mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...

, specifically in

algebraic geometry Algebraic geometry is a branch of mathematics, classically studying zeros of multivariate polynomials. Modern algebraic geometry is based on the use of abstract algebraic techniques, mainly from commutative algebra, for solving geometrical ...

, the fiber product of schemes is a fundamental construction. It has many interpretations and special cases. For example, the fiber product describes how an

algebraic variety Algebraic varieties are the central objects of study in algebraic geometry, a sub-field of mathematics. Classically, an algebraic variety is defined as the set of solutions of a system of polynomial equations over the real or complex numbers. ...

over one field determines a variety over a bigger field, or the pullback of a family of varieties, or a fiber of a family of varieties. Base change is a closely related notion.

Definition

The

category Category, plural categories, may refer to: Philosophy and general uses *Categorization, categories in cognitive science, information science and generally * Category of being * ''Categories'' (Aristotle) * Category (Kant) * Categories (Peirce) ...

of schemes is a broad setting for algebraic geometry. A fruitful philosophy (known as Grothendieck's relative point of view) is that much of algebraic geometry should be developed for a morphism of schemes ''X'' → ''Y'' (called a scheme ''X'' over ''Y''), rather than for a single scheme ''X''. For example, rather than simply studying

algebraic curve In mathematics, an affine algebraic plane curve is the zero set of a polynomial in two variables. A projective algebraic plane curve is the zero set in a projective plane of a homogeneous polynomial in three variables. An affine algebraic plane ...

s, one can study families of curves over any base scheme ''Y''. Indeed, the two approaches enrich each other. In particular, a scheme over a

commutative ring In mathematics, a commutative ring is a ring in which the multiplication operation is commutative. The study of commutative rings is called commutative algebra. Complementarily, noncommutative algebra is the study of ring properties that are not ...

''R'' means a scheme ''X'' together with a morphism ''X'' → Spec(''R''). The older notion of an algebraic variety over a field ''k'' is equivalent to a scheme over ''k'' with certain properties. (There are different conventions for exactly which schemes should be called "varieties". One standard choice is that a variety over a field ''k'' means an integral separated scheme of finite type over ''k''..) In general, a morphism of schemes ''X'' → ''Y'' can be imagined as a family of schemes parametrized by the points of ''Y''. Given a morphism from some other scheme ''Z'' to ''Y'', there should be a "pullback" family of schemes over ''Z''. This is exactly the fiber product ''X'' ×_''Y'' ''Z'' → ''Z''. Formally: it is a useful property of the category of schemes that the fiber product always exists. That is, for any morphisms of schemes ''X'' → ''Y'' and ''Z'' → ''Y'', there is a scheme ''X'' ×_''Y'' ''Z'' with morphisms to ''X'' and ''Z'', making the diagram

commutative In mathematics, a binary operation is commutative if changing the order of the operands does not change the result. It is a fundamental property of many binary operations, and many mathematical proofs depend on it. Most familiar as the name of ...

, and which is

universal Universal is the adjective for universe. Universal may also refer to: Companies * NBCUniversal, a media and entertainment company ** Universal Animation Studios, an American Animation studio, and a subsidiary of NBCUniversal ** Universal TV, a t ...

with that property. That is, for any scheme ''W'' with morphisms to ''X'' and ''Z'' whose compositions to ''Y'' are equal, there is a unique morphism from ''W'' to ''X'' ×_''Y'' ''Z'' that makes the diagram commute. As always with universal properties, this condition determines the scheme ''X'' ×_''Y'' ''Z'' up to a unique isomorphism, if it exists. The proof that fiber products of schemes always do exist reduces the problem to the tensor product of commutative rings (cf.

gluing schemes In algebraic geometry, a new scheme (e.g. an algebraic variety) can be obtained by gluing existing schemes through gluing maps. Statement Suppose there is a (possibly infinite) family of schemes \_ and for pairs i, j, there are open subsets U_ a ...

). In particular, when ''X'', ''Y'', and ''Z'' are all

affine scheme In commutative algebra, the prime spectrum (or simply the spectrum) of a ring ''R'' is the set of all prime ideals of ''R'', and is usually denoted by \operatorname; in algebraic geometry it is simultaneously a topological space equipped with the ...

s, so ''X'' = Spec(''A''), ''Y'' = Spec(''B''), and ''Z'' = Spec(''C'') for some commutative rings ''A'',''B'',''C'', the fiber product is the affine scheme :

X\times_Y Z = \operatorname(A\otimes_B C).

The morphism ''X'' ×_''Y'' ''Z'' → ''Z'' is called the base change or pullback of the morphism ''X'' → ''Y'' via the morphism ''Z'' → ''Y''. In some cases, the fiber product of schemes has a right adjoint, the restriction of scalars.

Interpretations and special cases

*In the category of schemes over a field ''k'', the product ''X'' × ''Y'' means the fiber product ''X'' ×_''k'' ''Y'' (which is shorthand for the fiber product over Spec(''k'')). For example, the product of affine spaces A^''m'' and A^''n'' over a field ''k'' is the affine space A^''m''+''n'' over ''k''. *For a scheme ''X'' over a field ''k'' and any

field extension In mathematics, particularly in algebra, a field extension is a pair of fields E\subseteq F, such that the operations of ''E'' are those of ''F'' restricted to ''E''. In this case, ''F'' is an extension field of ''E'' and ''E'' is a subfield of ...

