Krull intersection theorem for modules

This article defines a result where the base ring (or one or more of the rings involved) is Noetherian
View more results involving Noetherianness or Read a survey article on applying Noetherianness

This fact is an application of the following pivotal fact/result/idea: Artin-Rees lemma
View other applications of Artin-Rees lemma OR Read a survey article on applying Artin-Rees lemma

This fact is an application of the following pivotal fact/result/idea: Nakayama's lemma
View other applications of Nakayama's lemma OR Read a survey article on applying Nakayama's lemma

Statement

Let ${\displaystyle R}$ be a Noetherian ring and ${\displaystyle I}$ be an ideal inside ${\displaystyle R}$. Suppose ${\displaystyle M}$ is a finitely generated module over ${\displaystyle R}$. Then, we have the following:

1. Let ${\displaystyle N={\displaystyle \bigcap _{j=1}^{\mathrm{\infty }}}{I}^{j}M}$. Then, ${\displaystyle IN=N}$
2. There exists ${\displaystyle r\in I}$ such that ${\displaystyle (1-r)N=0}$

Results used

• Artin-Rees lemma
• Nakayama's lemma

Proof

The intersection equals its product with ${\displaystyle I}$

We first show that the intersection equals its product with ${\displaystyle I}$. This is the step where we se the Artin-Rees lemma.

Let:

${\displaystyle N:={\displaystyle \bigcap _1^{\mathrm{\infty }}}{I}^{j}M}$

Now consider the filtration:

${\displaystyle M\supset IM\supset I^{2}M\supset \dots }$

this is an ${\displaystyle I}$-adic filtration and the underlying ring is Noetherian, hence by the Artin-Rees lemma, the following filtration is also ${\displaystyle I}$-adic:

${\displaystyle N\supset IM\cap N\supset I^{2}M\cap N\supset \dots }$

Since each ${\displaystyle I^{j}M}$ contains ${\displaystyle N}$, the filtration below is the same as the filtration:

${\displaystyle N\supset N\supset N\supset \dots }$

This being ${\displaystyle I}$-adic forces that ${\displaystyle IN=N}$.

Finding the element ${\displaystyle r}$

Since ${\displaystyle IN=N}$, we can find an element ${\displaystyle r\in I}$ such that ${\displaystyle (1-r)N=0}$. This is an application of the Cayley-Hamilton theorem: we first find the Cayley-Hamilton polynomial, then observe that ${\displaystyle 1}$ is a root of the polynomial, and then take the negative of the sum of all coefficients of higher degree terms.

Proving the intersection is trivial for an integral domain

If ${\displaystyle R}$ is an integral domain, and we set ${\displaystyle M=R}$ in the above, we find an element ${\displaystyle r\in I}$ such that ${\displaystyle (1-r)({\bigcap }_j{I}^j)=0}$. Thus ${\displaystyle 1-r}$ is a zero divisor on the intersection. Since ${\displaystyle R}$ is an integral domain, one of these must hold:

• ${\displaystyle 1-r=0}$. This forces ${\displaystyle 1\in I}$, contradicting the assumption that ${\displaystyle I}$ is a proper ideal
• ${\displaystyle {\bigcap }_j{I}^j=0}$

This completes the proof.

Proving that the intersection is trivial for a local ring

In this case, ${\displaystyle I}$ is contained inside the unique maximal ideal ${\displaystyle \mathfrak{m}}$, which is the Jacobson radical. As above, let ${\displaystyle N={\bigcap }_j{I}^j}$. Then, we have ${\displaystyle IN=N}$. Since ${\displaystyle I}$ is contained in the Jacobson radical, this forces ${\displaystyle N=0}$.

References

• ''Dimensionstheorie in Stellenringen by Wolfgang Krull, 1938

Textbook references

• Book:Eisenbud, Page 152