Artin-Tate lemma: Difference between revisions

Latest revision as of 16:18, 12 May 2008

This article is about the statement of a simple but indispensable lemma in commutative algebra
View other indispensable lemmata

This article defines a result where the base ring (or one or more of the rings involved) is Noetherian
View more results involving Noetherianness or Read a survey article on applying Noetherianness

Statement

Suppose $A,B,C$ are commutative unital rings, such that:

$A$ is Noetherian
$B$ and $C$ are $A$ -algebras, with $B$ a subalgebra of $C$
$C$ is finitely generated as an $A$ -algebra (i.e. $C$ is an algebra of finite type over $A$ )
$C$ is finitely generated as a $B$ -module (i.e. $C$ is finite as an algebra over $B$ )

Then: $B$ is finitely generated as an $A$ -algebra

Explanation

The Artin-Tate lemma is related to the general philosophy that if an object is finitely generated, then any subobject of it is also finitely generated provided the subobject is almost the whole object. In our case, $C$ is finitely generated as an $A$ -algebra, but it is not necessary that all subalgebras of $C$ are finitely generated as $A$ -algebras. However, if the subalgebra is large enough inside $C$ , i.e. it is not too deep, then it behaves like $C$ , and we can try to show it is finitely generated.

An analogous result in group theory is the statement that any subgroup of finite index in a finitely generated group, is also finitely generated.

Definitions used

Facts used

Any submodule of a finitely generated module over a Noetherian ring, is finitely generated
Any finitely generated algebra over a finitely generated algebra is finitely generated
Finitely generated and integral implies finite: A finitely generated algebra over a ring, such that every element in it is integral over the ring, is finite as an algebra i.e. is finitely generated as a module over the base ring.
Any finitely generated algebra over a Noetherian ring is Noetherian. This follows from two facts: any polynomial ring over a Noetherian ring is Noetherian, and Any quotient ring of a Noetherian ring is Noetherian.

Proof

Find a finitely generated subalgebra of $B$

Pick a finite generating set $c_{1},c_{2},\ldots ,c_{r}$ of $C$ as an algebra over $A$ .

Since $C$ is finitely generated as a $B$ -module, every element in $C$ is integral over $B$ . In particular, every $c_{i}$ is integral over $B$ . Choose a monic polynomial satisfied by $c_{i}$ over $B$ for each $i$ , and consider the $A$ -algebra $B_{0}$ generated by the coefficients of all such monic polynomials.

Clearly $B_{0}$ satisfies the following:

$B_{0}$ is an $A$ -subalgebra of $B$
$B_{0}$ is finitely generated as an $A$ -algebra
$C$ is finitely generated as a $B_{0}$ -algebra (since in fact $C$ is finitely generated as an $A$ -algebra)
$C$ is integral over $B_{0}$

Going down

Since $C$ is both finitely generated as a $B_{0}$ -algebra and integral over $B_{0}$ , we see that $C$ is finitely generated as a $B_{0}$ -module.

We now use the fact that $A$ is Noetherian, and $B_{0}$ is finitely generated as an $A$ -algebra, to conclude that $B_{0}$ is Noetherian. Thus $C$ is a finitely generated module over a Noetherian ring $B_{0}$ . Hence, the submodule $B$ is also finitely generated as a $B_{0}$ -module. In particular, $B$ is finitely generated as a $B_{0}$ -algebra.

Transitivity

We know that $B_{0}$ is finitely generated as an $A$ -algebra, and we just proved that $B$ is finitely generated as a $B_{0}$ -algebra. Thus, $B$ is finitely generated as an $A$ -algebra.

