Chow's lemma

Chow's lemma, named after Wei-Liang Chow, is one of the foundational results in algebraic geometry. It 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 ${\displaystyle X}$ is a scheme that is proper over a noetherian base ${\displaystyle S}$, then there exists a projective ${\displaystyle S}$-scheme ${\displaystyle X^{\prime }}$ and a surjective ${\displaystyle S}$-morphism ${\displaystyle f:X^{\prime }\to X}$ that induces an isomorphism ${\displaystyle f^{-1}(U)\simeq U}$ for some dense open ${\displaystyle U\subseteq X.}$

The proof here is a standard one.^[2]

We can first reduce to the case where ${\displaystyle X}$ is irreducible. To start, ${\displaystyle X}$ is noetherian since it is of finite type over a noetherian base. Therefore it has finitely many irreducible components ${\displaystyle X_i}$, and we claim that for each ${\displaystyle X_i}$ there is an irreducible proper ${\displaystyle S}$-scheme ${\displaystyle Y_i}$ so that ${\displaystyle Y_i\to X}$ has set-theoretic image ${\displaystyle X_i}$ and is an isomorphism on the open dense subset ${\displaystyle X_i\setminus {\cup }_{j\ne i}{X}_j}$ of ${\displaystyle X_i}$. To see this, define ${\displaystyle Y_i}$ to be the scheme-theoretic image of the open immersion

${\displaystyle X\setminus {\cup }_{j\ne i}{X}_j\to X.}$

Since ${\displaystyle X\setminus {\cup }_{j\ne i}{X}_j}$ is set-theoretically noetherian for each ${\displaystyle i}$, the map ${\displaystyle X\setminus {\cup }_{j\ne i}{X}_j\to X}$ is quasi-compact and we may compute this scheme-theoretic image affine-locally on ${\displaystyle X}$, immediately proving the two claims. If we can produce for each ${\displaystyle Y_i}$ a projective ${\displaystyle S}$-scheme ${\displaystyle {Y_i}^{\prime }}$ as in the statement of the theorem, then we can take ${\displaystyle X^{\prime }}$ to be the disjoint union ${\displaystyle \coprod {Y_i}^{\prime }}$ and ${\displaystyle f}$ to be the composition ${\displaystyle \coprod {Y_i}^{\prime }\to \coprod Y_i\to X}$: this map is projective, and an isomorphism over a dense open set of ${\displaystyle X}$, while ${\displaystyle \coprod {Y_i}^{\prime }}$ is a projective ${\displaystyle S}$-scheme since it is a finite union of projective ${\displaystyle S}$-schemes. Since each ${\displaystyle Y_i}$ is proper over ${\displaystyle S}$, we've completed the reduction to the case ${\displaystyle X}$ irreducible.

Next, we will show that ${\displaystyle X}$ can be covered by a finite number of open subsets ${\displaystyle U_i}$ so that each ${\displaystyle U_i}$ is quasi-projective over ${\displaystyle S}$. To do this, we may by quasi-compactness first cover ${\displaystyle S}$ by finitely many affine opens ${\displaystyle S_j}$, and then cover the preimage of each ${\displaystyle S_j}$ in ${\displaystyle X}$ by finitely many affine opens ${\displaystyle X_{jk}}$ each with a closed immersion in to ${\displaystyle {\mathbb{𝔸}}_{S_j}^n}$ since ${\displaystyle X\to S}$ is of finite type and therefore quasi-compact. Composing this map with the open immersions ${\displaystyle {\mathbb{𝔸}}_{S_j}^n\to {\mathbb{\mathbb{P}}}_{S_j}^n}$ and ${\displaystyle {\mathbb{\mathbb{P}}}_{S_j}^n\to {\mathbb{\mathbb{P}}}_S^n}$, we see that each ${\displaystyle X_{ij}}$ is a closed subscheme of an open subscheme of ${\displaystyle {\mathbb{\mathbb{P}}}_S^n}$. As ${\displaystyle {\mathbb{\mathbb{P}}}_S^n}$ is noetherian, every closed subscheme of an open subscheme is also an open subscheme of a closed subscheme, and therefore each ${\displaystyle X_{ij}}$ is quasi-projective over ${\displaystyle S}$.

