Exponential Dominates Polynomial

Theorem
Let $\exp$ denote the real exponential function.

Let $k \in \N$.

Let $\alpha \in \R_{>0}$.

Then:
 * $\exists N \in \N: \forall x \in \R_{>N}: \map \exp {\alpha x} > x^k$

Proof
Choose any $N > \dfrac {\paren {k + 1}!} {\alpha^{k + 1} }$, where $!$ denotes the factorial.

By Taylor Series Expansion for Exponential Function we have for $x \in \R_{\ge 0}$:


 * $\ds \map \exp {\alpha x} = \sum_{m \mathop \ge 0} \frac {\paren {\alpha x}^m}{m!} > \frac {\paren {\alpha x}^{k + 1} } {\paren {k + 1}!}$

Therefore, for $x > N$: