Show that if $A^{n}=I$ then $A$ is diagonalizable.
Solution 1:
Let $P(X):=X^n-1$. Assume we work on an algebraically closed field $\mathbb K$ of characteristic $0$. We have, since $P$ kills $A$, that the minimal polynomial of $A$ splits on $\mathbb K[X]$ and has distinct roots. We conclude by Theorem 4.11.
Solution 2:
Davide showed what happens in an algebraically closed field of characteristic $0$.
If the field is not algebraically closed, the result is not true, for example
$$A=\begin{pmatrix} 0 & 1\\ -1 & 0 \end{pmatrix}$$
Satisfies $A^4=I$ but is not diagonalizable over $\mathbb R$, as it has complex eigenvalues.
Also $$A=\begin{pmatrix} 1& 1\\ 0 & 1 \end{pmatrix}$$
is not diagonalizable in an algebraically closed field of characteristic $2$, but $A^2=I_2$. Note that the reason why $A$ is not diagonalizable is simple: both eigenvalues are $1$, thus if $A$ is diagonalizable, $D=I$ and thus $A=PDP^{-1}=I$ contradiction.