Parabolic induction

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Template:Distinguish In algebraic geometry Chow's lemma, named after Wei-Liang Chow, roughly says that a proper morphism is fairly close to being a projective morphism. More precisely, a version of it states the following:[1]

If X is a scheme that is proper over a noetherian base S, then there exists a projective S-scheme X' and S-morphism f:XX that induces f1(U)U for some open dense subset U.

Chow's lemma is one of the foundational results in algebraic geometry.

Proof

The proof here is a standard one (cf. Template:Harvnb).

It is easy to reduce to the case when X is irreducible. X is noetherian since it is of finite type over a noetherian base. Thus, we can find a finite open affine cover X=i=1nUi. Ui are quasi-projective over S; there are open immersions over S ϕi:UiPi into some projective S-schemes Pi. Put U=Ui. U is nonempty since X is irreducible. Let

ϕ:UP=P1×S×SPn.

be given by ϕi's restricted to U over S. Let

ψ:UX×SP.

be given by UX and ϕ over S. ψ is then an immersion; thus, it factors as an open immersion followed by a closed immersion XX×SP. Let f:XX be the immersion followed by the projection. We claim f induces f1(U)U; for that, it is enough to show f1(U)=ψ(U). But this means that ψ(U) is closed in U×SP. ψ factorizes as UΓϕU×SPX×SP. P is separated over S and so the graph morphism Γϕ is a closed immersion. This proves our contention.

It remains to show X is projective over S. Let g:XP be the closed immersion followed by the projection. Showing that g is a closed immersion shows X is projective over S. This can be checked locally. Identifying Ui with its image in Pi we suppress ϕi from our notation.

Let Vi=pi1(Ui) where pi:PPi. We claim g1(Vi) are an open cover of X. This would follow from f1(Ui)g1(Vi) as sets. This in turn follows from f=pig on Ui as functions on the underlying topological space. Since X is separated over S and Ui is dense, this is clear from looking at the relevant commutative diagram. Now, X×SPP is closed since it is a base extension of the proper morphism XS. Thus, g(X) is a closed subscheme covered by Vi and so it is enough to show for each i g:g1(Vi)Vi, denoted by h, is a closed immersion.

Fix i. Let Z be the graph of u:VipiUiX. It is a closed subscheme of X×SVi since X is separated over S. Let q1:X×SPX,q2:X×SPP be the projections. We claim h factors through Z, which would imply h is a closed immersion. But for w:UVi we have:

v=Γuwq1v=uq2vq1ψ=uq2ψq1ψ=uϕ.

The last equality holds and thus there is w that satisfies the first equality. This proves our claim.

References

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