Product and its Existence

Definition

Let $C$ be a category, $X, Y$ objects in $C$ . An object $Z$ plus two morphisms

is a (fiber) product if it has the following universal mapping property: for all objects $W$ and morphisms

there is a unique morphism $t : W \to Z$ such that $r = p \cdot t, s = q \cdot t$ , i.e., such that

commutes.

Lemma

If $X, Y \in C$ and $X \times Y$ exists, then $st (X \times Y) ≃ st (X) \times st (Y)$ , where $st : C \to Set, X \mapsto st (X)$ is a forgetful functor.

\begin{proof} For any $(x_{0}, y_{0}) \in st (X) \times st (Y)$ , define $A^{0} = {p}$ and $A^{0} \to X, p \mapsto x_{0}$ and $A^{0} \to Y, p \mapsto y_{0}$ . By universal property, there exists unique $θ : A^{0} \to X \times Y$ and $θ (p) \leftrightarrow (x_{0}, y_{0})$ .

Conversely, for $w_{0} \in st (X \times Y)$ , we have $p (w_{0}) = x_{0}$ and $q (w_{0}) = y_{0}$ where $p, q$ are projection map. \end{proof}

in the Category of Affine Varieties

Proposition

Let $X$ and $Y$ be affine varieties, with coordinate rings $R$ and $S$ . Then

there is a product prevariety $X \times Y$ .

$X \times Y$ is affine with coordinate ring $R \otimes_{k} S$ .

a basis of the topology is given by the open sets

$\sum f_{i} (x) g_{i} (y) \neq = 0, f_{i} \in R, g_{i} \in S$

$\underline{o}_{(x, y)}$ is the localization of $\underline{o}_{x} \otimes_{k} \underline{o}_{y}$ at the maximal ideal $m_{x} \cdot \underline{o}_{y} + \underline{o}_{x} \cdot m_{y}$ .

Remark. We only need the fiber product is a prevariety. If $W = \cup_{finite} W_{i}$ with affine varieties $W_{i}$ , then $W$ is a fiber product iff ${W_{i}}_{i}$ are fiber products.

\begin{proof} It is a sketch of proof generated by Gemini.

