07-401/Class Notes for March 7

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Class Plan

Some discussion of the term test and HW6.

Some discussion of our general plan.

Lecture notes

Extension Fields

Definition. An extension field ${\displaystyle E}$ of ${\displaystyle F}$.

Theorem. For every non-constant polynomial ${\displaystyle f}$ in ${\displaystyle F[x]}$ there is an extension ${\displaystyle E}$ of ${\displaystyle F}$ in which ${\displaystyle f}$ has a zero.

Example ${\displaystyle x^{2}+1}$ over ${\displaystyle {\mathbb {R} }}$.

Example ${\displaystyle x^{5}+2x^{2}+2x+2=(x^{2}+1)(x^{3}+2x+2)}$ over ${\displaystyle {\mathbb {Z} }/3}$.

Definition. ${\displaystyle F(a_{1},\ldots ,a_{n})}$.

Theorem. If ${\displaystyle a}$ is a root of an irreducible polynomial ${\displaystyle p\in F[x]}$, within some extension field ${\displaystyle E}$ of ${\displaystyle F}$, then ${\displaystyle F(a)\cong F[x]/\langle p\rangle }$, and ${\displaystyle \{1,a,a^{2},\ldots ,a^{n-1}\}}$ (here ${\displaystyle n=\deg p}$) is a basis for ${\displaystyle F(a)}$ over ${\displaystyle F}$.

Corollary. In this case, ${\displaystyle F(a)}$ depends only on ${\displaystyle p}$.

Splitting Fields

Definition. ${\displaystyle f\in F[x]}$ splits in ${\displaystyle E/F}$, a splitting field for ${\displaystyle f}$ over ${\displaystyle F}$.

Theorem. A splitting field always exists.

Example. ${\displaystyle x^{4}-x^{2}-2=(x^{2}-2)(x^{2}+1)}$ over ${\displaystyle {\mathbb {Q} }}$.

Example. Factor ${\displaystyle x^{2}+x+2\in {\mathbb {Z} }_{3}[x]}$ within its splitting field ${\displaystyle {\mathbb {Z} }_{3}[x]/\langle x^{2}+x+2\rangle }$.

Theorem. Any two splitting fields for ${\displaystyle f\in F[x]}$ over ${\displaystyle F}$ are isomorphic.

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

Lemma 2. Isomorphisms can be extended to splitting fields.

Zeros of Irreducible Polynomials

Definition. The derivative of a polynomial.

Claim. The derivative operation is linear and satisfies Leibnitz's law.

Theorem. ${\displaystyle f\in F[x]}$ has a multiple zero in some extension field of ${\displaystyle F}$ iff ${\displaystyle f}$ and ${\displaystyle f'}$ have a common factor of positive degree.

Lemma. The property of "being relatively prime" is preserved under extensions.

Theorem. Let ${\displaystyle f\in F[x]}$ be irreducible. If ${\displaystyle \operatorname {char} F=0}$, then ${\displaystyle f}$ has no multiple zeros in any extension of ${\displaystyle F}$. If ${\displaystyle \operatorname {char} F=p>0}$, then ${\displaystyle f}$ has multiple zeros (in some extension) iff it is of the form ${\displaystyle g(x^{p})}$ for some ${\displaystyle g\in F[x]}$.

Definition. A perfect field.

Theorem. A finite field is perfect.

Theorem. An irreducible polynomial over a perfect field has no multiple zeros (in any extension).

Theorem. Let ${\displaystyle f\in F[x]}$ be irreducible and let ${\displaystyle E}$ be the splitting field of ${\displaystyle f}$ over ${\displaystyle F}$. Then in ${\displaystyle E}$ all zeros of ${\displaystyle f}$ have the same multiplicity.

Corollary. ${\displaystyle f}$ as above must have the form ${\displaystyle a(x-a_{1})^{n}\cdots (x-a_{k})^{n}}$ for some ${\displaystyle a\in F}$ and ${\displaystyle a_{1},\ldots ,a_{k}\in E}$.

Example. ${\displaystyle x^{2}-t\in {\mathbb {Z} }_{2}(t)[x]}$ is irreducible and has a single zero of multiplicity 2 within its splitting field over ${\displaystyle {\mathbb {Z} }_{2}(t)[x]}$.