A directly irreducible ring is a ring which cannot be written as the direct sum of two non-zero rings.
A subdirectly irreducible ring is a ring with a unique, non-zero minimum two-sided ideal.
"Meet-irreducible" rings are referred to as "irreducible rings" in commutative algebra. This article adopts the term "meet-irreducible" in order to distinguish between the several types being discussed.
Meet-irreducible rings play an important part in commutative algebra, and directly irreducible and subdirectly irreducible rings play a role in the general theory of structure for rings. Subdirectly irreducible algebras have also found use in number theory.
The terms "meet-reducible", "directly reducible" and "subdirectly reducible" are used when a ring is not meet-irreducible, or not directly irreducible, or not subdirectly irreducible, respectively.
The following conditions are equivalent for a commutative ring R:
R is meet-irreducible;
the zero ideal in R is irreducible, i.e. the intersection of two non-zero ideals of A always is non-zero.
The following conditions are equivalent for a commutative ring R:
The following conditions are equivalent for a ring R:
R is subdirectly irreducible;
when R is written as a subdirect product of rings, then one of the projections of R onto a ring in the subdirect product is an isomorphism;
The intersection of all non-zero ideals of R is non-zero.
Examples and properties
If R is subdirectly irreducible or meet-irreducible, then it is also directly irreducible, but the converses are not true.
All integral domains are meet-irreducible, but not all integral domains are subdirectly irreducible (e.g. Z). In fact, a commutative ring is a domain if and only if it is both meet-irreducible and reduced.
The quotient ringZ/4Z is a ring which has all three senses of irreducibility, but it is not a domain. Its only proper ideal is 2Z/4Z, which is maximal, hence prime. The ideal is also minimal.
The direct product of two non-zero rings is never directly irreducible, and hence is never meet-irreducible or subdirectly irreducible. For example, in Z × Z the intersection of the non-zero ideals {0} × Z and Z × {0} is equal to the zero ideal {0} × {0}.
Commutative meet-irreducible rings play an elementary role in algebraic geometry, where this concept is generalized to the concept of an irreducible scheme.
July 28, 2023
irreducible, ring, this, article, does, cite, sources, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, april, 2013, learn, when, remov. This article does not cite any sources Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Irreducible ring news newspapers books scholar JSTOR April 2013 Learn how and when to remove this template message In mathematics especially in the field of ring theory the term irreducible ring is used in a few different ways A meet irreducible ring is a ring in which the intersection of two non zero ideals is always non zero A directly irreducible ring is a ring which cannot be written as the direct sum of two non zero rings A subdirectly irreducible ring is a ring with a unique non zero minimum two sided ideal Meet irreducible rings are referred to as irreducible rings in commutative algebra This article adopts the term meet irreducible in order to distinguish between the several types being discussed Meet irreducible rings play an important part in commutative algebra and directly irreducible and subdirectly irreducible rings play a role in the general theory of structure for rings Subdirectly irreducible algebras have also found use in number theory This article follows the convention that rings have multiplicative identity but are not necessarily commutative Definitions EditThe terms meet reducible directly reducible and subdirectly reducible are used when a ring is not meet irreducible or not directly irreducible or not subdirectly irreducible respectively The following conditions are equivalent for a commutative ring R R is meet irreducible the zero ideal in R is irreducible i e the intersection of two non zero ideals of A always is non zero The following conditions are equivalent for a commutative ring R R is meet irreducible R possesses exactly one minimal prime ideal this prime ideal may be the zero ideal the spectrum of R is irreducible The following conditions are equivalent for a ring R R is directly irreducible R has no central idempotents except for 0 and 1 The following conditions are equivalent for a ring R R is subdirectly irreducible when R is written as a subdirect product of rings then one of the projections of R onto a ring in the subdirect product is an isomorphism The intersection of all non zero ideals of R is non zero Examples and properties EditIf R is subdirectly irreducible or meet irreducible then it is also directly irreducible but the converses are not true All integral domains are meet irreducible but not all integral domains are subdirectly irreducible e g Z In fact a commutative ring is a domain if and only if it is both meet irreducible and reduced The quotient ring Z 4Z is a ring which has all three senses of irreducibility but it is not a domain Its only proper ideal is 2Z 4Z which is maximal hence prime The ideal is also minimal The direct product of two non zero rings is never directly irreducible and hence is never meet irreducible or subdirectly irreducible For example in Z Z the intersection of the non zero ideals 0 Z and Z 0 is equal to the zero ideal 0 0 Commutative directly irreducible rings are connected rings that is their only idempotent elements are 0 and 1 Generalizations EditCommutative meet irreducible rings play an elementary role in algebraic geometry where this concept is generalized to the concept of an irreducible scheme Retrieved from https en wikipedia org w index php title Irreducible ring amp oldid 1144239022, wikipedia, wiki, book, books, library,