Construction of $X \times Y$ (Set of Points and Algebraic Structure):
- If $X \subseteq k^{n_{1}}$ is defined by ideal $I \subset k [x_{1}, ..., x_{n_{1}}]$ and $Y \subseteq k^{n_{2}}$ by ideal $J \subset k [y_{1}, ..., y_{n_{2}}]$ , then the set of points $X \times Y$ can be naturally viewed as the algebraic set $V (I + J)$ in $k^{n_{1} + n_{2}}$ defined by the ideal $I + J \subset k [x_{1}, ..., x_{n_{1}}, y_{1}, ..., y_{n_{2}}]$ .
- Its coordinate ring is $k [x_{i}, y_{j}] / (I + J)$ . There is a standard isomorphism:
  $k [x_{i}, y_{j}] / (I + J) ≅ (k [x_{i}] / I) \otimes_{k} (k [y_{j}] / J) = R \otimes_{k} S$
- Key Algebraic Fact: Since $k$ is an algebraically closed field and $X, Y$ are varieties, $R$ and $S$ are integral domains. In this case, $R \otimes_{k} S$ is also an integral domain.
- Corollary: Because $R \otimes_{k} S$ is an integral domain, the radical of the ideal generated by $I + J$ in $k [x_{i}, y_{j}]$ is a prime ideal. This means the algebraic set $X \times Y$ is irreducible. Therefore, $(X \times Y, \underline{o}_{X \times Y})$ is itself an affine variety, whose coordinate ring is precisely $R \otimes_{k} S$ .
Verifying the Universal Property:
- We need to show that the constructed affine variety $X \times Y = Spec (R \otimes_{k} S)$ satisfies the categorical definition of a product.
- The projection maps $p : X \times Y \to X$ and $q : X \times Y \to Y$ are natural (algebraically corresponding to $R ↪ R \otimes_{k} S$ and $S ↪ R \otimes_{k} S$ ) and are morphisms.
- Given any prevariety $W$ and two morphisms $r : W \to X$ , $s : W \to Y$ , we can first uniquely define a map of sets $t : W \to X \times Y$ such that $p \circ t = r, q \circ t = s$ , namely $t (w) = (r (w), s (w))$ .
- We need to verify that $t$ is a morphism. This can be done by checking that the pullback $t^{*}$ maps regular functions on $X \times Y$ to regular functions on $W$ . Since $Γ (X \times Y) = R \otimes_{k} S$ is generated by elements from $R$ and $S$ , and since $r^{*}$ and $s^{*}$ already pull back elements of $R$ and $S$ to $Γ (W, \underline{o}_{W})$ (because $r, s$ are morphisms), using the universal property of tensor products, one can show that $t^{*}$ is a ring homomorphism, and thus $t$ is a morphism.
Basis of Topology:
- The basis for the topology on an affine variety $Spec (A)$ is given by the principal open sets $D (h) = {P \in Spec (A) ∣ h \in / P}$ , where $h \in A$ .
- In $X \times Y = Spec (R \otimes_{k} S)$ , an element $h$ has the form $h = \sum f_{i} \otimes g_{i}$ . The point $(x, y)$ corresponds to the maximal ideal $m_{(x, y)}$ . The condition $h \in / m_{(x, y)}$ is usually interpreted as $h (x, y) \neq = 0$ , which means $\sum f_{i} (x) g_{i} (y) \neq = 0$ . Thus, these sets form a basis for the topology.
Local Ring:
- The local ring $\underline{o}_{Z, z}$ of an affine variety $Z = Spec (A)$ at a point $z$ (corresponding to maximal ideal $m_{z}$ ) is the localization $A_{m_{z}}$ .
- Therefore, $\underline{o}_{(x, y)} = (R \otimes_{k} S)_{m_{(x, y)}}$ .
- The equivalent description given in the Red Book is that $\underline{o}_{(x, y)}$ is the localization of the ring $\underline{o}_{x} \otimes_{k} \underline{o}_{y}$ at the maximal ideal $m_{x} \cdot \underline{o}_{y} + \underline{o}_{x} \cdot m_{y}$ .
- (Here $\underline{o}_{x} = R_{m_{x}}$ and $\underline{o}_{y} = S_{m_{y}}$ . $m_{x} \cdot \underline{o}_{y}$ denotes the ideal generated by elements $a \otimes b$ where $a \in m_{x} \subset \underline{o}_{x}, b \in \underline{o}_{y}$ , and $\underline{o}_{x} \cdot m_{y}$ is similar. This ideal corresponds to the functions in $\underline{o}_{x} \otimes_{k} \underline{o}_{y}$ that vanish at $(x, y)$ . Note: The corresponding formula in the original notes was incorrect).

Now we finish the proof. \end{proof}

in the Category of Prevarieties

Theorem

Let $X$ and $Y$ be prevarieties over $k$ . Then they have a product.

\begin{proof} Assume $Y$ is affine. Then $X = \cup_{i = 1}^{ℓ} X_{i}$ with $X_{i}$ affine and $X_{i} \times Y$ exists as an affine variety by ^f0237a. Since $(X_{1} \cap X_{2}) \times Y$ is an open set in both $X_{1} \times Y$ and $X_{2} \times Y$ . Then we can glue $X_{1} \times Y$ and $X_{2} \times Y$ along $(X_{1} \cap X_{2}) \times Y$ . Now we get a topological space, and then we construct a sheaf on it by

\underline{o}_{(X_{1} \cup X_{2}) \times Y} (U) = \cap_{(x_{0}, y_{0}) \in (X_{1} \cup X_{2}) \times Y} \underline{o}_{(x_{0}, y_{0})} \subseteq k (X_{1}) \otimes k (X_{2}) .

