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In mathematics, specifically abstract algebra, a commutative Artinian ring (sometimes Artin ring) is a commutative ring that satisfies the descending chain condition on ideals; that is, there is no infinite descending sequence of ideals. Artinian rings are named after Emil Artin, who first discovered that the descending chain condition for ideals simultaneously generalizes finite rings and rings that are finite-dimensional vector spaces over fields. The definition of Artinian rings may be restated by interchanging the descending chain condition with an equivalent notion: the minimum condition.

In the noncommutative setting, a ring is left Artinian if it satisfies the descending chain condition on left ideals, right Artinian if it satisfies the descending chain condition on right ideals, and Artinian or two-sided Artinian if it is both left and right Artinian^[1]. For commutative rings the left and right definitions coincide, but in general they are distinct from each other.

The Artin–Wedderburn theorem characterizes every simple Artinian ring as a ring of matrices over a division ring. This implies that a simple ring is left Artinian if and only if it is right Artinian.

The same definition and terminology can be applied to modules, with ideals replaced by submodules.

Although the descending chain condition appears dual to the ascending chain condition, in rings it is in fact the stronger condition. Specifically, a consequence of the Akizuki–Hopkins–Levitzki theorem is that a left (resp. right) Artinian ring is automatically a left (resp. right) Noetherian ring. This is not true for general modules; that is, an Artinian module need not be a Noetherian module.

Examples and counterexamples

An integral domain is Artinian if and only if it is a field.
A ring with finitely many, say left, ideals is left Artinian. In particular, a finite ring (e.g., $\mathbb {Z} /n\mathbb {Z}$ ) is left and right Artinian.
Let k be a field. Then $k[t]/(t^{n})$ is Artinian for every positive integer n.
Similarly, $k[x,y]/(x^{2},y^{3},xy^{2})=k\oplus k\cdot x\oplus k\cdot y\oplus k\cdot xy\oplus k\cdot y^{2}$ is an Artinian ring with maximal ideal $(x,y)$ .
If I is a nonzero ideal of a Dedekind domain A, then $A/I$ is a principal Artinian ring.^[2]
For each $n\geq 1$ , the full matrix ring $M_{n}(R)$ over a left Artinian (resp. left Noetherian) ring R is left Artinian (resp. left Noetherian).^[3]

The following two are examples of non-Artinian rings.

If R is any ring, then the polynomial ring R[x] is not Artinian, since the ideal generated by $x^{n+1}$ is (properly) contained in the ideal generated by $x^{n}$ for all natural numbers n. In contrast, if R is Noetherian so is R[x] by the Hilbert basis theorem.
The ring of integers $\mathbb {Z}$ is a Noetherian ring but is not Artinian.

Modules over Artinian rings

Let M be a left module over a left Artinian ring. Then the following are equivalent (Hopkins' theorem): (i) M is finitely generated, (ii) M has finite length (i.e., has composition series), (iii) M is Noetherian, (iv) M is Artinian.^[4]

Commutative Artinian rings

Let A be a commutative Noetherian ring with unity. Then the following are equivalent.

A is Artinian.
A is a finite product of commutative Artinian local rings.^[5]
A / nil(A) is a semisimple ring, where nil(A) is the nilradical of A.^{[citation needed]}
Every finitely generated module over A has finite length. (see above)
A has Krull dimension zero.^[6] (In particular, the nilradical is the Jacobson radical since prime ideals are maximal.)
$\operatorname {Spec} A$ is finite and discrete.
$\operatorname {Spec} A$ is discrete.^[7]

Let k be a field and A finitely generated k-algebra. Then A is Artinian if and only if A is finitely generated as k-module.

An Artinian local ring is complete. A quotient and localization of an Artinian ring is Artinian.

Simple Artinian ring

A simple Artinian ring A is a matrix ring over a division ring. Indeed,^[8] let I be a minimal (nonzero) right ideal of A. Then, since $AI$ is a two-sided ideal, $AI=A$ since A is simple. Thus, we can choose $a_{i}\in A$ so that $1\in a_{1}I+\cdots +a_{k}I$ . Assume k is minimal with respect that property. Consider the map of right A-modules:

{\begin{cases}I^{\oplus k}\to A,\\(y_{1},\dots ,y_{k})\mapsto a_{1}y_{1}+\cdots +a_{k}y_{k}\end{cases}}

It is surjective. If it is not injective, then, say, $a_{1}y_{1}=a_{2}y_{2}+\cdots +a_{k}y_{k}$ with nonzero $y_{1}$ . Then, by the minimality of I, we have: $y_{1}A=I$ . It follows:

a_{1}I=a_{1}y_{1}A\subset a_{2}I+\cdots +a_{k}I

,

which contradicts the minimality of k. Hence, $I^{\oplus k}\simeq A$ and thus $A\simeq \operatorname {End} _{A}(A)\simeq M_{k}(\operatorname {End} _{A}(I))$ .

