07-401/Class Notes for March 7: Difference between revisions

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'''Corollary.''' In this case, <math>F(a)</math> depends only on <math>p</math>.
'''Corollary.''' In this case, <math>F(a)</math> depends only on <math>p</math>.

'''Corollary.''' If <math>p\in F[x]</math> irreducible over <math>F</math>, <math>\phi:F\to F'</math> an isomorphism, <math>a</math> a root of <math>p</math> (in some <math>E/F</math>), <math>a'</math> a root of <math>\phi(p)</math> in some <math>E'/F'</math>, then <math>F[a]\cong F'[a']</math>.


===Splitting Fields===
===Splitting Fields===
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'''Example.''' Factor <math>x^2+x+2\in{\mathbb Z}_3[x]</math> within its splitting field <math>{\mathbb Z}_3[x]/\langle x^2+x+2\rangle</math>.
'''Example.''' Factor <math>x^2+x+2\in{\mathbb Z}_3[x]</math> within its splitting field <math>{\mathbb Z}_3[x]/\langle x^2+x+2\rangle</math>.

'''Theorem.''' Any two splitting fields for <math>f\in F[x]</math> over <math>F</math> are isomorphic.

'''Lemma 1.''' If <math>p\in F[x]</math> irreducible over <math>F</math>, <math>\phi:F\to F'</math> an isomorphism, <math>a</math> a root of <math>p</math> (in some <math>E/F</math>), <math>a'</math> a root of <math>\phi(p)</math> in some <math>E'/F'</math>, then <math>F[a]\cong F'[a']</math>.

'''Lemma 2.''' Isomorphisms can be extended to splitting fields.


===Zeros of Irreducible Polynomials===
===Zeros of Irreducible Polynomials===

Revision as of 14:10, 7 March 2007

In Preparation

The information below is preliminary and cannot be trusted! (v)

Class Plan

Some discussion of the term test and HW6.

Extension Fields

Definition. An extension field of .

Theorem. For every non-constant polynomial in there is an extension of in which has a zero.

Example over .

Example over .

Definition. .

Theorem. If is a root of an irreducible polynomial , within some extension field of , then , and (here ) is a basis for over .

Corollary. In this case, depends only on .

Splitting Fields

Definition. splits in , a splitting field for over .

Theorem. A splitting field always exists.

Example. over .

Example. Factor within its splitting field .

Theorem. Any two splitting fields for over are isomorphic.

Lemma 1. If irreducible over , an isomorphism, a root of (in some ), a root of in some , then .

Lemma 2. Isomorphisms can be extended to splitting fields.

Zeros of Irreducible Polynomials

Perfect Fields