Polynomial Factor Theorem

Theorem
Let $P \left({x}\right)$ be a polynomial in $x$ over a field $K$ of degree $n$.

Then $\xi \in K: P \left({\xi}\right) = 0$ if and only if $P \left({x}\right) = \left({x - \xi}\right) Q \left({x}\right)$, where $Q$ is a polynomial of degree $n - 1$.

Hence, if $\xi_1, \xi_2, \ldots, \xi_n \in K$ such that all are different, and $P \left({\xi_1}\right) = P \left({\xi_2}\right) = \ldots = P \left({\xi_n}\right) = 0$, then:
 * $\displaystyle P \left({x}\right) = k \prod_{j \mathop = 1}^n \left({x - \xi_j}\right)$

where $k \in K$.

Proof
If $P = \left({x - \xi}\right) Q$ then $P \left({\xi}\right) = Q \left({\xi}\right) \cdot 0 = 0$.

Conversely suppose that $P \left({\xi}\right) = 0$.

By the Division Theorem for Polynomial Forms over Field, there exist polynomials $Q$ and $R$ such that $P = Q(x-\xi) + R$ and $\operatorname{deg}R < \operatorname{deg} \left({x - \xi}\right) = 1$.

Evaluating at $\xi$ we have:
 * $0 = P \left({\xi}\right) = R \left({\xi}\right)$

But $\operatorname{deg} R = 0$, so $R \in K$, in particular $R = 0$.

Thus $P = Q \left({x - \xi}\right)$ as required.

The fact that $\operatorname{deg} Q = n - 1$ follows from the fact that the ring of polynomials is an integral domain and the properties of degree of product of polynomials.

We can then apply this result to the situation where:
 * $P \left({\xi_1}\right) = P \left({\xi_2}\right) = \ldots = P \left({\xi_n}\right) = 0$

We can progressively work through:


 * $P \left({x}\right) = \left({x - \xi_1}\right) Q_{n-1} \left({x}\right)$

where $Q_{n-1} \left({x}\right)$ is a polynomial of order $n - 1$.

Then, substituting $\xi_2$ for $x$, we get that:
 * $0 = P \left({\xi_2}\right) = \left({\xi_2 - \xi_1}\right) Q_{n-1} \left({x}\right)$

Since $\xi_2 \ne \xi_1$:
 * $Q_{n-1} \left({\xi_2}\right) = 0$

and we can apply the above result again:


 * $Q_{n-1} \left({x}\right) = \left({x - \xi_2}\right) Q_{n-2} \left({x}\right)$

Thus
 * $P \left({x}\right) = \left({x - \xi_1}\right) \left({x - \xi_2}\right) Q_{n-2} \left({x}\right)$

and we then move on to consider $\xi_3$.

Eventually we reach:
 * $P \left({x}\right) = \left({x - \xi_1}\right) \left({x - \xi_2}\right) \ldots \left({x - \xi_n}\right) Q_0 \left({x}\right)$

$Q_0 \left({x}\right)$ is a polynomial of zero degree, that is a constant polynomial.

The result follows.