proof that a domain is Dedekind if its ideals are products of primes

We show that for an integral domain $R$, the following are equivalent.

1. 1.

   $R$ is a Dedekind domain.

2. 2.

   every nonzero proper ideal is a product of maximal ideals.

3. 3.

   every nonzero proper ideal is a product of prime ideals.

For the equivalence of 1 and 2 see proof that a domain is Dedekind if its ideals are products of maximals. Also, as every maximal ideal is prime, it is immediate that 2 implies 3. So, we just need to consider the case where 3 is satisfied and show that 2 follows, for which it enough to show that every nonzero prime ideal is maximal.

We first suppose that $𝔭$ is an invertible (http://planetmath.org/FractionalIdeal) prime ideal and show that it is maximal. To do this it is enough to show that any $a\in R\setminus 𝔭$ gives $𝔭+(a)=R$. First, we have the following inclusions,

$$𝔭⊊𝔭+(a^2)\subseteq 𝔭+(a).$$

Then, consider the prime factorizations

	$𝔭+(a)={𝔭}_1\mathrm{\cdots }{𝔭}_m,$		(1)
	$𝔭+(a^2)={𝔮}_1\mathrm{\cdots }{𝔮}_n.$		(2)

We write $\overline{a}$ for the image of $a$ under the natural homorphism (http://planetmath.org/NaturalHomomorphism) $R\to R/𝔭$ and $\overline{𝔞}$ for the image of any ideal $𝔞$. Equations (1) and (2) give

$${\overline{𝔮}}_1\mathrm{\cdots }{\overline{𝔮}}_n={(\overline{a})}^2={({\overline{𝔭}}_1\mathrm{\cdots }{\overline{𝔭}}_m)}^2.$$

(3)

As $𝔭$ is strictly contained in $𝔭+(a)$ and $𝔭+(a^2)$, it must also be strictly contained in ${𝔭}_k$ and ${𝔮}_k$. So, ${\overline{𝔭}}_k,{\overline{𝔮}}_k$ are nonzero prime ideals, and by uniqueness of prime factorization (see, prime ideal factorization is unique) Equation (3) gives $n=2m$ and ${\overline{𝔭}}_k={\overline{𝔮}}_k={\overline{𝔮}}_{k+m}$, after reordering of the factors. So ${𝔭}_k={𝔮}_k={𝔮}_{k+m}$ and,

$$𝔭+(a^2)={𝔮}_1\mathrm{\cdots }{𝔮}_n={\left({𝔭}_1\mathrm{\cdots }{𝔭}_m\right)}^2={\left(𝔭+(a)\right)}^2={𝔭}^2+a𝔭+(a^2).$$

(4)

Then, $a\notin 𝔭$ gives $𝔭\cap (a^2)\subseteq a𝔭$ and taking the intersection of both sides of (4) with $𝔭$,

$$𝔭={𝔭}^2+a𝔭+𝔭\cap (a^2)\subseteq {𝔭}^2+a𝔭=\left(𝔭+(a)\right)𝔭.$$

But $𝔭$ was assumed to be invertible, and can be cancelled giving $R\subseteq 𝔭+(a)$, showing that $𝔭$ is maximal.

Now let $𝔭$ be any prime ideal and $a\in 𝔭\setminus \{0\}$. Factoring into a product of primes

$${𝔭}_1\mathrm{\cdots }{𝔭}_n=(a)\subseteq 𝔭,$$

(5)

each of the ${𝔭}_k$ is invertible and, by the above argument, must be maximal. Finally, as $𝔭$ is prime, (5) gives ${𝔭}_k\subseteq 𝔭$ for some $k$, so $𝔭={𝔭}_k$ is maximal.