Unique factorization and Noetherian implies every prime ideal is generated by finitely many prime elements: Difference between revisions

Statement

Suppose ${\displaystyle R}$ is a unique factorization domain that is also a Noetherian ring; in particular, ${\displaystyle R}$ is a Noetherian unique factorization domain. Then, every prime ideal in ${\displaystyle R}$ is generated by finitely many prime elements, in other words, it can be expressed as a finitely generated ideal where all the elements of the generating set are prime elements.

Related facts

• Unique factorization implies every nonzero prime ideal contains a prime element
• Unique factorization and one-dimensional iff principal ideal
• Unique factorization and finite-dimensional implies every prime ideal is generated by a set of primes of size at most the dimension

Proof

Given: A unique factorization domain ${\displaystyle R}$. A prime ideal ${\displaystyle P}$ of ${\displaystyle R}$.

To prove: ${\displaystyle P=(p_{1},p_{2},\dots ,p_{n})}$ for primes ${\displaystyle p_{i}}$ and some nonnegative integer ${\displaystyle n}$.

Proof:

1. We do the construction inductively. Suppose we have a collection of pairwise distinct primes ${\displaystyle p_{1},p_{2},\dots ,p_{i}}$ in ${\displaystyle P}$ (${\displaystyle i}$ could be zero, which is covered in the general case, but can also be proved separately as shown in fact (1)). We show that if ${\displaystyle (p_{1},p_{2},\dots ,p_{i})\neq P}$, there exists a prime ${\displaystyle p_{i+1}\in P\setminus \{p_{1},p_{2},\dots ,p_{i}\}}$:
   1. For this, pick ${\displaystyle a\in P\setminus (p_{1},p_{2},\dots ,p_{i})}$. Clearly, ${\displaystyle a}$ has a prime factorization in ${\displaystyle R}$ (use fact (2) to argue that the irreducible factors are indeed prime).
   2. Since ${\displaystyle P}$ is prime, at least one of the prime factors of ${\displaystyle a}$ is in ${\displaystyle P}$. Call this prime factor ${\displaystyle p_{i+1}}$.
   3. If ${\displaystyle p_{i+1}\in (p_{1},p_{2},\dots ,p_{i})}$, then ${\displaystyle a\in (p_{1},p_{2},\dots ,p_{i})}$ because ${\displaystyle a}$ is a multiple of ${\displaystyle p_{i+1}}$. This contradicts the way we picked ${\displaystyle a}$. Thus, ${\displaystyle p_{i+1}\in P\setminus (p_{1},p_{2},\dots ,p_{i})}$, and we have the required induction step.
2. We thus have, for the prime ideal ${\displaystyle P}$, a strictly increasing chain of ideals ${\displaystyle (p_{1})\subset (p_{1},p_{2})\subset \dots }$ with ${\displaystyle p_{i}}$ prime, that terminates at ${\displaystyle p_{n}}$ if and only if ${\displaystyle (p_{1},p_{2},\dots ,p_{n})=P}$. Since ${\displaystyle R}$ is Noetherian, the sequence must terminate at some finite stage, forcing ${\displaystyle P=(p_{1},p_{2},\dots ,p_{n})}$ for some nonnegative integer ${\displaystyle n}$.