Assume $Y$ is affine. Then $X = \cup_{i = 1}^{ℓ} X_{i}$ with $X_{i}$ affine and $X_{i} \times Y$ exists as an affine variety by ^f0237a. Since $(X_{1} \cap X_{2}) \times Y$ is an open set in both $X_{1} \times Y$ and $X_{2} \times Y$ . Then we can glue $X_{1} \times Y$ and $X_{2} \times Y$ along $(X_{1} \cap X_{2}) \times Y$ using the identity map. Repeating this for all pairs $i, j$ yields a topological space $Z$ . We construct a sheaf $\underline{o}_{Z}$ on $Z$ by defining its sections on open sets $U \subseteq Z$ :

\underline{o}_{Z} (U) = {f : U \to k : \forall i, f ∣_{U \cap (X_{i} \times Y)} \in \underline{o}_{X_{i} \times Y} (U \cap (X_{i} \times Y))} .

Now we verify $(Z, \underline{o}_{Z})$ is a prevariety. Notice that ${X_{i} \times Y}_{i = 1}^{ℓ}$ is a finite cover of $Z$ , where $X_{i} \times Y$ are irreducible affine varieties. Also note that $X_{i} \times Y$ and $X$ are connected, then $Z$ is also connected, because a space covered by finitely many connected open sets with overlapping intersections is connected. Therefore, $(Z, \underline{o}_{Z})$ is a prevariety. Define $Z = X \times Y$ .

It remains to check the universal property. For any prevariety $W$ and $r : W \to X, s : W \to Y$ , define $t : W \to X \times Y, w \mapsto (r (w), s (w))$ . Then it remains to check $t$ is a morphism. Take a finite open cover ${W_{k}}$ of $W$ such that $r (W_{k}) \subseteq X_{i}$ for some $i$ . Then $t ∣_{W_{k}} : W_{k} \to X_{i} \times Y$ is a morphism by ^f0237a.

By the definition of morphism, it suffices to show for any open set $V \subseteq X \times Y$ and $g \in Γ (V, \underline{o}_{X \times Y})$ , $g \circ t \in Γ (t^{- 1} (V), \underline{o}_{W})$ . For any $w \in t^{- 1} (V)$ , there exists $W_{0} \in {W_{k}}$ containing $w$ such that $t ∣_{W_{0}}$ is a morphism. Define $W_{1} = W_{0} \cap t^{- 1} (V)$ , then $t ∣_{W_{1}}$ is also a morphism. It deduces that

(g \circ t) ∣_{W_{1}} \in Γ (t_{W_{1}}^{- 1} (V), \underline{o}_{W_{1}}) = Γ (W_{1}, \underline{o}_{W_{1}}) .

That is, $g \circ t$ is regular at $w \in W_{1}$ for any $w \in t^{- 1} (V)$ . Thus $g \circ t \in Γ (t^{- 1} (V), \underline{o}_{W})$ and so $t$ is a morphism. The uniqueness is easy to check.

In general, prevariety $Y$ can be written as $Y = \cup_{j} Y_{j}$ with $Y_{j}$ affine. As $X \times Y_{j}$ exists, we can glue $X \times Y_{1}$ and $X \times Y_{2}$ along $X \times (Y_{1} \cap Y_{2})$ . Similarly, we can get a topological space $Z^{'} = X \times Y$ , which satisfies the universal property.

Remark. For affine $X$ and $Y$ , take open $U \subseteq X$ , then $U \times Y$ is open in $X \times Y$ .

in the Category of Projective Varieties

Theorem

The product of two projective varieties is a projective variety.

\begin{proof} Assume $X \subseteq P^{n}$ and $Y \subseteq P^{m}$ , then $X \times Y \subseteq X \times P^{m} \subseteq P^{n} \times P^{m} \to P^{N}$ where $N = (n + 1) (m + 1) - 1$ . Define the Segre embedding

I : P^{n} \times P^{m} \to P^{N}, [x_{0}, \dots, x_{n}], [y_{0}, \dots, y_{m}] \to [\dots, x_{i} y_{j}, \dots]

and $I$ is injective.

