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3.2 Principal Ideal Domains

Definition 3.2.1 A principal ideal domain (PID) is an integral domain in which every ideal is principal.

Lemma 3.2.2 Z is a PID.

NOTE: Showing that Z is a PID means showing that if I is an ideal of Z, then there is some integer n for which I consists of all the integer multiples of n.

Proof: Suppose that I Z is an ideal. If I = {0} then I is the principal ideal generated by 0 and I is principal. If I ≠ {0} then I contains both positive and negative elements. Let m be the least positive element of I. We will show that I = (m).

Certainly (m) I as I must contain all integer mulitples of m. On the other hand suppose a ∈ I. Then we can write

a = mq + r

where q ∈ Z and Principal Ideal Domain - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET Then r = a - qm. Since a ∈ I and -qm ∈ I, this means r ∈ I. It follows that r = 0, otherwise we have a contradiction to the choice of m. Thus a = qm and a ∈ (m). We conclude I = (m).

Note: In fact every subring of Z is an ideal - think about this.

Lemma 3.2.3 Let F be afield. Then the polynomial ring F[x] is a PID.

NOTE: Recall that F[x] has one important property in common with Z, namely a division algorithm. This is the key to showing that F[x] is a PID.

Proof: Let I F[x] be an ideal. If I = {0} then I = (0) and I is principal. If I ≠ {0}, let f(x) be a polynomial of minimal degree m in I. Then (f(x)) I since every polynomial multiple of f(x) is in I.

We will show that I = (f (x)). To see this suppose g(x) ∈ I. Then

g(x) = f(x)q(x) + r(x)

where q(x),r(x) ∈ F[x] and r(x) = 0 or deg(r(x)) < m. Now

r(x) = g(x) — f(x)q(x)

and so r(x) ∈ I. It follows that r(x) = 0 otherwise r(x) is a polynomial in I of degree strictly less than m, contrary to the choice of f(x).

Thus g(x) = f(x)q(x), g(x) ∈ (f(x)) and I = (f(x)).

Question for the Seminar: If R is a ring (not a field) it is not always true that R[x] is a PID.

Find an example of a non-principal ideal in Z[x].

The document Principal Ideal Domain - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET is a part of the Mathematics Course Mathematics for IIT JAM, GATE, CSIR NET, UGC NET.
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FAQs on Principal Ideal Domain - Ring Theory, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is a principal ideal domain?
Ans. A principal ideal domain (PID) is a type of commutative ring in which every ideal is generated by a single element. In other words, for every ideal in a PID, there exists an element such that the ideal consists of all possible products of that element with any other element in the ring.
2. How does a principal ideal domain differ from other types of rings?
Ans. A principal ideal domain is a more specific type of ring compared to other types such as integral domains or Euclidean domains. The key difference is that in a principal ideal domain, every ideal can be generated by a single element, whereas in other types of rings, this may not always be the case.
3. Are all principal ideal domains also Euclidean domains?
Ans. No, not all principal ideal domains are also Euclidean domains. While every Euclidean domain is a principal ideal domain, the converse is not true. Euclidean domains have an additional property that allows for a division algorithm, which is not necessarily present in all principal ideal domains.
4. Can you provide an example of a principal ideal domain?
Ans. One example of a principal ideal domain is the ring of integers, denoted by Z. In this ring, every ideal can be generated by a single integer. For example, the ideal generated by the number 2 consists of all multiples of 2, including both positive and negative integers.
5. How are principal ideal domains useful in mathematics?
Ans. Principal ideal domains are important in various areas of mathematics, particularly in algebra and number theory. They provide a rich structure for studying properties of ideals, factorization of elements, and divisibility. Principal ideal domains also serve as a key tool in proving many theorems and results in these areas of mathematics.
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