Definition

A (closed) algebraic subset of $k^{n}$ is defined as $V := {z \in k^{n} : f_{1} (z) = \dots = f_{m} (z) = 0}$ with $f_{i} \in k [x_{1}, \dots, x_{n}]$ .

Let $I = (f_{1}, \dots, f_{n})$ be the ideal generated by $f_{i}$ . Then $V = V (I) = {z \in k^{n} : f (z) = 0, \forall f \in I}$ . Note that $k (x_{1}, \dots, x_{n})$ is Noetherian, then any ideal $I$ is finitely generated and $I = (f_{1}, \dots, f_{ℓ})$ . It deduces that $V (I) = {z \in k^{n} : f_{1} (z) = \dots = f_{ℓ} (z) = 0}$ .

Remark. Note that $V ((0)) = k [x_{1}, \dots, x_{n}]$ and $V (k [x_{1}, \dots, x_{n}]) = \emptyset$ .

Definition

Let $V \subseteq k^{n}$ be an algebraic set. Define $I (V) = {f \in k [x_{1}, \dots, x_{n}] : f (V) = 0}$ .

Facts.

$I (V) \subseteq k [x_{1}, \dots, x_{n}]$ is an ideal.
$V (I (V)) = V$ .

Hilbert's Nullstellensatz

$I (V (I)) = I := {f \in k [x_{1}, \dots, x_{n}] : \mbox t h eree x i s t s m \mbox, s u c h t ha t f^{m} \in I}$ .

\begin{proof} "→" If $f \in I$ , then $f^{m} \in I$ and $f^{m} (z) = 0$ for all $z \in V (I)$ . Thus $f (z) = 0$ and so $f \in I (V (I))$ .

"←" Let $I = (f_{1}, \dots, f_{n})$ . For $z$ with $f_{1} (z) = \dots = f_{n} (z) = 0$ and $g$ with $g (z) = 0$ , we aim to show there exists $m$ such that $g^{m} \in I$ .

Define an ideal $B = I \cdot k [x_{1}, \dots, x_{n}, x_{n + 1}] + (1 - g \cdot x_{n + 1})$ .

Step 1. We claim that $B = k [x_{1}, \dots, x_{n + 1}]$ . Otherwise, if $B ⊊ k [x_{1}, \dots, x_{n + 1}]$ , then $B \subseteq M$ for some maximal ideal $M$ and $M = (x_{1} - a_{1}, \dots, x_{n + 1} - a_{n + 1})$ by weak Nullstellensatz. Since $f \in B \subseteq M$ , we have $f_{i} (a_{1}, \dots, a_{m}) = 0$ for $1 ⩽ i ⩽ n$ . It deduces that $g (a_{1}, \dots, a_{n}) = 0$ . Since $1 - g \cdot x_{n + 1} \in B$ , then $1 - g (a_{1}, \dots, a_{n}) \cdot a_{n + 1} = 1$ , which is a contradiction. Therefore, $B = k [x_{1}, \dots, x_{n + 1}]$ .

Step 2. As $B = k [x_{1}, \dots, x_{n + 1}]$ , we have

1 = i = 1 \sum n h_{i} (x_{1}, \dots, x_{n}, x_{n + 1}) f_{i} (x_{1}, \dots, x_{n}) + h_{n + 1} (x_{1}, \dots, x_{n + 1}) (1 - g x_{n + 1}) .

Let $x_{n + 1} = 1/ g$ , then

1 = i = 1 \sum n h_{i} (x_{1}, \dots, x_{n}, 1/ g) f_{i} (x_{1}, \dots, x_{n}) .

There exists $m$ large enough such that $g^{m} h_{i} (x_{1}, \dots, x_{n}, 1/ g) \in (f_{1}, \dots, f_{m})$ and then

g^{m} = \sum g^{m} h_{i} (x_{1}, \dots, x_{n}, 1/ g) f_{i} (x_{1}, \dots, x_{n}) \in (f_{1}, \dots, f_{m}) .

