# Noether normalization lemma

In mathematics, the **Noether normalization lemma** is a result of commutative algebra, introduced by Emmy Noether in 1926.^{[1]} It states that for any field *k*, and any finitely generated commutative *k*-algebra *A*, there exists a nonnegative integer *d* and algebraically independent elements *y*_{1}, *y*_{2}, ..., *y*_{d} in *A*
such that *A* is a finitely generated module over the polynomial ring *S*:=*k*[*y*_{1}, *y*_{2}, ..., *y*_{d}].

The integer *d* is uniquely determined; it is the Krull dimension of the ring *A*; when *A* is an integral domain, *d* is also the transcendence degree of the field of fractions of *A* over *k*.

The theorem has a geometric interpretation. Suppose *A* is integral. Let *S* be the coordinate ring of the *d*-dimensional affine space , and *A* as the coordinate ring of some other *d*-dimensional affine variety *X*. Then the inclusion map *S* → *A* induces a surjective finite morphism of affine varieties . The conclusion is that any affine variety is a branched covering of affine space;
when *k* is infinite, such a branched covering map can be constructed by taking a general projection from an affine space containing *X* to a *d*-dimensional subspace.

More generally, in the language of schemes, the theorem can equivalently be stated as follows: every affine *k*-scheme (of finite type) *X* is finite over an affine *n*-dimensional space; the theorem can be refined to include a chain of ideals of *R* (equivalently, closed subsets of *X*) that are finite over the affine coordinate subspaces of the appropriate dimensions.^{[2]}

The form of the Noether normalization lemma stated above can be used as an important step in proving Hilbert's Nullstellensatz; this gives it further geometric importance, at least formally, as the Nullstellensatz underlies the development of much of classical algebraic geometry. The theorem is also an important tool in establishing the notions of Krull dimension for *k*-algebras.

## Proof[edit]

The following proof is due to Nagata and is taken from Mumford's red book. A proof in the geometric flavor is also given in the page 127 of the red book and this mathoverflow thread.

The ring *A* in the lemma is generated as a *k*-algebra by elements, say, . We shall induct on *m*. If , then the assertion is trivial. Assume now . It is enough to show that there is a subring *S* of *A* that is generated by elements, such that *A* is finite over *S.* Indeed, by the inductive hypothesis, we can find algebraically independent elements of *S* such that *S* is finite over .

Since otherwise there would be nothing to prove, we can also assume that there is a nonzero polynomial *f* in *m* variables over *k* such that

- .

Given an integer *r* which is determined later, set

Then the preceding reads:

- .

Now, the highest term in of looks

Thus, if *r* is larger than any exponent appearing in *f*, then the highest term of in also has the form as above. In other words, is integral over . Since are also integral over that ring, *A* is integral over *S*. It follows *A* is finite over *S,* and since *S* is generated by *m-1* elements, by the inductive hypothesis we are done.

If *A* is an integral domain, then *d* is the transcendence degree of its field of fractions. Indeed, *A* and have the same transcendence degree (i.e., the degree of the field of fractions) since the field of fractions of *A* is algebraic over that of *S* (as *A* is integral over *S*) and *S* obviously has transcendence degree *d*. Thus, it remains to show the Krull dimension of the polynomial ring *S* is *d*. (this is also a consequence of dimension theory.) We induct on *d*, being trivial. Since is a chain of prime ideals, the dimension is at least *d*. To get the reverse estimate, let be a chain of prime ideals. Let . We apply the noether normalization and get (in the normalization process, we're free to choose the first variable) such that *S* is integral over *T*. By inductive hypothesis, has dimension *d* - 1. By incomparability, is a chain of length and then, in , it becomes a chain of length . Since , we have . Hence, .

## Refinement[edit]

The following refinement appears in Eisenbud's book, which builds on Nagata's idea:^{[2]}

**Theorem** — Let *A* be a finitely generated algebra over a field *k*, and be a chain of ideals such that Then there exists algebraically independent elements *y*_{1}, ..., *y*_{d} in *A* such that

*A*is a finitely generated module over the polynomial subring*S*=*k*[*y*_{1}, ...,*y*_{d}].- .
- If the 's are homogeneous, then
*y*_{i}'s may be taken to be homogeneous.

Moreover, if *k* is an infinite field, then *any* sufficiently general choice of *y*_{I}'s has Property 1 above ("sufficiently general" is made precise in the proof).

Geometrically speaking, the last part of the theorem says that for any general linear projection induces a finite morphism (cf. the lede); besides Eisenbud, see also [1].

**Corollary** — Let *A* be an integral domain that is a finitely generated algebra over a field. If is a prime ideal of *A*, then

- .

In particular, the Krull dimension of the localization of *A* at *any* maximal ideal is dim *A*.

**Corollary** — Let be integral domains that are finitely generated algebras over a field. Then

(the special case of Nagata's altitude formula).

## Illustrative application : generic freeness[edit]

The proof of generic freeness (the statement later) illustrates a typical yet nontrivial application of the normalization lemma; the generic freeness says: let be rings such that is a Noetherian integral domain and suppose there is a ring homomorphism that exhibits as a finitely generated algebra over . Then there is some such that is a free -module.

Let be the fraction field of . We argue by induction on the Krull dimension of . The basic case is when the Krull dimension is ; i.e., . This is to say there is some such that and so is free as an -module. For the inductive step, note is a finitely generated -algebra. Hence, by the Noether normalization lemma, contains algebraically independent elements such that is finite over the polynomial ring . Multiplying each by elements of , we can assume are in . We now consider:

It need not be the case that is finite over . But that will be the case after invertible one element, as follows. If is an element of , then, as an element of , it is integral over ; i.e., for some in . Thus, some kills all the denominators of the coefficients of and so is integral over . Choosing some finitely many generators of as an -algebra and applying this observation to each generator, we find some such that is integral (thus finite) over . Replace by and then we can assume is finite over .
To finish, consider a finite filtration by -submodules such that for prime ideals (such a filtration exists by the theory of associated primes). For each *i*, if , by inductive hypothesis, we can choose some in such that is free as an -module, while is a polynomial ring and thus free. Hence, with , is a free module over .

## Notes[edit]

**^**Noether 1926- ^
^{a}^{b}Eisenbud 1995, Theorem 13.3

## References[edit]

- Eisenbud, David (1995),
*Commutative algebra. With a view toward algebraic geometry*, Graduate Texts in Mathematics,**150**, Berlin, New York: Springer-Verlag, ISBN 3-540-94268-8, MR 1322960, Zbl 0819.13001 - Hazewinkel, Michiel, ed. (2001) [1994], "Noether theorem",
*Encyclopedia of Mathematics*, Springer Science+Business Media B.V. / Kluwer Academic Publishers, ISBN 978-1-55608-010-4. NB the lemma is in the updating comments. - Noether, Emmy (1926), "Der Endlichkeitsatz der Invarianten endlicher linearer Gruppen der Charakteristik
*p*",*Nachrichten von der Gesellschaft der Wissenschaften zu Göttingen*: 28–35, archived from the original on 2013-03-08 Cite uses deprecated parameter`|deadurl=`

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