Now suppose ${\displaystyle \{U_i\}}$ is a finite open cover of ${\displaystyle X}$ by quasi-projective ${\displaystyle S}$-schemes, with ${\displaystyle {\varphi }_i:U_i\to P_i}$ an open immersion in to a projective ${\displaystyle S}$-scheme. Set ${\displaystyle U={\cap }_i{U}_i}$, which is nonempty as ${\displaystyle X}$ is irreducible. The restrictions of the ${\displaystyle {\varphi }_i}$ to ${\displaystyle U}$ define a morphism

${\displaystyle \varphi :U\to P=P_1{\times }_S\cdots {\times }_S{P}_n}$

so that ${\displaystyle U\to U_i\to P_i=U\stackrel{\varphi }{\to }P\stackrel{p_i}{\to }{P}_i}$, where ${\displaystyle U\to U_i}$ is the canonical injection and ${\displaystyle p_i:P\to P_i}$ is the projection. Letting ${\displaystyle j:U\to X}$ denote the canonical open immersion, we define ${\displaystyle \psi =(j,\varphi {)}_S:U\to X{\times }_{S}P}$, which we claim is an immersion. To see this, note that this morphism can be factored as the graph morphism ${\displaystyle U\to U{\times }_{S}P}$ (which is a closed immersion as ${\displaystyle P\to S}$ is separated) followed by the open immersion ${\displaystyle U{\times }_{S}P\to X{\times }_{S}P}$; as ${\displaystyle X{\times }_{S}P}$ is noetherian, we can apply the same logic as before to see that we can swap the order of the open and closed immersions.

Now let ${\displaystyle X^{\prime }}$ be the scheme-theoretic image of ${\displaystyle \psi }$, and factor ${\displaystyle \psi }$ as

${\displaystyle \psi :U\stackrel{{\psi }^{\prime }}{\to }{X}^{\prime }\stackrel{h}{\to }X{\times }_{S}P}$

where ${\displaystyle {\psi }^{\prime }}$ is an open immersion and ${\displaystyle h}$ is a closed immersion. Let ${\displaystyle q_1:X{\times }_{S}P\to X}$ and ${\displaystyle q_2:X{\times }_{S}P\to P}$ be the canonical projections. Set

${\displaystyle f:X^{\prime }\stackrel{h}{\to }X{\times }_{S}P\stackrel{q_1}{\to }X,}$

${\displaystyle g:X^{\prime }\stackrel{h}{\to }X{\times }_{S}P\stackrel{q_2}{\to }P.}$

We will show that ${\displaystyle X^{\prime }}$ and ${\displaystyle f}$ satisfy the conclusion of the theorem.

To show ${\displaystyle f}$ is surjective, we first note that it is proper and therefore closed. As its image contains the dense open set ${\displaystyle U\subset X}$, we see that ${\displaystyle f}$ must be surjective. It is also straightforward to see that ${\displaystyle f}$ induces an isomorphism on ${\displaystyle U}$: we may just combine the facts that ${\displaystyle f^{-1}(U)=h^{-1}(U{\times }_{S}P)}$ and ${\displaystyle \psi }$ is an isomorphism on to its image, as ${\displaystyle \psi }$ factors as the composition of a closed immersion followed by an open immersion ${\displaystyle U\to U{\times }_{S}P\to X{\times }_{S}P}$. It remains to show that ${\displaystyle X^{\prime }}$ is projective over ${\displaystyle S}$.

We will do this by showing that ${\displaystyle g:X^{\prime }\to P}$ is an immersion. We define the following four families of open subschemes:

${\displaystyle V_i={\varphi }_i(U_i)\subset P_i}$

${\displaystyle W_i=p_i^{-1}(V_i)\subset P}$

${\displaystyle {U_i}^{\prime }=f^{-1}(U_i)\subset X^{\prime }}$

${\displaystyle {U_i}^{″}=g^{-1}(W_i)\subset X^{\prime }.}$

As the ${\displaystyle U_i}$ cover ${\displaystyle X}$, the ${\displaystyle {U_i}^{\prime }}$ cover ${\displaystyle X^{\prime }}$, and we wish to show that the ${\displaystyle {U_i}^{″}}$ also cover ${\displaystyle X^{\prime }}$. We will do this by showing that ${\displaystyle {U_i}^{\prime }\subset {U_i}^{″}}$ for all ${\displaystyle i}$. It suffices to show that ${\displaystyle p_i\circ g{|}_{{U_i}^{\prime }}:{U_i}^{\prime }\to P_i}$ is equal to ${\displaystyle {\varphi }_i\circ f{|}_{{U_i}^{\prime }}:{U_i}^{\prime }\to P_i}$ as a map of topological spaces. Replacing ${\displaystyle {U_i}^{\prime }}$ by its reduction, which has the same underlying topological space, we have that the two morphisms ${\displaystyle ({U_i}^{\prime }{)}_{red}\to P_i}$ are both extensions of the underlying map of topological space ${\displaystyle U\to U_i\to P_i}$, so by the reduced-to-separated lemma they must be equal as ${\displaystyle U}$ is topologically dense in ${\displaystyle U_i}$. Therefore ${\displaystyle {U_i}^{\prime }\subset {U_i}^{″}}$ for all ${\displaystyle i}$ and the claim is proven.