Now we finish the proof. \end{proof}

Corollary

There exists a 1-1 correspondence
${V \subseteq k^{n} : V \mbox i s ana l g e b r ai cse t} \leftrightarrow {I \subseteq k [x_{1}, \dots, x_{n}] : I = I} .$

Proposition

The followings hold.

If $I \subseteq J$ , then $V (I) \supseteq V (J)$ ;

If $V_{1} \subseteq V_{2}$ , then $I (V_{1}) \supseteq I (V_{2})$ ;

If $V (\sum_{α} I_{α}) = \cap_{α} V (I_{α})$ ;

$V (I \cap J) = V (I) \cup V (J)$ .

\begin{proof} i)-iii) are easy to proof.

iv) Since $I \cap J \subseteq I, J$ , we have $V (I \cap J) \supseteq V (I) \cup V (J)$ . If $z \in / V (I) \cup V (J)$ , then there exists $f \in I, g \in J$ such that $f (z) \neq = 0$ and $g (z) \neq = 0$ . It deduces that $0 \neq = f (z) g (z)$ with $f g \in V \cap J$ and so $z \in V (I \cap J)$ . Thus $V (I \cap J) \subseteq V (I) \cup V (J)$ . \end{proof}

Remark.

Here is an example to show $V (\cap_{α \in Λ} I_{α}) \neq = \cup_{α \in Λ} V (I_{α})$ . Note that $I (Q) = {f \in C [x] : f (Q) = 0} = {0}$ and $V (I (Q)) = \cup_{q \in Q} V (I (q))$ . If $V (I (Q))$ is closed, then $Q = V (I (Q)) = V ((0)) = C$ , which is a contradiction.
Close set are “measure zero”: for any $f \in I ∖ {0}$ , we have $V \subseteq V ((f)) = {z : f (z) = 0}$ .

Definition

A closed algebraic set is irreducible if it is NOT the union of $2$ strictly smaller closed algebraic sets.

Example. Notice that $V (x y) = {x y = 0} \subseteq C^{2} = {x = 0} \cup {y = 0} = V ((x)) \cup V ((y))$ , so $V ((x y))$ is not irreducible.

Explanation with ideals.

Here are some facts:
- $I = I$ and $J = J$ , then $I \cap J = I \cap J$ ;
- All prime ideals $P$ satisfying $P = P$ ;
- If $P$ is a prime ideal and $P = I \cap J$ , then $P = I$ or $J$ . (Otherwise, take $x \in I ∖ P$ and $y \in J ∖ P$ , then $x y \in P$ leading to a contradiction.)
Assume that $I, J_{1}, J_{2}$ are radical ideals. Then $V (I) = V (J_{1}) \cup V (J_{2}) = V (J_{1} \cap J_{2})$ iff $I = J_{1} \cap J_{2}$ . Hence,
- $V (I)$ is irreducible iff for $I = J_{1} \cap J_{2}$ there is $I = J_{i}$ for some $i$ .
- $V (I)$ is not irreducible iff there exists $I \neq = J_{i}$ such that $I = J_{1} \cap J_{2}$ .
Primary decomposition: If $I \subseteq k [x_{1}, \dots, x_{n}]$ is an ideal with $I = I$ , there exists unique ${P_{i} : P_{i} \mbox i s a p r im e i d e a l, 1 ⩽ i ⩽ m}$ such that $I = P_{1} \cap P_{2} \cap \dots \cap P_{m}$ .
With the uniqueness of primary decomposition, we have the following proposition.

