Principal ideal ring implies one-dimensional

This article gives the statement and possibly, proof, of an implication relation between two commutative unital ring properties. That is, it states that every commutative unital ring satisfying the first commutative unital ring property (i.e., principal ideal ring) must also satisfy the second commutative unital ring property (i.e., one-dimensional ring)
View all commutative unital ring property implications | View all commutative unital ring property non-implications |Get help on looking up commutative unital ring property implications/non-implications
Get more facts about principal ideal ring|Get more facts about one-dimensional ring

Statement

Verbal statement

Any principal ideal ring is a one-dimensional ring: its Krull dimension is at most one. In other words, it cannot have an ascending chain of prime ideals of length more than one.

Statement with symbols

Suppose ${\displaystyle R}$ is a principal ideal ring. Then, we cannot have a strictly ascending chain of prime ideals in ${\displaystyle R}$ of the form:

${\displaystyle P_0\subset P_1\subset P_2}$

Related facts

• PID implies one-dimensional
• Unique factorization and one-dimensional iff principal ideal
• Unique factorization implies every nonzero prime ideal contains a prime element
• 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 principal ideal ring ${\displaystyle R}$.

To prove: There cannot be three prime ideals ${\displaystyle P_0\subset P_1\subset P_2}$ with the containment strict.

Proof: Suppose we have such prime ideals. Since ${\displaystyle R}$ is a principal ideal ring, we can choose generators ${\displaystyle p_1,p_2}$ of ${\displaystyle P_1,P_2}$. We then have ${\displaystyle p_1=q_{12}{p}_2}$ for some ${\displaystyle q_{12}\in R}$. Since ${\displaystyle P_1}$ is prime and ${\displaystyle p_2\notin P_1}$, we have ${\displaystyle q_{12}\in P_1}$. Thus, ${\displaystyle q_{12}=p_{1}x}$ for some ${\displaystyle x\in R}$. This yields:

${\displaystyle p_1=p_{1}x{p}_2}$

which simplifies to:

${\displaystyle p_1(1-x{p}_2)=0}$.

Since ${\displaystyle 0\in P_0}$ and ${\displaystyle P_0}$ is prime, we have that either ${\displaystyle p_1\in P_0}$ (not possible since the containment is strict) or ${\displaystyle x{p}_2=1}$ (not possible since ${\displaystyle P_2}$ is a proper ideal). Thus, we have the required contradiction.