Spectrum is sober: Difference between revisions

Revision as of 20:46, 15 March 2008

Statement

Topological statement

The spectrum of a commutative unital ring, with the usual topology, is a sober space: in other words, any irreducible closed subset is the closure of a one-point subset.

Ring-theoretic statement

Any irreducible closed subset in the spectrum of a commutative unital ring corresponds to a prime ideal under the Galois correspondece between a ring and its spectrum.

Proof

Given: A commutative unital ring $R$ , its spectrum $Spec(R)$ , an irreducible closed subset $A$ of $Spec(R)$ . Let ${\mathcal {Z}}(I)$ , for an ideal $I$ , denote the set of prime ideals containing $I$ .

To prove: There is a prime ideal $P$ such that $A$ is precisely the set of all prime ideals containing $P$

Proof: By definition of closed set, there exists a unique radical ideal $P$ such that $A$ is precisely the set of prime ideals containing $P$ . We need to show that $P$ is in fact prime. Suppose not. Then there exist ideals $J$ and $K$ of $R$ such that $JK\subseteq P$ but neither $J$ nor $K$ is contained in $P$ .

We now argue the following:

${\mathcal {Z}}(J)\cup {\mathcal {Z}}(K)={\mathcal {Z}}(P)=A$ : If $Q$ is a prime ideal containing $P$ , then $JK\subset Q$ . But primeness of $Q$ forces $J\subset Q$ or $K\subset Q$ , thus forcing $Q\in {\mathcal {Z}}(J)\cup {\mathcal {Z}}(K)$ .
Both are closed subsets: This is by definition
Both are proper subsets: If ${\mathcal {Z}}(J)={\mathcal {Z}}(P)$ , then $P$ being a radical ideal, must be the radical of $J$ . But that'd force $J\subset P$ , a contradiction to assumption. Hence ${\mathcal {Z}}(J)$ must be a proper subset of $A$ . A similar argument holds for ${\mathcal {Z}}(K)$ .

Thus, we have expressed $A$ as a union of two proper closed subsets, a contradiction. Hence, our original assumption was false, and $P$ is prime.

@@ Line 1: / Line 1: @@
 ==Statement==
+===Topological statement===
 The [[spectrum of a commutative unital ring]], with the usual topology, is a [[sober space]]: in other words, any irreducible closed subset is the closure of a one-point subset.
+===Ring-theoretic statement===
+Any irreducible closed subset in the spectrum of a commutative unital ring corresponds to a [[prime ideal]] under the [[Galois correspondece between a ring and its spectrum]].
+==Proof==
+''Given'': A commutative unital ring <math>R</math>, its spectrum <math>Spec(R)</math>, an irreducible closed subset <math>A</math> of <math>Spec(R)</math>. Let <math>\mathcal{Z}(I)</math>, for an ideal <math>I</math>, denote the set of prime ideals containing <math>I</math>.
+''To prove'': There is a [[prime ideal]] <math>P</math> such that <math>A</math> is precisely the set of all prime ideals containing <math>P</math>
+''Proof'': By definition of closed set, there exists a unique radical ideal <math>P</math> such that <math>A</math> is precisely the set of prime ideals containing <math>P</math>. We need to show that <math>P</math> is in fact prime. Suppose not. Then there exist ideals <math>J</math> and <math>K</math> of <math>R</math> such that <math>JK \subseteq P</math> but neither <math>J</math> nor <math>K</math> is contained in <math>P</math>.
+We now argue the following:
+* <math>\mathcal{Z}(J) \cup \mathcal{Z}(K) = \mathcal{Z}(P) = A</math>: If <math>Q</math> is a prime ideal containing <math>P</math>, then <math>JK \subset Q</math>. But primeness of <math>Q</math> forces <math>J \subset Q</math> or <math>K \subset Q</math>, thus forcing <math>Q \in \mathcal{Z}(J) \cup \mathcal{Z}(K)</math>.
+* Both are closed subsets: This is by definition
+* Both are proper subsets: If <math>\mathcal{Z}(J) = \mathcal{Z}(P)</math>, then <math>P</math> being a radical ideal, must be the radical of <math>J</math>. But that'd force <math>J \subset P</math>, a  contradiction to assumption. Hence <math>\mathcal{Z}(J)</math> must be a proper subset of <math>A</math>. A similar argument holds for <math>\mathcal{Z}(K)</math>.
+Thus, we have expressed <math>A</math> as a union of two proper closed subsets, a ''contradiction''. Hence, our original assumption was false, and <math>P</math> is prime.