Proposition

$V (I) \subseteq k^{n}$ is irreducible with $I = I$ iff $I$ is a prime ideal;

$V (I) = V_{1} \cup \dots \cup V_{m}$ is uniquely decomposed into irreducible sets with $V_{i} \neq = V_{j}$ .

\begin{proof} If $I = P_{1} \cap \dots \cap P_{m}$ is uniquely decomposed, then $V (I) = V (P_{1}) \cup \dots \cup V (P_{m})$ . If $V (I)$ is irreducible, then note that $V (I) = V (P_{1}) \cup V (P_{2} \cap \dots \cap P_{m})$ and there exists $V (I) = V (P_{j})$ such that $I = P_{j}$ . If $V (I) = V (P_{1}) \cup \dots \cup V (P_{m}) = V (Q_{1}) \cup \dots \cup V (Q_{ℓ})$ , then $P_{1} \cap \dots \cap P_{m} = Q_{1} \cap \dots \cap Q_{ℓ}$ and ${P_{1}, \dots, P_{m}} = {Q_{1}, \dots, Q_{ℓ}}$ by uniqueness of primary decomposition. \end{proof}

Projective Algebraic Set

Definition

Define projective space $P^{n} (k) = {(z_{1}, \dots, z_{n}) \in k^{n + 1} ∖ {0} / \sim} = {[z_{0} : \dots : z_{n}] : z_{0}, \dots, z_{n} \mbox a re n o t a ll zero}$ , where $(z_{0}, \dots, z_{n}) \sim (u_{0}, \dots, u_{n})$ if there exists $λ \in k^{*} = k ∖ {0}$ such that $(z_{0}, \dots, z_{n}) = (λ u_{0}, \dots, λ u_{n})$ and $[z_{0}, \dots, z_{n}]$ are homogeneous coordinate.

Definition

For homogeneous polynomials $f_{1}, \dots, f_{m}$ , define $V = {\overline{x} \in P^{n} (k) : f_{1} (\overline{x}) = \dots = f_{m} (\overline{x}) = 0}$ and define $(f_{1}, \dots, f_{m})$ as the ideal generated by homogeneous polynomial.

Conversely, for any homogeneous ideal $I$ , define $V (I) = {\overline{x} \in P^{n} (k) : \forall f \in I, f (\overline{x}) = 0}$ .

Fact. It has same propositions as ^487780 and ^894d70.

Theorem

There is a $1$ - $1$ correspondence
${V \subseteq P^{n} (k) : V \mbox i s ana l g e b r ai cse t} \leftrightarrow {\mbox h o m o g e n eo u s i d e a l I \mbox s u c h t ha t I = I \mbox e x ce pt (x_{0}, \dots, x_{n})} .$

Proposition

Any algebraic set $V \subseteq P^{n} (k)$ , we have a unique composition $V = V_{1} \cup \dots \cup V_{m}$ with irreducible $V_{i}$ .

${V \mbox i rre d u c ib l e} \leftrightarrow {\mbox h o m o g e n eo u s p r im e i d e a l e x ce pt (x_{0}, \dots, x_{n})}$ .

Remark. Note that $U_{i} = {[z_{0}, \dots, z_{i}, \dots, z_{n}] \in P^{k} : z_{i} \neq = 0} = {[z_{0} / z_{i} : \dots : 1 : \dots : z_{n} / z_{i}] \in P^{k}}$ , and there is a $1$ - $1$ correspondence $U_{i} \leftrightarrow k^{n}$ . Then we can get a homogeneous polynomial from a polynomial, and get a projective algebraic set from an affine algebraic set. For example, $V = {x_{1} x_{2} + x_{0}^{2} = 0} \subseteq P^{2}$ , and take $u = x_{1} / x_{0}$ and $v = x_{2} / x_{0}$ . Then $V ∣_{U_{0}} ≃ {uv + 1 = 0}$ .

Algebraic Sets vs. Varieties: Two Conventions (Concise)

Convention 1 (Common): Variety = Irreducible Algebraic Set

Algebraic Set: Zero locus of polynomials (can be reducible).

Variety: Irreducible algebraic set.

Convention 2 (Less Common): Variety = Algebraic Set

Variety: Zero locus of polynomials (can be reducible or irreducible).

Irreducible Variety: Used specifically for irreducible cases.

Key Point for Convention 2: Under this convention, “algebraic set” and “variety” are synonymous.

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1.2 Irreducible Algebraic Sets

Projective Algebraic Set

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