Complex Roots of Unity are Vertices of Regular Polygon Inscribed in Circle

Theorem
Let $n \in \Z$ be an integer such that $n \ge 3$.

Let $z \in \C$ be a complex number such that $z^n = 1$.

Let $U_n = \left\{{e^{2 i k \pi / n}: k \in \N_n}\right\}$ be the set of $n$th roots of unity.

Let $U_n$ be plotted on the complex plane.

Then the elements of $U_n$ are located at the vertices of a regular $n$-sided polygon $P$, such that:
 * $(1):\quad$ $P$ is circumscribed by a unit circle whose center is at $\left({0, 0}\right)$
 * $(2):\quad$ one of those vertices is at $\left({1, 0}\right)$.

Proof


The above diagram illustrates the $7$th roots of unity.