Maximal ideal explained

In mathematics, more specifically in ring theory, a maximal ideal is an ideal that is maximal (with respect to set inclusion) amongst all proper ideals.[1] [2] In other words, I is a maximal ideal of a ring R if there are no other ideals contained between I and R.

Maximal ideals are important because the quotients of rings by maximal ideals are simple rings, and in the special case of unital commutative rings they are also fields.

In noncommutative ring theory, a maximal right ideal is defined analogously as being a maximal element in the poset of proper right ideals, and similarly, a maximal left ideal is defined to be a maximal element of the poset of proper left ideals. Since a one-sided maximal ideal A is not necessarily two-sided, the quotient R/A is not necessarily a ring, but it is a simple module over R. If R has a unique maximal right ideal, then R is known as a local ring, and the maximal right ideal is also the unique maximal left and unique maximal two-sided ideal of the ring, and is in fact the Jacobson radical J(R).

It is possible for a ring to have a unique maximal two-sided ideal and yet lack unique maximal one-sided ideals: for example, in the ring of 2 by 2 square matrices over a field, the zero ideal is a maximal two-sided ideal, but there are many maximal right ideals.

Definition

There are other equivalent ways of expressing the definition of maximal one-sided and maximal two-sided ideals. Given a ring R and a proper ideal I of R (that is IR), I is a maximal ideal of R if any of the following equivalent conditions hold:

There is an analogous list for one-sided ideals, for which only the right-hand versions will be given. For a right ideal A of a ring R, the following conditions are equivalent to A being a maximal right ideal of R:

Maximal right/left/two-sided ideals are the dual notion to that of minimal ideals.

Examples

(2,x)

is a maximal ideal in ring

Z[x]

. Generally, the maximal ideals of

Z[x]

are of the form

(p,f(x))

where

p

is a prime number and

f(x)

is a polynomial in

Z[x]

which is irreducible modulo

p

.

R

whenever there exists an integer

n>1

such that

xn=x

for any

x\inR

.

C[x]

are principal ideals generated by

x-c

for some

c\inC

.

Properties

4Z

is a maximal ideal in

2Z

, but

2Z/4Z

is not a field.

Mn x (Z)

be the ring of all

n x n

matrices over

Z

. This ring has a maximal ideal

Mn x (pZ)

for any prime

p

, but this is not a prime ideal since (in the case

n=2

)

A=diag(1,p)

and

B=diag(p,1)

are not in

Mn x (pZ)

, but

AB=pI2\inMn x (pZ)

. However, maximal ideals of noncommutative rings are prime in the generalized sense below.

Generalization

For an R-module A, a maximal submodule M of A is a submodule satisfying the property that for any other submodule N, implies or . Equivalently, M is a maximal submodule if and only if the quotient module A/M is a simple module. The maximal right ideals of a ring R are exactly the maximal submodules of the module RR.

Unlike rings with unity, a nonzero module does not necessarily have maximal submodules. However, as noted above, finitely generated nonzero modules have maximal submodules, and also projective modules have maximal submodules.

As with rings, one can define the radical of a module using maximal submodules. Furthermore, maximal ideals can be generalized by defining a maximal sub-bimodule M of a bimodule B to be a proper sub-bimodule of M which is contained in no other proper sub-bimodule of M. The maximal ideals of R are then exactly the maximal sub-bimodules of the bimodule RRR.

See also

Notes and References

  1. Book: Dummit . David S. . Foote . Richard M. . Abstract Algebra . . 2004 . 3rd . 0-471-43334-9.
  2. Book: Lang, Serge . Serge Lang

    . Serge Lang . Algebra . . . 2002 . 0-387-95385-X.