@@ Line 1: / Line 1: @@
+{{indispensable lemma}}
+{{Noetherian ring result}}
 ==Statement==
@@ Line 5: / Line 7: @@
 * <math>A</math> is [[Noetherian ring|Noetherian]]
 * <math>B</math> and <math>C</math> are <math>A</math>-algebras, with <math>B</math> a subalgebra of <math>C</math>
-* <math>C</math> is finitely generated as an <math>A</matH>-algebra
+* <math>C</math> is finitely generated as an <math>A</math>-algebra (i.e. <math>C</math> is an [[algebra of finite type]] over <math>A</math>)
-* <math>C</math> is finitely generated as a <math>B</math>-module
+* <math>C</math> is finitely generated as a <math>B</math>-module (i.e. <math>C</math> is [[finiteness as an algebra|finite as an algebra]] over <math>B</math>)
 Then: <math>B</math> is finitely generated as an <math>A</math>-algebra
+==Explanation==
+The Artin-Tate lemma is related to the general philosophy that if an object is ''finitely generated'', then any subobject of it is also finitely generated provided the subobject is ''almost'' the whole object. In our case, <math>C</math> is finitely generated as an <math>A</math>-algebra, but it is not necessary that ''all'' subalgebras of <math>C</math> are finitely generated as <math>A</math>-algebras. However, if the subalgebra is ''large'' enough inside <math>C</math>, i.e. it is ''not too deep'', then it behaves like <math>C</math>, and we can try to show it is finitely generated.
+An analogous result in group theory is the statement that [[gp:finite index in finitely generated implies finitely generated|any subgroup of finite index in a finitely generated group, is also finitely generated]].
+==Definitions used==
+==Facts used==
+* Any submodule of a finitely generated module over a Noetherian ring, is finitely generated
+* Any finitely generated algebra over a finitely generated algebra is finitely generated
+* [[Finitely generated and integral implies finite]]: A finitely generated algebra over a ring, such that every element in it is integral over the ring, is finite as an algebra i.e. is finitely generated as a module over the base ring.
+* Any finitely generated algebra over a Noetherian ring is Noetherian. This follows from two facts: [[Noetherianness is polynomial-closed|any polynomial ring over a Noetherian ring is Noetherian]], and [[Noetherianness is quotient-closed|Any quotient ring of a Noetherian ring is Noetherian]].
+==Proof==
+===Find a finitely generated subalgebra of <math>B</math>===
+Pick a finite generating set <math>c_1, c_2, \ldots, c_r</math> of <math>C</math> as an algebra over <math>A</math>.
+Since <math>C</math> is finitely generated as a <math>B</math>-module, every element in <math>C</math> is integral over <math>B</math>. In particular, every <math>c_i</math> is integral over <math>B</math>. Choose a monic polynomial satisfied by <math>c_i</math> over <math>B</math> for each <math>i</math>, and consider the <math>A</math>-algebra <math>B_0</math> generated by the coefficients of all such monic polynomials.
+Clearly <math>B_0</math> satisfies the following:
+* <math>B_0</math> is an <math>A</math>-subalgebra of <math>B</math>
+* <math>B_0</math> is finitely generated as an <math>A</math>-algebra
+* <math>C</math> is finitely generated as a <math>B_0</math>-algebra (since in fact <math>C</math> is finitely generated as an <math>A</math>-algebra)
+* <math>C</math> is integral over <math>B_0</math>
+===Going down===
+Since <math>C</math> is both finitely generated as a <math>B_0</math>-algebra and integral over <math>B_0</math>, we see that <math>C</math> is finitely generated as a <math>B_0</math>-module.
+We now use the fact that <math>A</math> is Noetherian, and <math>B_0</math> is finitely generated as an <math>A</math>-algebra, to conclude that <math>B_0</math> is Noetherian. Thus <math>C</math> is a finitely generated module over a Noetherian ring <math>B_0</math>. Hence, the submodule <math>B</math> is also finitely generated as a <math>B_0</math>-module. In particular, <math>B</matH> is finitely generated as a <math>B_0</math>-algebra.
+===Transitivity===
+We know that <math>B_0</math> is finitely generated as an <math>A</math>-algebra, and we just proved that <math>B</math> is finitely generated as a <math>B_0</math>-algebra. Thus, <math>B</math> is finitely generated as an <math>A</math>-algebra.