Maximal ideal

This article is about a basic definition in commutative algebra. View a complete list of basic definitions in commutative algebra

This article defines a property of an ideal in a commutative unital ring |View other properties of ideals in commutative unital rings

This property of an ideal in a ring is equivalent to the property of the quotient ring being a/an: field | View other quotient-determined properties of ideals in commutative unital rings

Definition

Symbol-free definition

An ideal in a commutative unital ring (or more generally, in any commutative ring) is termed maximal if it is proper (not the whole ring) and it satisfies the following equivalent conditions:

There is no ideal of the ring properly in between this ideal and the whole ring
The quotient of the ring by this ideal is a field
The natural action of $R$ on $R/M$ makes $R/M$ into a simple $R$ -module.

Definition with symbols

An ideal $M$ in a commutative ring $R$ is termed maximal if it satisfies the following equivalent conditions:

For any ideal $J$ such that $M$ ≤ $J$ ≤ $R$ , $J$ is equal either to $M$ or to $R$ .
The quotient ring $R/M$ is a field.

Relation with other properties

Weaker properties

Prime ideal: For proof of the implication, refer Maximal implies prime and for proof of its strictness (i.e. the reverse implication being false) refer prime not implies maximal
Radical ideal
Intersection of maximal ideals

Metaproperties

Intersection-closedness

This property of ideals in commutative unital rings is not closed under taking arbitrary intersections; in other words, an arbitrary intersection of ideals with this property need not have this property

Template:Not intringcondn ideal

Effect of property operators

The intersection-closure

Applying the intersection-closure to this property gives: intersection of maximal ideals

External links

Definition links