Regular local ring: Difference between revisions

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imported>Giovanni Antonio DiMatteo
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Let <math>A</math> be a [[Noetherian Ring|Noetherian]] [[local ring]] with maximal ideal <math>m</math> and residual field <math>k=A/m</math>.  The following conditions are equivalent:
Let <math>A</math> be a [[Noetherian Ring|Noetherian]] [[local ring]] with maximal ideal <math>m</math> and residual field <math>k=A/m</math>.  The following conditions are equivalent:


# The Krull dimension of <math>A</math> is equal to the dimension of <math>m/m^2</math> as a <math>k</math>-vector space.
# The Krull dimension of <math>A</math> is equal to the dimension of the <math>k</math>-vector space <math>m/m^2</math>.


And when these conditions hold, <math>A</math> is called a regular local ring.  
And when these conditions hold, <math>A</math> is called a regular local ring.  

Revision as of 08:43, 2 December 2007

There are deep connections between algebraic (in fact, scheme-theoretic) notions of smoothness and regularity.


Definition

Let be a Noetherian local ring with maximal ideal and residual field . The following conditions are equivalent:

  1. The Krull dimension of is equal to the dimension of the -vector space .

And when these conditions hold, is called a regular local ring.

Basic Results on Regular Local Rings

One important criterion for regularity is Serre's Criterion, which states that a Noetherian local ring is regular if and only if its global dimension is finite, in which case it is equal to the krull dimension of .

In a paper of Auslander and Buchsbaum published in 1959, it was shown that every regular local ring is a UFD.

Regular Rings

A regular ring is a Noetherian ring such that the localisation at every prime is a regular local ring.