It suffices to show $(P^{n})_{x_{0}} \times (P^{m})_{y_{0}} \to P^{N}$ is a closed embedding, that is, the image of $I$ is a subvariety of $P^{N}$ . Note that

(P^{n})_{x_{0}} \times (P^{m})_{y_{0}} ((s_{1}, \dots, s_{n}), (t_{1}, \dots, t_{n})) \to P^{N} \mapsto (\dots, R_{ij}, \dots)

where $s_{i} = x_{i} / x_{0}$ , $t_{j} = y_{j} / y_{0}$ and $R_{ij} = s_{i} t_{j}$ if $ij \neq = 0$ and $R_{0 j} = t_{j}$ , $R_{i 0} = s_{i}$ . Then $im (I) = I (R_{ij} - R_{i 0} \cdot R_{0 j} : i, j ⩾ 1)$ , that is, the ideal generated by $R_{ij} - R_{i 0} R_{0 j}$ .

Check that

k [s_{1}, \dots, s_{n}] \otimes k [t_{1}, \dots, t_{m}] \leftarrow ≃ k [\dots, R_{ij}, \dots] / (R_{ij} - R_{i 0} R_{0 j})_{i, j} Γ (im (I)) \to Γ ((P^{n})_{x_{0}} \times Γ (P^{m})_{y_{0}}), R_{ij} \mapsto s_{i} \otimes t_{j}

is a morphism between affine variety. So $f$ is an isomorphism. \end{proof}

Hausdorff Axiom

Hausdorff axiom

Let $X$ be a prevariety. $X$ is a variety if for all prevarieties $Y$ and for all morphisms

${y \in Y ∣ f (y) = g (y)}$ is a closed subset of $Y$ .

Too similar definitions to differ

Affine variety: Defined by polynomial equations in affine space.

Prevariety: A space locally modeled on affine varieties (can be glued from them).

Variety: A prevariety satisfying the Hausdorff axiom — morphisms into it are distinguishable (equalizer sets are closed).

Example. Let $Y = X \times X, f = p_{1}$ , $g = p_{2}$ . Also let $Δ : X ⟶ X \times X$ be a morphism $(id_{X}, id_{X})$ . $Δ$ is called the diagonal morphism, and

Δ (X) = {z \in X \times X ∣ p_{1} (z) = p_{2} (z)} .

Therefore the Hausdorff axiom implies $Δ (X)$ is closed. In fact, we can prove that for a topological space $X$ , $X$ is Hausdorff iff $Δ (X)$ is closed.

Proposition

Let $X$ be a prevariety. Then $X$ is a variety if and only if $Δ (X)$ is closed in $X \times X$ .

\begin{proof} Suppose $f, g : Y \to X$ are given. Then they induce a morphism $(f, g) : Y \to$ $X \times X$ . Since

{y \in Y ∣ f (y) = g (y)} = θ^{- 1} (Δ (X))

$Δ (X)$ being closed implies the Hausdorff axiom, so $X$ is a variety.

Conversely, if $X$ is a variety, then take $Y = X \times X$ with $f = p_{1}, g = p_{2}$ and $Δ (X) = {z \in Y : p_{1} (z) = p_{2} (z)}$ is closed. \end{proof}

Example. a line with two points at zero does not satisfy Hausdorff axiom, see here.

Separateness = "limit is unique"

Why is this called the “Hausdorff Axiom”? This term draws an analogy with the Hausdorff property in topology:

Topology: Hausdorff separation means distinct points $x \neq = y$ can be separated by disjoint open sets.

This is equivalent to the diagonal $Δ (X)$ being closed in $X \times X$ (product topology).

Algebraic Geometry: The separation axiom here distinguishes morphisms. For any $f, g : Y \to X$ , the set where they agree, $E = {y \in Y ∣ f (y) = g (y)}$ , must be closed in $Y$ (Zariski topology).

Connection to Limits/Closure: Taking the closure of $E$ is similar to taking a limit. As all open sets are dense in $Y$ (if $Y$ is irreducible), a morphism is uniquely determined by its values on an open set.

This axiom is also equivalent to the diagonal $Δ (X)$ being closed in $X \times X$ (product Zariski topology).

