Complex Numbers are Parallel iff Cross Product is Zero

Theorem
Let $z_1$ and $z_2$ be complex numbers in vector form such that $z_1 \ne 0$ and $z_2 \ne 0$.

Then $z_1$ and $z_2$ are parallel :
 * $z_1 \times z_2 = 0$

where $z_1 \times z_2$ denotes the complex cross product of $z_1$ with $z_2$.

Proof
By definition of complex cross product:
 * $z_1 \times z_2 = \cmod {z_1} \, \cmod {z_2} \sin \theta$
 * $\cmod {z_1}$ denotes the complex modulus of $z_1$
 * $\theta$ denotes the angle from $z_1$ to $z_2$, measured in the positive direction.

Necessary Condition
Let $z_1$ and $z_2$ be parallel.

Then either $\theta = 0^\circ$ or $\theta = 180^\circ$.

Either way, from Sine of Zero is Zero or Sine of Straight Angle:
 * $\sin \theta = 0$

and so:
 * $\cmod {z_1} \, \cmod {z_2} \sin \theta = 0$

Hence by definition:
 * $z_1 \times z_2 = 0$

Sufficient Condition
Let $z_1 \times z_2 = 0$.

Then by definition:
 * $cmod {z_1} \, \cmod {z_2} \sin \theta = 0$

As neither $z_1 = 0$ or $z_2 = 0$ it follows that $\sin \theta = 0$.

From Sine of Multiple of Pi it follows that either:
 * $\theta = 0^\circ$
 * $\theta = 180^\circ$

or:
 * $\theta$ is either of the above plus a full circle.

That is, $z_1$ and $z_2$ are parallel.