Book of Varieties and Schemes: Includes the Michigan Lectures (1974) on Curves and Their Jacobians. Lecture Notes in Mathematics. Vol. 1358 (2nd ed.). Springer-Verlag. doi:10.1007/b62130. ISBN 3-540-63293-X.
Intuitively, the residue field of a point is a local invariant. Axioms of schemes are set up in such a way as to assure the compatibility between various affine open neighborhoods of a point, which implies the statement.
Görtz, Ulrich and Wedhorn, Torsten. Algebraic Geometry: Part 1: Schemes (2010) Vieweg+Teubner Verlag.

Misplaced Pages

Definition

Example

Properties

See also

References

Further reading