The upshot is that the ${\displaystyle W_i}$ cover ${\displaystyle g(X^{\prime })}$, and we can check that ${\displaystyle g}$ is an immersion by checking that ${\displaystyle g{|}_{{U_i}^{″}}:{U_i}^{″}\to W_i}$ is an immersion for all ${\displaystyle i}$. For this, consider the morphism

${\displaystyle u_i:W_i\stackrel{p_i}{\to }{V}_i\stackrel{{\varphi }_i^{-1}}{\to }{U}_i\to X.}$

Since ${\displaystyle X\to S}$ is separated, the graph morphism ${\displaystyle {\mathrm{\Gamma }}_{u_i}:W_i\to X{\times }_S{W}_i}$ is a closed immersion and the graph ${\displaystyle T_i={\mathrm{\Gamma }}_{u_i}(W_i)}$ is a closed subscheme of ${\displaystyle X{\times }_S{W}_i}$; if we show that ${\displaystyle U\to X{\times }_S{W}_i}$ factors through this graph (where we consider ${\displaystyle U\subset X^{\prime }}$ via our observation that ${\displaystyle f}$ is an isomorphism over ${\displaystyle f^{-1}(U)}$ from earlier), then the map from ${\displaystyle {U_i}^{″}}$ must also factor through this graph by construction of the scheme-theoretic image. Since the restriction of ${\displaystyle q_2}$ to ${\displaystyle T_i}$ is an isomorphism onto ${\displaystyle W_i}$, the restriction of ${\displaystyle g}$ to ${\displaystyle {U_i}^{″}}$ will be an immersion into ${\displaystyle W_i}$, and our claim will be proven. Let ${\displaystyle v_i}$ be the canonical injection ${\displaystyle U\subset X^{\prime }\to X{\times }_S{W}_i}$; we have to show that there is a morphism ${\displaystyle w_i:U\subset X^{\prime }\to W_i}$ so that ${\displaystyle v_i={\mathrm{\Gamma }}_{u_i}\circ w_i}$. By the definition of the fiber product, it suffices to prove that ${\displaystyle q_1\circ v_i=u_i\circ q_2\circ v_i}$, or by identifying ${\displaystyle U\subset X}$ and ${\displaystyle U\subset X^{\prime }}$, that ${\displaystyle q_1\circ \psi =u_i\circ q_2\circ \psi }$. But ${\displaystyle q_1\circ \psi =j}$ and ${\displaystyle q_2\circ \psi =\varphi }$, so the desired conclusion follows from the definition of ${\displaystyle \varphi :U\to P}$ and ${\displaystyle g}$ is an immersion. Since ${\displaystyle X^{\prime }\to S}$ is proper, any ${\displaystyle S}$-morphism out of ${\displaystyle X^{\prime }}$ is closed, and thus ${\displaystyle g:X^{\prime }\to P}$ is a closed immersion, so ${\displaystyle X^{\prime }}$ is projective. ${\displaystyle ◼}$

In the statement of Chow's lemma, if ${\displaystyle X}$ is reduced, irreducible, or integral, we can assume that the same holds for ${\displaystyle X^{\prime }}$. If both ${\displaystyle X}$ and ${\displaystyle X^{\prime }}$ are irreducible, then ${\displaystyle f:X^{\prime }\to X}$ is a birational morphism.^[3]

• Grothendieck, Alexandre; Dieudonné, Jean (1961). "Éléments de géométrie algébrique: II. Étude globale élémentaire de quelques classes de morphismes". Publications Mathématiques de l'IHÉS 8. doi:10.1007/bf02699291. http://www.numdam.org/item/PMIHES_1961__8__5_0. 
• Hartshorne, Robin (1977), Algebraic Geometry, Graduate Texts in Mathematics, 52, New York: Springer-Verlag, ISBN 978-0-387-90244-9 

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