Unique factorization

Every integer ${\displaystyle N>1}$ can be written in a unique way as a product of prime factors, up to reordering. To see why this is true, assume that ${\displaystyle N}$ can be written as a product of prime factors in two ways

${\displaystyle N=p_{1}p_{2}\cdots p_{m}=q_{1}q_{2}\cdots q_{n}}$

We may now use a technique known as mathematical induction to show that the two prime decompositions are really the same.

Consider the prime factor ${\displaystyle p_{1}}$. We know that

${\displaystyle p_{1}\mid q_{1}q_{2}\cdots q_{n}.}$

Using the second definition of prime numbers, it follows that ${\displaystyle p_{1}}$ divides one of the q-factors, say ${\displaystyle q_{i}}$. Using the first definition, ${\displaystyle p_{1}}$ is in fact equal to ${\displaystyle q_{i}}$

Now, if we set ${\displaystyle N_{1}=N/p_{1}}$, we may write

${\displaystyle N_{1}=p_{2}p_{3}\cdots p_{m}}$

and

${\displaystyle N_{1}=q_{1}q_{2}\cdots q_{i-1}q_{i+1}\cdots q_{n}}$

In other words, ${\displaystyle N_{1}}$ is the product of all the ${\displaystyle q}$'s except ${\displaystyle q_{i}}$.

Continuing this way, we obtain a sequence of numbers ${\displaystyle N=N_{0}>N_{1}>N_{2}>\cdots >N_{n}=1}$ where each ${\displaystyle N_{\alpha }}$ is obtained by dividing ${\displaystyle N_{\alpha -1}}$ by a prime factor. In particular, we see that ${\displaystyle m=n}$ and that there is some permutation ("rearrangement") σ of the indices ${\displaystyle 1,2,\ldots n}$ such that ${\displaystyle p_{i}=q_{\sigma (i)}}$. Said differently, the two factorizations of N must be the same up to a possible rearrangement of terms.