Commutative Algebra/Basics on prime and maximal ideals and local rings

Lemma 12.2:

Let ${\displaystyle R}$  be a ring and ${\displaystyle I\leq R}$  an ideal. ${\displaystyle I}$  is prime if and only if ${\displaystyle R/I}$  is an integral domain.

Proof:

${\displaystyle I}$  prime is equivalent to ${\displaystyle ab\in I\Rightarrow a\in I\vee b\in I}$ . This is equivalent to

${\displaystyle ab+I=0+I\Rightarrow a+I=0+I\vee b+I=0+I}$ .${\displaystyle \Box }$ 

Proof:

Order all ideals of ${\displaystyle R}$  not intersecting ${\displaystyle S}$  by set inclusion, and let a chain

${\displaystyle I_{1}\subseteq I_{2}\subseteq \cdots \subseteq I_{k}\subseteq \cdots }$ 

be given. The ideal

${\displaystyle I:=\bigcup _{k\in \mathbb {N} }I_{k}}$ 

(this is an ideal, since ${\displaystyle a,b\in I\Rightarrow a\in I_{m},b\in I_{n}\Rightarrow a,b\in I_{\max\{m,n\}}}$ , hence ${\displaystyle a+b\in I}$ , ${\displaystyle ra\in I}$ ) is an upper bound of the chain, since ${\displaystyle I}$  cannot intersect ${\displaystyle S}$  for else one of the ${\displaystyle I_{k}}$  would intersect ${\displaystyle S}$ . Since the given chain was arbitrary, Zorn's lemma implies the existence of a maximal ideal among all ideals not intersecting ${\displaystyle S}$ . This ideal shall be called ${\displaystyle J}$ ; we prove that it is prime.

Let ${\displaystyle ab\in J}$ , and assume for contradiction that ${\displaystyle a\notin J}$  and ${\displaystyle b\notin J}$ . Then ${\displaystyle \langle a\rangle +J}$ , ${\displaystyle \langle b\rangle +J}$  are strict superideals of ${\displaystyle J}$  and hence intersect ${\displaystyle S}$ , that is,

${\displaystyle s=xa+yj}$ ,

${\displaystyle t=zb+wj'}$ ,

${\displaystyle s,t\in S}$ , ${\displaystyle x,y,z,w\in R}$ , ${\displaystyle j,j'\in J}$ . Then ${\displaystyle S\ni st=xzab+yzbj+xawj'+ywjj'\in J}$ , contradiction.${\displaystyle \Box }$ 

In this section, we want to fix a notiation. Let ${\displaystyle R}$  be a ring and ${\displaystyle I\leq R}$  an ideal. Then we may form the quotient ring ${\displaystyle R/I}$  consisting of the elements of the form ${\displaystyle r+I}$ , ${\displaystyle r\in R}$ . Throughout the book, we shall use the following notation for the canonical projection ${\displaystyle r\mapsto r+I}$ :

Lemma 12.6:

An ideal ${\displaystyle I\leq R}$  is maximal iff ${\displaystyle R/I}$  is a field.

Proof:

A ring is a field if and only if its only proper ideal is the zero ideal. For, in a field, every nonzero ideal contains ${\displaystyle 1}$ , and if ${\displaystyle R}$  is not a field, it contains a non-unit ${\displaystyle a}$ , and then ${\displaystyle \langle a\rangle }$  does not contain ${\displaystyle 1}$ .

By the correspondence given by the correspondence theorem, ${\displaystyle R/I}$  corresponds to ${\displaystyle R}$ , the zero ideal of ${\displaystyle R/I}$  corresponds to ${\displaystyle I}$ , and any ideal strictly in between corresponds to an ideal ${\displaystyle K\leq R}$  such that ${\displaystyle I\subsetneq K\subsetneq R}$ . Hence, ${\displaystyle R/I}$  is a field if and only if there are no proper ideals strictly containing ${\displaystyle I}$ .${\displaystyle \Box }$ 

Lemma 12.7:

Any maximal ideal is prime.

Proof 1:

If ${\displaystyle R}$  is a ring, ${\displaystyle m\leq R}$  maximal, then ${\displaystyle R/m}$  is a field. Hence ${\displaystyle R/m}$  is an integral domain, hence ${\displaystyle m}$  is prime.${\displaystyle \Box }$ 

Proof 2:

Let ${\displaystyle m\leq R}$  be maximal. Let ${\displaystyle ab\in m}$ . Assume ${\displaystyle a,b\notin m}$ . Then ${\displaystyle 1=ra+sn=tb+uk}$  for suitable ${\displaystyle n,k\in m}$ , ${\displaystyle r,s,t,u\in R}$ . But then ${\displaystyle 1=1^{2}=(ra+sn)(tb+uk)=rtab+stbn+rauk+sunk\in m}$ .${\displaystyle \Box }$ 

Proof:

We order the set of all ideals ${\displaystyle J}$  such that ${\displaystyle I\subseteq J}$  and ${\displaystyle J\neq R}$  by inclusion. Let

${\displaystyle J_{1}\subseteq J_{2}\subseteq \cdots \subseteq J_{k}\subseteq \cdots }$ 

be a chain of those ideals. Then set

${\displaystyle J:=\bigcup _{k\in \mathbb {N} }J_{k}}$ .

