Principal ideal explained

in a ring

that is generated by a single element

through multiplication by every element of

The term also has another, similar meaning in order theory, where it refers to an (order) ideal in a poset

generated by a single element

x\inP,

which is to say the set of all elements less than or equal to

The remainder of this article addresses the ring-theoretic concept.

Definitions

a left principal ideal of

is a subset of

given by

Ra=\{ra:r\inR\}

for some element

a right principal ideal of

is a subset of

given by

aR=\{ar:r\inR\}

for some element

a two-sided principal ideal of

is a subset of

given by

RaR=\{r₁as₁+\ldots+r_nas_n:r_1,s_1,\ldots,r_n,s_n\inR\}

for some element

namely, the set of all finite sums of elements of the form

ras.

While this definition for two-sided principal ideal may seem more complicated than the others, it is necessary to ensure that the ideal remains closed under addition.

is a commutative ring with identity, then the above three notions are all the same.In that case, it is common to write the ideal generated by

\langlea\rangle

(a).

Examples of non-principal ideal

Not all ideals are principal.For example, consider the commutative ring

C[x,y]

of all polynomials in two variables

and

with complex coefficients. The ideal

\langlex,y\rangle

generated by

and

which consists of all the polynomials in

C[x,y]

that have zero for the constant term, is not principal. To see this, suppose that

were a generator for

\langlex,y\rangle.

Then

and

would both be divisible by

which is impossible unless

is a nonzero constant.But zero is the only constant in

\langlex,y\rangle,

so we have a contradiction.

In the ring

Z[\sqrt{-3}]=\{a+b\sqrt{-3}:a,b\inZ\},

the numbers where

a+b

is even form a non-principal ideal. This ideal forms a regular hexagonal lattice in the complex plane. Consider

(a,b)=(2,0)

and

(1,1).

These numbers are elements of this ideal with the same norm (two), but because the only units in the ring are

and

-1,

they are not associates.

Related definitions

A ring in which every ideal is principal is called principal, or a principal ideal ring. A principal ideal domain (PID) is an integral domain in which every ideal is principal. Any PID is a unique factorization domain; the normal proof of unique factorization in the integers (the so-called fundamental theorem of arithmetic) holds in any PID.

Examples of principal ideal

The principal ideals in

are of the form

\langlen\rangle=nZ.

In fact,

is a principal ideal domain, which can be shown as follows. Suppose

I=\langlen_1,n_2,\ldots\rangle

where

n_{1 ≠}0,

and consider the surjective homomorphisms

Z/\langlen_1\rangle → Z/\langlen_1,n_2\rangle → Z/\langlen_1,n_2,n_{3\rangle →} … .

Since

Z/\langlen_1\rangle

is finite, for sufficiently large

we have

Z/\langlen_1,n_2,\ldots,n_k\rangle=Z/\langlen_1,n_2,\ldots,n_k+1\rangle= … .

Thus

I=\langlen_1,n_2,\ldots,n_k\rangle,

which implies

is always finitely generated. Since the ideal

\langlea,b\rangle

generated by any integers

and

is exactly

\langlegcd(a,b)\rangle,

by induction on the number of generators it follows that

is principal.

However, all rings have principal ideals, namely, any ideal generated by exactly one element. For example, the ideal

\langlex\rangle

is a principal ideal of

C[x,y],

and

\langle\sqrt{-3}\rangle

is a principal ideal of

Z[\sqrt{-3}].

In fact,

\{0\}=\langle0\rangle

and

R=\langle1\rangle

are principal ideals of any ring

Properties

Any Euclidean domain is a PID; the algorithm used to calculate greatest common divisors may be used to find a generator of any ideal.More generally, any two principal ideals in a commutative ring have a greatest common divisor in the sense of ideal multiplication.In principal ideal domains, this allows us to calculate greatest common divisors of elements of the ring, up to multiplication by a unit; we define

\gcd(a,b)

to be any generator of the ideal

\langlea,b\rangle.

we may also ask, given a non-principal ideal

whether there is some extension

such that the ideal of

generated by

is principal (said more loosely,

becomes principal in

).This question arose in connection with the study of rings of algebraic integers (which are examples of Dedekind domains) in number theory, and led to the development of class field theory by Teiji Takagi, Emil Artin, David Hilbert, and many others.

The principal ideal theorem of class field theory states that every integer ring

(i.e. the ring of integers of some number field) is contained in a larger integer ring

which has the property that every ideal of

becomes a principal ideal of

In this theorem we may take

to be the ring of integers of the Hilbert class field of

; that is, the maximal unramified abelian extension (that is, Galois extension whose Galois group is abelian) of the fraction field of

and this is uniquely determined by

Krull's principal ideal theorem states that if

is a Noetherian ring and

is a principal, proper ideal of

then

has height at most one.

References

Book: Gallian, Joseph A. . 2017. 9th. Contemporary Abstract Algebra. Cengage Learning. 978-1-305-65796-0.

Principal ideal explained

Definitions

Examples of non-principal ideal

Related definitions

Examples of principal ideal

Properties

See also

References