x^4-x=0 equation

Given the equation
$$x^{4} - x = 0$$
Obviously:

x0 = 0

next,
transform
$$\frac{1}{x^{3}} = 1$$
Because equation degree is equal to = -3 - does not contain even numbers in the numerator, then
the equation has single real root.
Get the root -3-th degree of the equation sides:
We get:
$$\frac{1}{\sqrt[3]{\frac{1}{x^{3}}}} = \frac{1}{\sqrt[3]{1}}$$
or
$$x = 1$$
We get the answer: x = 1

All other 2 root(s) is the complex numbers.
do replacement:
$$z = x$$
then the equation will be the:
$$\frac{1}{z^{3}} = 1$$
Any complex number can presented so:
$$z = r e^{i p}$$
substitute to the equation
$$\frac{e^{- 3 i p}}{r^{3}} = 1$$
where
$$r = 1$$
- the magnitude of the complex number
Substitute r:
$$e^{- 3 i p} = 1$$
Using Euler’s formula, we find roots for p
$$- i \sin{\left(3 p \right)} + \cos{\left(3 p \right)} = 1$$
so
$$\cos{\left(3 p \right)} = 1$$
and
$$- \sin{\left(3 p \right)} = 0$$
then
$$p = - \frac{2 \pi N}{3}$$
where N=0,1,2,3,...
Looping through the values of N and substituting p into the formula for z
Consequently, the solution will be for z:
$$z_{1} = 1$$
$$z_{2} = - \frac{1}{2} - \frac{\sqrt{3} i}{2}$$
$$z_{3} = - \frac{1}{2} + \frac{\sqrt{3} i}{2}$$
do backward replacement
$$z = x$$
$$x = z$$

The final answer:

x0 = 0

$$x_{1} = 1$$
$$x_{2} = - \frac{1}{2} - \frac{\sqrt{3} i}{2}$$
$$x_{3} = - \frac{1}{2} + \frac{\sqrt{3} i}{2}$$