Sufficiently large implies splitting: Difference between revisions

From Groupprops
(Created page with '==Statement== Let <math>G</math> be a finite group, and let <math>d</math> be the exponent of <math>G</math>: in other words, <math>d</math> is the l...')
 
No edit summary
Line 4: Line 4:


Then, <math>k</math> is a [[splitting field]] for <math>G</math>: Every linear representation of <math>G</math> that can be realized over an algebraic extension of <math>k</math> can in fact be realized over <math>k</math>.
Then, <math>k</math> is a [[splitting field]] for <math>G</math>: Every linear representation of <math>G</math> that can be realized over an algebraic extension of <math>k</math> can in fact be realized over <math>k</math>.
==References==
===Textbook references===
* {{booklink-proved|Serre|94|Corollary to Theorem 24, Section 12.3}}

Revision as of 20:46, 10 April 2009

Statement

Let G be a finite group, and let d be the exponent of G: in other words, d is the least common multiple of the orders of all elements of G. Suppose k is a sufficiently large field for G: k is a field whose characteristic does not divide the order of G, and such that the polynomial xd1 splits completely over k.

Then, k is a splitting field for G: Every linear representation of G that can be realized over an algebraic extension of k can in fact be realized over k.

References

Textbook references

  • Linear representations of finite groups by Jean-Pierre Serre, 10-digit ISBN 0287901906 (English), ISBN 3540901906 (French), Page 94, Corollary to Theorem 24, Section 12.3, More info