Finitely generated algebra

In mathematics, a finitely generated algebra (also called an algebra of finite type) is a commutative associative algebra $A$ over a field $K$ where there exists a finite set of elements $a_{1},\dots ,a_{n}$ of $A$ such that every element of $A$ can be expressed as a polynomial in $a_{1},\dots ,a_{n}$ , with coefficients in $K$ .

Equivalently, there exist elements $a_{1},\dots ,a_{n}\in A$ such that the evaluation homomorphism at ${\bf {a}}=(a_{1},\dots ,a_{n})$

\phi _{\bf {a}}\colon K[X_{1},\dots ,X_{n}]\twoheadrightarrow A

is surjective; thus, by applying the first isomorphism theorem, $A\simeq K[X_{1},\dots ,X_{n}]/{\rm {ker}}(\phi _{\bf {a}})$ .

Conversely, $A:=K[X_{1},\dots ,X_{n}]/I$ for any ideal $I\subseteq K[X_{1},\dots ,X_{n}]$ is a $K$ -algebra of finite type, indeed any element of $A$ is a polynomial in the cosets $a_{i}:=X_{i}+I,i=1,\dots ,n$ with coefficients in $K$ . Therefore, we obtain the following characterisation of finitely generated $K$ -algebras^[1]

A

is a finitely generated

K

-algebra if and only if it is isomorphic as a

K

-algebra to a quotient ring of the type

K[X_{1},\dots ,X_{n}]/I

by an ideal

I\subseteq K[X_{1},\dots ,X_{n}]

.

If it is necessary to emphasize the field K then the algebra is said to be finitely generated over K. Algebras that are not finitely generated are called infinitely generated.

Examples

The polynomial algebra $K[x_{1},\dots ,x_{n}]$ is finitely generated. The polynomial algebra in countably infinitely many generators is infinitely generated.
The field $E=K(t)$ of rational functions in one variable over an infinite field $K$ is not a finitely generated algebra over $K$ . On the other hand, $E$ is generated over $K$ by a single element, $t$ , as a field.
If $E/F$ is a finite field extension then it follows from the definitions that $E$ is a finitely generated algebra over $F$ .
Conversely, if $E/F$ is a field extension and $E$ is a finitely generated algebra over $F$ then the field extension is finite. This is called Zariski's lemma. See also integral extension.
If $G$ is a finitely generated group then the group algebra $KG$ is a finitely generated algebra over $K$ .

Properties

A homomorphic image of a finitely generated algebra is itself finitely generated. However, a similar property for subalgebras does not hold in general.
Hilbert's basis theorem: if A is a finitely generated commutative algebra over a Noetherian ring then every ideal of A is finitely generated, or equivalently, A is a Noetherian ring.

Relation with affine varieties

Finitely generated reduced commutative algebras are basic objects of consideration in modern algebraic geometry, where they correspond to affine algebraic varieties; for this reason, these algebras are also referred to as (commutative) affine algebras. More precisely, given an affine algebraic set $V\subseteq \mathbb {A} ^{n}$ we can associate a finitely generated $K$ -algebra

\Gamma (V):=K[X_{1},\dots ,X_{n}]/I(V)

called the affine coordinate ring of $V$ ; moreover, if $\phi \colon V\to W$ is a regular map between the affine algebraic sets $V\subseteq \mathbb {A} ^{n}$ and $W\subseteq \mathbb {A} ^{m}$ , we can define a homomorphism of $K$ -algebras

\Gamma (\phi )\equiv \phi ^{*}\colon \Gamma (W)\to \Gamma (V),\,\phi ^{*}(f)=f\circ \phi ,

then, $\Gamma$ is a contravariant functor from the category of affine algebraic sets with regular maps to the category of reduced finitely generated $K$ -algebras: this functor turns out^[2] to be an equivalence of categories

\Gamma \colon ({\text{affine algebraic sets}})^{\rm {opp}}\to ({\text{reduced finitely generated }}K{\text{-algebras}}),

and, restricting to affine varieties (i.e. irreducible affine algebraic sets),

\Gamma \colon ({\text{affine algebraic varieties}})^{\rm {opp}}\to ({\text{integral finitely generated }}K{\text{-algebras}}).

Finite algebras vs algebras of finite type

We recall that a commutative $R$ -algebra $A$ is a ring homomorphism $\phi \colon R\to A$ ; the $R$ -module structure of $A$ is defined by

\lambda \cdot a:=\phi (\lambda )a,\quad \lambda \in R,a\in A.

An $R$ -algebra $A$ is called finite if it is finitely generated as an $R$ -module, i.e. there is a surjective homomorphism of $R$ -modules

R^{\oplus _{n}}\twoheadrightarrow A.

Again, there is a characterisation of finite algebras in terms of quotients^[3]

An

R

-algebra

A

is finite if and only if it is isomorphic to a quotient

R^{\oplus _{n}}/M

by an

R

-submodule

M\subseteq R

.

By definition, a finite $R$ -algebra is of finite type, but the converse is false: the polynomial ring $R[X]$ is of finite type but not finite. However, if an $R$ -algebra is of finite type and integral, then it is finite. More precisely, $A$ is a finitely generated $R$ -module if and only if $A$ is generated as an $R$ -algebra by a finite number of elements integral over $R$ .

Finite algebras and algebras of finite type are related to the notions of finite morphisms and morphisms of finite type.

References

^ Kemper, Gregor (2009). A Course in Commutative Algebra. Springer. p. 8. ISBN 978-3-642-03545-6.
^ Görtz, Ulrich; Wedhorn, Torsten (2010). Algebraic Geometry I. Schemes With Examples and Exercises. Springer. p. 19. doi:10.1007/978-3-8348-9722-0. ISBN 978-3-8348-0676-5.
^ Atiyah, Michael Francis; Macdonald, Ian Grant (1994). Introduction to commutative algebra. CRC Press. p. 21. ISBN 9780201407518.

Examples

Properties

Relation with affine varieties

Finite algebras vs algebras of finite type

References

See also