Finite morphism

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In algebraic geometry, a branch of mathematics, a morphism f: X \rightarrow Y of schemes is a finite morphism, if Y has an open cover by affine schemes

Vi = SpecBi

such that for each i,

f − 1(Vi) = Ui

is an open affine subscheme SpecAi, and the restriction of f to Ui, which induces a map of rings

B_i \rightarrow A_i,

makes Ai a finitely generated module over Bi.

[edit] Morphisms of finite type

There is another finiteness condition on morphisms of schemes, morphisms of finite type, which is much weaker than being finite.

Morally, a morphism of finite type corresponds to a set of polynomial equations with finitely many variables. For example, the algebraic equation

y3 = x4z

corresponds to the map of (affine) schemes \mbox{Spec} \; \mathbb Z [x, y, z] / \langle y^3-x^4+z \rangle \rightarrow \mbox{Spec} \; \mathbb Z or equivalently to the inclusion of rings \mathbb Z \rightarrow \mathbb Z [x, y, z] / \langle y^3-x^4+z \rangle. This is an example of a morphism of finite type.

The technical definition is as follows: let {Vi = SpecBi} be an open cover of Y by affine schemes, and for each i let {Uij = SpecAij} be an open cover of f − 1(Vi) by affine schemes. The restriction of f to Uij induces a morphism of rings B_i \rightarrow A_{ij}. The morphism f is called locally of finite type, if Aij is a finitely generated algebra over Bi (via the above map of rings). If in addition the open cover f^{-1}(V_i) = \bigcup_j U_{ij} can be chose to be finite, then f is called of finite type.

For example, if k is a field, the scheme \mathbb{A}^n(k) has a natural morphism to Speck induced by the inclusion of rings k \to k[X_1,\ldots,X_n]. This is a morphism of finite type, but if n > 0 then it is not a finite morphism.

On the other hand, if we take the affine scheme {\mbox{Spec}} \; k[X,Y]/ \langle Y^2-X^3-X \rangle, it has a natural morphism to \mathbb{A}^1 given by the ring homomorphism k[X]\to k[X,Y]/ \langle Y^2-X^3-X \rangle. Then this morphism is a finite morphism.

[edit] Properties of finite morphisms

  • Finite morphisms have finite fibres (i.e. they are quasi-finite).
  • Finite morphisms are proper, in particular closed.
  • Proper, quasi-finite maps are finite. This is a deep theorem.
  • Closed immersions are finite, as they are locally given by A \rightarrow A / I, where I is the ideal corresponding to the closed subset.
  • Any base-change of a finite morphism is finite, i.e. if f: X \rightarrow Y is finite and g: Z \rightarrow Y is any morphism, then the canonical morphism X \times_Y Z \rightarrow Z is finite. This corresponds to the following algebraic statement: if A is a finitely generated B-module, then A \otimes_B C is a finitely generated C-module, where C \rightarrow B is any map. The generators are a_i \otimes 1, where ai are the generators of A as a B-module.
  • The composition of two finite maps is finite.

[edit] See also

Glossary of scheme theory