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Difference between revisions of "Artinian"

(New page: We say that a ring or module is '''Artinian''' if the descending chain condition holds for its ideals/submodules. The notion is similar to that of Noetherian rings...)
 
 
Line 1: Line 1:
 
We say that a [[ring]] or [[module]] is '''Artinian'''
 
We say that a [[ring]] or [[module]] is '''Artinian'''
 
if the [[descending chain condition]] holds for its
 
if the [[descending chain condition]] holds for its
[[ideals]]/[[submodules]].  The notion is similar to that
+
[[ideal | ideals]]/[[submodules]].  The notion is similar to that
 
of [[Noetherian]] rings and modules.
 
of [[Noetherian]] rings and modules.
  
 
One might expect Artinian rings to be just as broad and
 
One might expect Artinian rings to be just as broad and
 
diverse a category as Noetherian rings.  However, this
 
diverse a category as Noetherian rings.  However, this
is not the case.
+
is not the case. In fact, Artinian rings are Noetherian but the converse does not hold.
  
 +
'''Theorem.''' Let <math>A</math> be an Artinian ring. Then every prime ideal of <math>A</math> is maximal. Thus <math>\dim A = 0</math> (the [[Krull dimension]] of <math>A</math> is <math>0</math>).
  
 
'''Theorem.'''  Let <math>A</math> be a ring.  Then <math>A</math> is Artinian
 
'''Theorem.'''  Let <math>A</math> be a ring.  Then <math>A</math> is Artinian
 
if and only if <math>A</math> is Noetherian and every element of <math>A</math>
 
if and only if <math>A</math> is Noetherian and every element of <math>A</math>
 
is either [[invertible]] or [[nilpotent]].
 
is either [[invertible]] or [[nilpotent]].
 
<!-- I have a marvellous proof of this theorem in the making,
 
but unfortunately I must eat lunch. -->
 
  
 
However, Artinian ''modules'' are not necessarily
 
However, Artinian ''modules'' are not necessarily

Latest revision as of 21:00, 19 April 2012

We say that a ring or module is Artinian if the descending chain condition holds for its ideals/submodules. The notion is similar to that of Noetherian rings and modules.

One might expect Artinian rings to be just as broad and diverse a category as Noetherian rings. However, this is not the case. In fact, Artinian rings are Noetherian but the converse does not hold.

Theorem. Let $A$ be an Artinian ring. Then every prime ideal of $A$ is maximal. Thus $\dim A = 0$ (the Krull dimension of $A$ is $0$).

Theorem. Let $A$ be a ring. Then $A$ is Artinian if and only if $A$ is Noetherian and every element of $A$ is either invertible or nilpotent.

However, Artinian modules are not necessarily Noetherian. Consider, for example, the Prüfer Group for some prime $p$ as a $\mathbb{Z}$-module (i.e., the additive group of rationals of the form $a/p^k$, modulo $\mathbb{Z}$). Each of its submodules is of the form $(1/p^n)$, for some integer $n \ge 0$. Thus a descending chain of submodules corresponds uniquely to an increasing sequence of nonnegative integers, and vice-versa. Thus every ascending chain must stabilize, but we have the descending chain \[(1/p^0) \supset (1/p^1) \supset (1/p^2) \supset \dotsb .\] This module is therefore Artinian, but not Noetherian.

See also

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