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Proofs from THE BOOK by Martin Aigner and Günter Ziegler begins by giving six proofs of the infinity of primes. We will go over the third proof. Before we go over this proof, lets cover some background.

— 1. Fermat Numbers —

Fermat numbers are defined by

$\displaystyle F_{n}=2^{2^{n}}+1,$

so that ${F_{0}=3,F_{1}=5,F_{2}=17,F_{3}=257,}$ and ${F_{4}=65537}$. They are of great interest in many ways: for example, it was proved by Gauss that, if ${F_{n}}$, is a prime ${p}$, then a regular polygon of ${p}$ sides can be inscribed in a circle by Euclidean methods. The property of the Fermat numbers which is relevant here is

Theorem 1 No two Fermat numbers have a common divisor greater than 1.

We will prove this theorem later.

The first four Fermat numbers are prime, and Fermat conjectured that all were prime. Euler, however, found in 1732 that

$\displaystyle F_{5}=2^{2^{5}}+1=641\cdot6700417$

is composite.

In 1880 Landry proved that

$\displaystyle F_{6}=2^{2^{6}}+1=274177\cdot67280421310721.$

It is currently known that ${F_{n}}$, is composite for ${5 \leq n \leq 32}$. Factoring Fermat numbers is extremely difficult as a result of their large size. ${F_{12}}$ has ${5}$ known factors with ${C1187}$ remaining (where ${C}$ denotes a composite number with $n$ digits). ${F_{13}}$ has ${4}$ known factors with ${C2391}$ remaining. ${F_{14}}$ has no known factors but is composite. There are currently four Fermat numbers that are known to be composite, but for which no single factor is known: ${F_{14},F_{20},F_{22},}$ and ${F_{14}}$. In all the other cases proved to be composite a factor is known. No prime ${F_{n}}$ has been found beyond ${F_{4}}$, and it seems unlikely that any more will be found using current computational methods and hardware.

— 2. Infinitude of Primes Theorem —

We are now ready to prove Euclid’s Second Theorem, also called the Infinitude of Primes Theorem using the third proof in Proofs from THE BOOK.

Theorem 2 (Euclid’s Second Theorem) The number of primes is infinite.

Proof: Next let us look at the Fermat numbers ${F_{n}=2^{2^{n}}+1}$ for ${n=0,1,2,\cdots}$. We will show that any two Fermat numbers are relatively prime (Theorem 1); hence there must be infinitely many primes. To this end, we verify the recursion

$\displaystyle \prod_{k=0}^{n-1}F_{k}=F_{n}-2\quad(n\geq1),$

from which our assertion follows immediately. Indeed, if ${m}$ is a divisor of, say, ${F_{k}}$ and ${F_{n}}$ ${(k, then ${m}$ divides ${2}$, and hence ${m=1}$ or ${2}$. But ${m=2}$ is impossible since all Fermat numbers are odd.

To prove the recursion we use induction on ${n}$. For ${n=1}$ we have ${F_{0}=3}$ and ${F_{1}-2=5-2=3}$. With induction we now conclude

$\displaystyle \begin{array}{rcl} \prod_{k=0}^{n} F_{k} & = & \left(\prod_{k=0}^{n-1}F_{k}\right)F_{n}\\ & = & (F_{n}-2)F_{n}\\ & = & (2^{2^{n}}-1)(2^{2^{n}}+1)\\ & = & 2^{2^{n+1}}-1\\ & = & F_{n+1}-2. \Box \end{array}$

Proofs from THE BOOK by Martin Aigner and Günter Ziegler begins by giving six proofs of the infinity of primes. We will go over the second proof. Before we go over this proof, lets cover some background.

— 1. Algebraic Structures —

One of the themes of modern algebra is to compare algebraic structures. An algebraic structure refers to a nonempty set equipped with a binary operation or several binary operations (usually two). Also, we shall refer to a nonempty set equipped with two binary operations satisfying certain properties as a number system. First, we shall define algebraic structures called group, ring and field. A group consists of nonempty set with one binary operation satisfying several conditions. It is the simplest of the three.

Definition 1 Let ${G}$ be a nonempty set and ${*:G\times G\rightarrow G}$ be a binary operation on ${G.}$ Then the set ${G}$ together with the binary operation ${*}$, denoted${(G,*)}$, is a group, if the following three conditions are satisfied:

i. The binary operation ${*}$ is associative, i.e., ${(a*b)*c=a*(b*c)}$ for all ${a,b,c\in G}$.

ii. There is a ${*}$-identity ${e\in G}$, i.e., ${e*x=x*e=x}$ for all ${x\in G}$.

iii. For each ${a\in G}$, there is a ${*}$-inverse ${a'\in G}$, i.e., ${a*a'=a'*a=e}$, where ${e}$ is the ${*}$-identity.

Further more, a group ${(G,*)}$ is said to be commutative (or abelian), if the binary operation ${*}$ is commutative.

I have re-posted this to test my changes to the latex2wp.py and terrystyle.py programs, compiled with Python Software Foundation’s Python 2.7.2 64 bit version, to add support for LyX 1.6.9. The code change incorporates some additional theorem-like environments, macros, font styles, and the numbering has been change so that the different theorem-like types each have a separate counter (e.g., theorem 1, theorem 2, lemma 1, proposition 1, theorem 3, lemma 2, …, as opposed to theorem 1, theorem 2, lemma 3, proposition 4, …). Furthermore, I have provided more background information which will benefit those without a background in abstract algebra.

Proofs from THE BOOK by Martin Aigner and Günter Ziegler begins by giving six proofs of the infinity of primes. The first proof is what they call "the oldest Book Proof" attributed to Euclid. Before we go over this proof, lets cover some background. Read the rest of this entry »

Proofs from THE BOOK by Martin Aigner and Günter Ziegler begins by giving six proofs of the infinity of primes. The first proof is what they call “the oldest Book Proof” attributed to Euclid. Before we go over this proof, lets cover some background. Read the rest of this entry »