Let $G$ be group of order $17^4$. I have to find its center $Z(G)$ and $G/Z(G)$.
$|G|=17^4$.
Since $Z(G)$ is subgroup of $G$, the order of center divides the order of the group: $|Z(G)|=17^a$, where $a\leq4$.
$1^{\circ}$ $a=4$ $\Rightarrow |Z(G)|=|G|$. Since center of the group is Abelian, and the group is non-abelian, we have contradiction.
$2^{\circ}$ $a=3$ $\Rightarrow |G/Z(G)|=17$. This means that $G/Z(g)$ is cyclic, and then $G$ is Abelian. Contradiction.
What should I do with the cases $a=2$ and $a=1$?
And also, is this the right way to do this problem? Thank you.
Actually, for all groups of order $17$ or $17^2$ there exist the examples of groups of order $17^4$, whose center is isomorphic to them.
For $C_{17} \times C_{17}$ it is $C_{17} \times (C_{17^2} \rtimes C_{17})$
For $C_{17^2}$ it is $C_{17^3} \rtimes C_{17}$
For $C_{17}$ it is $\langle x, y, z | x^{17^2} = e, x^{17} = y^{17} = z^{17}, x^{-1}yx = y^n, x^{-1}zx = z^n, y^{-1}zy = z^n \rangle$ where $n^{17} \equiv 1 (\text{mod } {17}^2)$