Proposition

$X$ is variety, and $Z \subseteq X$ is a closed sub-prevariety. Then $Z$ is a variety.

\begin{proof}

Since $X$ is variety, ${y \in Y : (j \circ f) (y) = (j \circ g) (y)}$ is closed and so ${y \in Y : f (y) = g (y)}$ is closed. Hence $Z$ is a variety. \end{proof}

Proposition

$X, Y$ are varieties, then $X \times Y$ is variety.

\begin{proof} Let $W$ be an arbitrary prevariety, and let $f, g : W \to X \times Y$ be two arbitrary morphisms. By definition, it suffices to show

E = {w \in W ∣ f (w) = g (w)}

is a closed subset of $W$ .

Let $p_{X} : X \times Y \to X$ and $p_{Y} : X \times Y \to Y$ be the projection morphisms. We can decompose the morphisms $f$ and $g$ into their components:

$f_{1} = p_{X} \circ f : W \to X$
$f_{2} = p_{Y} \circ f : W \to Y$
$g_{1} = p_{X} \circ g : W \to X$
$g_{2} = p_{Y} \circ g : W \to Y$

Since compositions of morphisms are morphisms, $f_{1}, f_{2}, g_{1}, g_{2}$ are all morphisms. Note that $w \in E$ iff both $f_{1} (w) = g_{1} (w)$ and $f_{2} (w) = g_{2} (w)$ hold. Let $E_{1} = {w \in W ∣ f_{1} (w) = g_{1} (w)}$ and $E_{2} = {w \in W ∣ f_{2} (w) = g_{2} (w)}$ , then one know $E = E_{1} \cap E_{2}$ . Since $X$ and $Y$ are varieties, $E_{1}$ and $E_{2}$ are closed and so for $E$ . \end{proof}

Proposition

Affine variety is a variety.

\begin{proof} Let $X$ be an affine variety, and let $R = Γ (X, \underline{o}_{X})$ be its coordinate ring. To show $X$ is an variety, it suffices to show for any prevariety $Y$ and any morphisms $f, g : Y \to X$ , the equalizer $E = {y \in Y ∣ f (y) = g (y)}$ is closed in $Y$ .

For any $s \in R$ , the functions $s \circ f$ and $s \circ g$ are global regular functions on $Y$ since $f, g$ are morphisms. Then their difference $(s \circ f) - (s \circ g)$ is also a global regular function on $Y$ . Note that $y \in E$ iff $s (f (y)) = s (g (y))$ for all $s \in R$ . So $E$ can be written that

E = V ({(s \circ f) - (s \circ g) ∣ s \in R}) .

By definition of a prevariety, $E$ is a closed subset of $Y$ . Now we finish the proof.

Alternating proof. Let $X$ be an affine variety, embedded as a closed subset in some affine space $A^{n}$ . Then the product $X \times X$ is a closed subset of $A^{n} \times A^{n} ≅ A^{2 n}$ . Note that

Δ (A^{n}) = {(a, a) ∣ a \in A^{n}} \subseteq A^{n} \times A^{n}

is defined by the equations $x_{1} - y_{1} = 0, \dots, x_{n} - y_{n} = 0$ , where $(x_{1}, \dots, x_{n}, y_{1}, \dots, y_{n})$ are coordinates on $A^{n} \times A^{n}$ . This is clearly a closed set.

It follows that $Δ (X) = Δ (A^{n}) \cap (X \times X)$ is still closed in $A^{2 n}$ and is also a closed subset of $X \times X$ . By ^t398yf, $X$ is a variety. \end{proof}

Proposition

$Δ (X)$ is locally closed. Remark that we say $Z \subseteq X$ is locally closed if for any $z_{0} \in Z$ , there exists open $U \subseteq X$ containing $z_{0}$ such that $Z \cap U$ is closed in $U$ .

\begin{proof} Take $Y = X \times X$ with $f = p_{1}, g = p_{2}$ . Then $Z = Δ (X)$ is closed in $Y$ . For any $z \in Z$ , let $V$ be an affine open neighborhood of $f (z)$ in $X$ . Remark that $f (z) = g (z)$ . Then