Notes

^ Brešar 2014, p.73
^ Theorem 20.11. of http://math.uga.edu/~pete/integral.pdf Archived 2010-12-14 at the Wayback Machine
^ Cohn 2003, 5.2 Exercise 11
^ Bourbaki, VIII, pg 7
^ Atiyah & Macdonald 1969, Theorems 8.7
^ Atiyah & Macdonald 1969, Theorems 8.5
^ Atiyah & Macdonald 1969, Ch. 8, Exercise 2.
^ Milnor, John Willard (1971), Introduction to algebraic K-theory, Annals of Mathematics Studies, vol. 72, Princeton, NJ: Princeton University Press, p. 144, MR 0349811, Zbl 0237.18005

References

Auslander, Maurice; Reiten, Idun; Smalø, Sverre O. (1995), Representation theory of Artin algebras, Cambridge Studies in Advanced Mathematics, vol. 36, Cambridge University Press, doi:10.1017/CBO9780511623608, ISBN 978-0-521-41134-9, MR 1314422
Bourbaki, Nicolas (2012). Algèbre. Chapitre 8, Modules et anneaux semi-simples. Heidelberg: Springer-Verlag Berlin Heidelberg. ISBN 978-3-540-35315-7.
Charles Hopkins. Rings with minimal condition for left ideals. Ann. of Math. (2) 40, (1939). 712–730.
Atiyah, Michael Francis; Macdonald, I.G. (1969), Introduction to Commutative Algebra, Westview Press, ISBN 978-0-201-40751-8
Cohn, Paul Moritz (2003). Basic algebra: groups, rings, and fields. Springer. ISBN 978-1-85233-587-8.
Brešar, Matej (2014). Introduction to Noncommutative Algebra. Springer. ISBN 978-3-319-08692-7.

[1] Brešar 2014, p.73

[2] Theorem 20.11. of http://math.uga.edu/~pete/integral.pdf Archived 2010-12-14 at the Wayback Machine

[3] Cohn 2003, 5.2 Exercise 11

[4] Bourbaki, VIII, pg 7

[5] Atiyah & Macdonald 1969, Theorems 8.7

[6] Atiyah & Macdonald 1969, Theorems 8.5

[7] Atiyah & Macdonald 1969, Ch. 8, Exercise 2.

[8] Milnor, John Willard (1971), Introduction to algebraic K-theory, Annals of Mathematics Studies, vol. 72, Princeton, NJ: Princeton University Press, p. 144, MR 0349811, Zbl 0237.18005

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-In [[mathematics]], specifically [[abstract algebra]], an '''Artinian ring''' (sometimes '''Artin ring''') is a [[ring (mathematics)|ring]] that satisfies the [[descending chain condition]] on [[ideal (ring theory)|ideals]]; that is, there is no infinite descending sequence of ideals. Artinian rings are named after [[Emil Artin]], who first discovered that the descending chain condition for ideals simultaneously generalizes [[finite ring]]s and rings that are [[dimension (vector space)|finite-dimensional]] [[vector space]]s over [[field (mathematics)|fields]]. The definition of Artinian rings may be restated by interchanging the descending chain condition with an equivalent notion: the [[minimum condition]].
+In [[mathematics]], specifically [[abstract algebra]], a commutative '''Artinian ring''' (sometimes '''Artin ring''') is a [[Commutative  ring|commutative  ring]] that satisfies the [[descending chain condition]] on [[ideal (ring theory)|ideals]]; that is, there is no infinite descending sequence of ideals. Artinian rings are named after [[Emil Artin]], who first discovered that the descending chain condition for ideals simultaneously generalizes [[finite ring]]s and rings that are [[dimension (vector space)|finite-dimensional]] [[vector space]]s over [[field (mathematics)|fields]]. The definition of Artinian rings may be restated by interchanging the descending chain condition with an equivalent notion: the [[minimum condition]].
-A ring is '''left Artinian''' if it satisfies the descending chain condition on left ideals, '''right Artinian''' if it satisfies the descending chain condition on right ideals, and '''Artinian''' or '''two-sided Artinian''' if it is both left and right Artinian.  For [[commutative ring]]s the left and right definitions coincide, but in general they are distinct from each other.
+In the noncommutative setting, a ring is '''left Artinian''' if it satisfies the descending chain condition on left ideals, '''right Artinian''' if it satisfies the descending chain condition on right ideals, and '''Artinian''' or '''two-sided Artinian''' if it is both left and right Artinian<ref>{{harvnb|Brešar|2014|loc=p.73}}</ref>.  For [[commutative ring]]s the left and right definitions coincide, but in general they are distinct from each other.
 The [[Artin–Wedderburn theorem]] characterizes every [[simple ring|simple]] Artinian ring as a [[Matrix ring|ring of matrices]] over a [[division ring]].  This implies that a simple ring is left Artinian [[if and only if]] it is right Artinian.
@@ Line 67: / Line 67: @@
 *{{Citation | last1=Atiyah | first1=Michael Francis | author1-link=Michael Atiyah | last2=Macdonald | first2=I.G. | author2-link=Ian G. Macdonald | title=Introduction to Commutative Algebra | publisher=Westview Press | isbn=978-0-201-40751-8 | year=1969}}
 * {{cite book |last1=Cohn |first1=Paul Moritz |title=Basic algebra: groups, rings, and fields |year=2003 |publisher=Springer |isbn=978-1-85233-587-8 }}
+* {{cite book |last1=Brešar|first1=Matej|title=Introduction to Noncommutative Algebra |year=2014 |publisher=Springer |isbn=978-3-319-08692-7 }}
 [[Category:Ring theory]]