Kleiman's theorem

Last updated November 09, 2019

In algebraic geometry, Kleiman's theorem, introduced by Kleiman (1974), concerns dimension and smoothness of scheme-theoretic intersection after some perturbation of factors in the intersection.

In algebraic geometry, the dimension of a scheme is a generalization of a dimension of an algebraic variety. Scheme theory emphasizes the relative point of view and, accordingly, the relative dimension of a morphism of schemes is also important.

In algebraic geometry, the scheme-theoretic intersection of closed subschemes X, Y of a scheme W is $, the fiber product of the closed immersions . It is denoted by .$

either $gV_{1}\times _{X}V_{2}$ is empty or has pure dimension $\dim V_{1}+\dim V_{2}-\dim X$ , where $gV_{1}$ is $V_{1}\to X{\overset {g}{\to }}X$ ,
(Kleiman–Bertini theorem) If $V_{i}$ are smooth varieties and if the characteristic of the base field k is zero, then $gV_{1}\times _{X}V_{2}$ is smooth.

Statement 1 establishes a version of Chow's moving lemma:^[2] after some perturbation of cycles on X, their intersection has expected dimension.

In algebraic geometry, Chow's moving lemma, proved by Wei-Liang Chow (1956), states: given algebraic cycles Y, Z on a nonsingular quasi-projective variety X, there is another algebraic cycle Z' on X such that Z' is rationally equivalent to Z and Y and Z' intersect properly. The lemma is one of key ingredients in developing the intersection theory, as it is used to show the uniqueness of the theory.

Sketch of proof

We write $f_{i}$ for $V_{i}\to X$ . Let $h:G\times V_{1}\to X$ be the composition that is $(1_{G},f_{1}):G\times V_{1}\to G\times X$ followed by the group action $\sigma :G\times X\to X$ .

Let $\Gamma =(G\times V_{1})\times _{X}V_{2}$ be the fiber product of $h$ and $f_{2}:V_{2}\to X$ ; its set of closed points is

In mathematics, specifically in algebraic geometry, 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 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.

\Gamma =\{(g,v,w)|g\in G,v\in V_{1},w\in V_{2},g\cdot f_{1}(v)=f_{2}(w)\}

.

We want to compute the dimension of $\Gamma$ . Let $p:\Gamma \to V_{1}\times V_{2}$ be the projection. It is surjective since $G$ acts transitively on X. Each fiber of p is a coset of stabilizers on X and so

\dim \Gamma =\dim V_{1}+\dim V_{2}+\dim G-\dim X

.

Consider the projection $q:\Gamma \to G$ ; the fiber of q over g is $gV_{1}\times _{X}V_{2}$ and has the expected dimension unless empty. This completes the proof of Statement 1.

In mathematics, a projection is a mapping of a set into a subset, which is equal to its square for mapping composition. The restriction to a subspace of a projection is also called a projection, even if the idempotence property is lost. An everyday example of a projection is the casting of shadows onto a plane. The projection of a point is its shadow on the paper sheet. The shadow of a point on the paper sheet is this point itself (idempotency). The shadow of a three-dimensional sphere is a closed disk. Originally, the notion of projection was introduced in Euclidean geometry to denote the projection of the Euclidean space of three dimensions onto a plane in it, like the shadow example. The two main projections of this kind are:

For Statement 2, since G acts transitively on X and the smooth locus of X is nonempty (by characteristic zero), X itself is smooth. Since G is smooth, each geometric fiber of p is smooth and thus $p_{0}:\Gamma _{0}:=(G\times V_{1,{\text{sm}}})\times _{X}V_{2,{\text{sm}}}\to V_{1,{\text{sm}}}\times V_{2,{\text{sm}}}$ is a smooth morphism. It follows that a general fiber of $q_{0}:\Gamma _{0}\to G$ is smooth by generic smoothness. $\square$

Notes

↑ Fulton (1998 , Appendix B. 9.2.)
↑ Fulton (1998 , Example 11.4.5.)

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References

Eisenbud, David; Harris, Joe (2016), 3264 and All That: A Second Course in Algebraic Geometry, Cambridge University Press, ISBN 978-1107602724
Kleiman, Steven L. (1974), "The transversality of a general translate", Compositio Mathematica , 28: 287–297, MR 0360616
Fulton, William (1998), Intersection Theory, Ergebnisse der Mathematik und ihrer Grenzgebiete. 3. Folge., 2 (2nd ed.), Berlin, New York: Springer-Verlag, ISBN 978-3-540-62046-4, MR 1644323

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[1] Fulton (1998 , Appendix B. 9.2.)

[2] Fulton (1998 , Example 11.4.5.)

Kleiman's theorem

Contents

Sketch of proof

Notes

Related Research Articles

References