Z \cap [f^{- 1} (V) \cap g^{- 1} (V)] = ⎩ ⎨ ⎧ z \in f^{- 1} (V) \cap g^{- 1} (V) f (z) = g (z) in the affine variety ⎭ ⎬ ⎫

where $U := f^{- 1} (V) \cap g^{- 1} (V)$ is an open set containing $z$ . Define $f^{'} = f ∣_{U}$ and $g^{'} = g ∣_{U}$ , then $f^{'}, g^{'}$ are morphisms from $U$ to $V$ . Since $V$ is a variety, ${z^{'} \in U : f^{'} (z) = g^{'} (z)}$ is closed in $U$ , where ${z^{'} \in U : f^{'} (z) = g^{'} (z)} = U \cap Z$ . Now we finish the proof. \end{proof}

Proposition

Let $X$ be a prevariety. If for any $x, y \in X$ , there exists an open affine subvariety $U \subseteq X$ containing $x, y$ . Then $X$ is a variety.

\begin{proof} Define $Z = {y \in Y : f (y) = g (y)}$ . Take $z_{0} \in \overline{Z} \subseteq Y$ . Assume $f (z_{0}) = x$ and $g (z_{0}) = y$ , and we aim to show $x = y$ . By assumption, there exists an affine open set $U$ such that $x, y \in U$ . Then $z_{0} \in V := f^{- 1} (U) \cap g^{- 1} (U)$ is an open set in $Y$ . Since $U$ is affine, $Z \cap V = {v \in V : f ∣_{V} (v) = g ∣_{V} (v)}$ is closed in $V$ by ^w3d7va. It deduces that $\overline{Z \cap V}^{V} = Z \cap V$ .

Note that $z_{0} \in \overline{Z \cap V}^{V} = Z \cap V$ . Thus $z_{0} \in Z$ and so $Z$ is closed. \end{proof}

Corollary

$P^{n}$ is a variety.

\begin{proof} For any $x, y \in P^{n}$ , take $H = {\sum a_{i} x_{i} = 0}$ such that $x, y \in / H$ . Then $A^{n} ≃ P^{n} ∖ H$ contains $x, y$ . By ^c0400a, $P^{n}$ is a variety. \end{proof}

Proposition

Let $X$ be a variety, and let $U, V$ be affine open subvarieties. Then $U \cap V$ is affine.

Counterexample. $A^{2} ∖ {0}$ is not a variety.

\begin{proof} Since $X$ is a variety, the set $Δ (X)$ is closed by ^t398yf. Since $U, V$ are affine open subvarieties, we know $U \times V$ is affine by ^f0237a. Define

τ : U \cap V \to X \times X, x \mapsto (x, x),

and let $π_{1}, π_{2}$ be the projections to the first and second factors, respectively. Since $π_{1} \circ τ$ and $π_{2} \circ τ$ are morphism, by universal property $τ$ is also a morphism. Set $Z^{'} = Δ (X) \cap (U \times V)$ , and define $θ = π_{1} ∣_{Z^{'}} : Z^{'} \to U \cap V$ . It is easy to check $θ \circ τ = id_{U \cap V}$ and $τ \circ θ = id_{Z^{'}}$ . Note that $Z^{'}$ is closed in $U \times V$ and $U \times V$ is an affine variety, then $Z^{'}$ is also an affine variety.

Define $Γ (U) = R$ and $Γ (V) = S$ , then $Γ (U \times V) = R \otimes_{k} S$ by ^f0237a. Since $Z^{'}$ is closed in $U \times V$ , we can set $Γ (Z^{'}) = R \otimes_{k} S / I (Z^{'})$ . Then $τ$ induces the map $τ^{*} : Γ (Z^{'}) \to Γ (U \cap V)$ , and $θ$ induces the map $θ^{*} : Γ (U \cap V) \to Γ (Z^{'})$ . Note that $τ^{*}$ and $θ^{*}$ are inverse, and we have $U \cap V ≃ τ Z^{'}$ . Therefore, $U \cap V$ is affine. \end{proof}

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1.6 Products and the Hausdorff Axiom

Product and its Existence

in the Category of Affine Varieties

in the Category of Prevarieties

in the Category of Projective Varieties

Hausdorff Axiom

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