Clearly, all ${\displaystyle J_{k}}$  are contained within ${\displaystyle J}$ . Since ${\displaystyle I\subseteq J_{1}}$ , ${\displaystyle I\subseteq J}$ . Further, assume ${\displaystyle 1\in J}$ . Then ${\displaystyle 1\in J_{m}}$  for some ${\displaystyle m}$ , contradiction. Hence, ${\displaystyle J}$  is a proper ideal such that ${\displaystyle I\subseteq J}$ , and hence an upper bound for the given chain. Since the given chain was arbitrary, we may apply Zorn's lemma to obtain the existence of a maximal element with respect to inclusion. This ideal must then be maximal, for any proper superideal also contains ${\displaystyle I}$ .${\displaystyle \Box }$ 

Proof: From the correspondence theorem.${\displaystyle \Box }$ 

Proof:

1. ${\displaystyle \Rightarrow }$  2.: Assume ${\displaystyle a}$  and ${\displaystyle b}$  are both non-units. Then ${\displaystyle \langle a\rangle }$  and ${\displaystyle \langle b\rangle }$  are proper ideals of ${\displaystyle R}$  and hence they are contained in some maximal ideal of ${\displaystyle R}$  by theorem 12.7. But there is only one maximal ideal ${\displaystyle m}$  of ${\displaystyle R}$ , and hence ${\displaystyle a,b\in m}$ , thus ${\displaystyle a+b\in m}$ . Maximal ideals can not contain units.

2. ${\displaystyle \Rightarrow }$  3.: The sum of two non-units is a non-unit, and if ${\displaystyle a}$  is a non-unit and ${\displaystyle r\in R}$ , ${\displaystyle ra}$  is a non-unit (for if ${\displaystyle sra=1}$ , ${\displaystyle sr}$  is an inverse of ${\displaystyle a}$ ). Hence, all non-units form an ideal. Any proper ideal of ${\displaystyle R}$  contains only non-units, hence this ideal is maximal.

3. ${\displaystyle \Rightarrow }$  4.: Assume the ${\displaystyle r_{j}}$  are all non-units. Since the non-units form an ideal, ${\displaystyle r_{1}+\cdots +r_{n}}$  is contained in that ideal of non-units, contradiction.

4. ${\displaystyle \Rightarrow }$  5.: Assume ${\displaystyle r}$ , ${\displaystyle 1-r}$  are non-units. Then ${\displaystyle 1=r+(1-r)}$  is a non-unit, contradiction.

5. ${\displaystyle \Rightarrow }$  1.: Let ${\displaystyle m,n\leq R}$  two distinct maximal ideals. Then ${\displaystyle m+n=R}$ , hence ${\displaystyle 1=s+t}$ , ${\displaystyle s\in m}$ , ${\displaystyle t\in n}$ , that is, ${\displaystyle s=1-t}$ . ${\displaystyle t}$  is not a unit, so ${\displaystyle 1-t=s}$  is, contradiction.${\displaystyle \Box }$ 

In chapter 9, we had seen how to localise a ring at a multiplicatively closed subset ${\displaystyle S}$ . An important special case is ${\displaystyle S=R\setminus p}$ , where ${\displaystyle p}$  is a prime ideal.

Lemma 12.12:

Let ${\displaystyle p\leq R}$  be a prime ideal of a ring. Then ${\displaystyle S:=R\setminus p\subseteq R}$  is multiplicatively closed.

Proof: Let ${\displaystyle a,b\notin p}$ . Then ${\displaystyle ab}$  can't be in ${\displaystyle p}$ , hence ${\displaystyle ab\in S}$ .${\displaystyle \Box }$ 

Theorem 12.14:

Let ${\displaystyle R}$  be a ring, ${\displaystyle p\leq R}$  be prime. ${\displaystyle R_{p}}$  is a local ring.

Proof:

Set ${\displaystyle S:=R\setminus p}$ , then ${\displaystyle R_{p}=S^{-1}R}$ . Set

${\displaystyle m:=\{r/s|r\in p,s\in S\}\subseteq S^{-1}R}$ .

All elements of ${\displaystyle m}$  are non-units, and all elements of ${\displaystyle R_{p}\setminus m}$  are of the form ${\displaystyle r'/t}$ , ${\displaystyle r'\notin p}$ , ${\displaystyle t\in S}$  and thus are units. Further, ${\displaystyle m}$  is an ideal since ${\displaystyle p}$  is and by definition of addition and multiplication in ${\displaystyle S^{-1}R}$  and since ${\displaystyle S}$  is multiplicatively closed. Hence ${\displaystyle R_{p}}$  is a local ring.${\displaystyle \Box }$ 

This finally explains why we speak of localisation.