''E'' of ''k'', the base change ''X''_''E'' means the fiber product ''X'' ×_Spec(''k'') Spec(''E''). Here ''X''_''E'' is a scheme over ''E''. For example, if ''X'' is the curve in the projective plane P over the

real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every ...

s R defined by the equation ''xy''² = 7''z''³, then ''X''_C is the complex curve in P defined by the same equation. Many properties of an algebraic variety over a field ''k'' can be defined in terms of its base change to the algebraic closure of ''k'', which makes the situation simpler. *Let ''f'': ''X'' → ''Y'' be a morphism of schemes, and let ''y'' be a point in ''Y''. Then there is a morphism Spec(''k''(''y'')) → ''Y'' with image ''y'', where ''k''(''y'') is the

residue field In mathematics, the residue field is a basic construction in commutative algebra. If ''R'' is a commutative ring and ''m'' is a maximal ideal, then the residue field is the quotient ring ''k'' = ''R''/''m'', which is a field. Frequently, ''R'' is a ...

of ''y''. The fiber of ''f'' over ''y'' is defined as the fiber product ''X'' ×_''Y'' Spec(''k''(''y'')); this is a scheme over the field ''k''(''y'').Hartshorne (1977), section II.3. This concept helps to justify the rough idea of a morphism of schemes ''X'' → ''Y'' as a family of schemes parametrized by ''Y''. *Let ''X'', ''Y'', and ''Z'' be schemes over a field ''k'', with morphisms ''X'' → ''Y'' and ''Z'' → ''Y'' over ''k''. Then the set of ''k''- rational points of the fiber product ''X'' x_''Y'' ''Z'' is easy to describe: ::

(X\times_Y Z)(k)=X(k)\times_Z(k).

:That is, a ''k''-point of ''X'' x_''Y'' ''Z'' can be identified with a pair of ''k''-points of ''X'' and ''Z'' that have the same image in ''Y''. This is immediate from the universal property of the fiber product of schemes. *If ''X'' and ''Z'' are closed subschemes of a scheme ''Y'', then the fiber product ''X'' x_''Y'' ''Z'' is exactly the

intersection In mathematics, the intersection of two or more objects is another object consisting of everything that is contained in all of the objects simultaneously. For example, in Euclidean geometry, when two lines in a plane are not parallel, thei ...

''X'' ∩ ''Z'', with its natural scheme structure.. The same goes for open subschemes.

Base change and descent

Some important properties P of morphisms of schemes are preserved under arbitrary base change. That is, if ''X'' → ''Y'' has property P and ''Z'' → ''Y'' is any morphism of schemes, then the base change ''X'' x_''Y'' ''Z'' → ''Z'' has property P. For example,

flat morphism In mathematics, in particular in the theory of schemes in algebraic geometry, a flat morphism ''f'' from a scheme ''X'' to a scheme ''Y'' is a morphism such that the induced map on every stalk is a flat map of rings, i.e., :f_P\colon \mathcal_ \ ...

smooth morphism In algebraic geometry, a morphism f:X \to S between schemes is said to be smooth if *(i) it is locally of finite presentation *(ii) it is flat, and *(iii) for every geometric point \overline \to S the fiber X_ = X \times_S is regular. (iii) mea ...

proper morphism In algebraic geometry, a proper morphism between schemes is an analog of a proper map between complex analytic spaces. Some authors call a proper variety over a field ''k'' a complete variety. For example, every projective variety over a field ...

s, and many other classes of morphisms are preserved under arbitrary base change.. The word descent refers to the reverse question: if the pulled-back morphism ''X'' x_''Y'' ''Z'' → ''Z'' has some property P, must the original morphism ''X'' → ''Y'' have property P? Clearly this is impossible in general: for example, ''Z'' might be the empty scheme, in which case the pulled-back morphism loses all information about the original morphism. But if the morphism ''Z'' → ''Y'' is flat and surjective (also called faithfully flat) and

quasi-compact In mathematics, specifically general topology, compactness is a property that seeks to generalize the notion of a closed and bounded subset of Euclidean space by making precise the idea of a space having no "punctures" or "missing endpoints", i ...

, then many properties do descend from ''Z'' to ''Y''. Properties that descend include flatness, smoothness, properness, and many other classes of morphisms.. These results form part of Grothendieck's theory of

faithfully flat descent Faithfully flat descent is a technique from algebraic geometry, allowing one to draw conclusions about objects on the target of a faithfully flat morphism. Such morphisms, that are flat and surjective, are common, one example coming from an open c ...

. Example: for any field extension ''k'' ⊂ ''E'', the morphism Spec(''E'') → Spec(''k'') is faithfully flat and quasi-compact. So the descent results mentioned imply that a scheme ''X'' over ''k'' is smooth over ''k'' if and only if the base change ''X''_''E'' is smooth over ''E''. The same goes for properness and many other properties.

Notes

References

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External links

*{{Citation , author1=The Stacks Project Authors , title=The Stacks Project , url=http://stacks.math.columbia.edu/ *