Group Theory and Linear Algebra

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updated: 27 September 2014

Lecture 32: Revision: The Fundamental Theorem of Algebra

(II) Week 1 §2: Show that the field of complex numbers is algebraically closed.

To show: If $f = a_{0} + a_{1} t + \dots + a_{ℓ} t^{ℓ} \in ℂ [t]$ then there exists $β_{1}, β_{2}, \dots, β_{ℓ} \in ℂ$ such that $a_{0} + a_{1} t + \dots + a_{ℓ} t^{ℓ} = (t - β_{1}) \dots (t - β_{ℓ}) .$ Proof by induction on $ℓ :$

If $f = a_{0} + a_{1} t + \dots + a_{ℓ} t^{ℓ} \in ℂ [t]$ then there exist $β \in ℂ$ and $f_{1} = b_{0} + b_{1} t + \dots + b_{ℓ - 1} t^{ℓ - 1}$ such that $f = (t - β) f_{1} .$

Another version of the Lemma is

If $f = a_{0} + a_{1} t + \dots + a_{ℓ} t^{ℓ} \in ℂ [t]$ then there exist $β \in ℂ$ such that $f (β) = 0 .$

$ℝ$ is not algebraically closed: $t^{2} + 1$ does not factor in $ℝ [t],$ even though $t^{2} + 1 = (t + i) (t - i)$ factors in $ℂ [t] .$

If $f = a_{0} + a_{1} t + \dots + a_{ℓ} t^{ℓ} \in ℝ [t]$ then there exist $p_{1}, \dots, p_{r}$ with $deg (p_{i})$ equal to $1$ or $2$ such that $f = p_{1} \cdot p_{2} \dots p_{r} .$

This follows from the fundamental theorem of algebra and the fact that If $f \in ℝ [t]$ and $β \in ℂ$ such that $f (β) = 0$ then $f (\overline{β}) = 0 .$ So $\begin{array}{rcl} f & = & (t - γ_{1}) \dots (t - γ_{r}) (t - β_{1}) (t - \overline{β_{1}}) \dots (t - β_{s}) (t - \overline{β_{s}}) \\ = & (t - γ_{1}) \dots (t - γ_{r}) (t^{2} - (β_{1} + \overline{β_{1}} + β_{1} \overline{β_{1}})) \dots (t^{2} - (β_{s} + \overline{β_{s}}) + β_{s} \overline{β_{s}}) \end{array}$ with $γ_{1}, \dots, γ_{r} \in ℝ$ and $β_{1}, \dots, β_{s} \in ℂ$ with $β_{1}, \dots, β_{s} \notin ℝ .$ Note that $β_{j} + \overline{β_{j}} \in ℝ$ and $β_{j} \overline{β_{j}} \in ℝ .$

This theorem is called the fundamental theorem of algebra. It was first proved by d'Alembert, after which Gauss studied the theorem intensively providing 14 proofs.

Further references: Wikipedia - Fundamental Theorem of Algebra, Math Overflow - Fundamental Theorem of Algebra, Article of Harm Derksen.

$ℂ$ is algebraically closed.

Proof (d'Alembert-Gauss [Bou, Top. Ch VIII §1, no. 1, Theorem 1]).

Bourbaki defines $ℂ$ as $ℝ [X] (X^{2} + 1) .$

To show:

(a)	If $a \in ℝ_{\geq 0}$ then there exists $\sqrt{a} \in ℝ .$
(b)	If $p (t) \in ℝ [t]$ and $deg p$ is odd then there exists $α \in ℝ$ such that $p (α) = 0 .$

(b)

Assume

p (t) = a_{n} X^{n} + a_{n - 1} X^{n - 1} + \dots + a_{0}

with

n

odd and

a_{n} \neq 0 .

x \in ℝ

and

x \neq 0

then

p (x) = a_{n} x^{n} g (x),

where

g (x) = 1 + \frac{a_{n - 1}}{a_{n} x} + \dots + \frac{a_{0}}{a_{n} x^{n}} .

lim_{x \to \infty} g (x) = 1 and lim_{x \to - \infty} g (x) = 1 .

So there exists

a \in ℝ_{\geq 0}

such that

sign (a_{n}) = sign (f (a)) and sign (- a_{n}) = sign (f (- a)) .

Thus, by Bolzano's theorem, [Bou, Top IV §6, no. 1, Theorem 2], there exists

α \in {[- a, a]}_{ℝ}

such that

f (α) = 0 .

$□$

Proof 2 [Bou, Top. Ch VIII §2. Exercise 2].

Let $f (t) \in ℂ [t]$ such that $f (t) \neq 0 .$
To show: There exists $r \in ℝ_{\geq 0}$ such that if $z \in ℂ$ and $| z | \geq r$ then $| f (z) | > | f (0) | .$ Use [Exercise 1] and Weierstrass' theorem [Bou, Top. ChIV §6 no. 1, Theorem 1] to show $ℂ$ is algebraically closed.

$□$

[Bou Top. Ch. VIII §2, Exercise 1]
Let $a \in ℂ,$ $a \neq 0$ and $n \in ℤ_{> 0} .$

To show:

(a)	If $r \in ℝ_{> 0}$ such that $r^{n} \leq \| a \|$ then there exists $z \in ℂ$ such that $\| z \| = r$ and $\| a + z^{n} \| = \| a \| - r^{n} .$
(b)	If $f (z) \in ℂ [t]$ and $deg (f) > 0$ and $z_{0} \in ℂ,$ with $f (z_{0}) \neq 0$ then there exists $z \in B_{ε} (z_{0})$ such that $\| f (z_{0}) \| > \| f (z) \| .$

Notes and References

These are a typed copy of Lecture 32 from a series of handwritten lecture notes for the class Group Theory and Linear Algebra given on October 19, 2011.

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