Understanding angular velocity in spherical polar coordinates

Question

I'm a first year physics student and i've just learnt this equation for angular velocity in spherical polar coordinates:

$\omega=\dot{\phi}\mathbf{e_z}+\dot{\theta}\mathbf{e_\phi}$

The diagram i am using is on the RHS of this link:

https://en.wikipedia.org/wiki/Spherical_coordinate_system

I don't understand why this eqn is correct. Let's take the case where we imagine a vector going around in purely the xy-plane, a horizontal circle. Therefore $\theta=constant$ so in the above equation, $\dot{\theta}\mathbf{e_\phi}=0$. Now $\omega$ should be a vector that only has $\mathbf{e_x}$ and/or $\mathbf{e_y}$ component since it is only moving in that xy plane. But, from the equation, we're left with $\omega=\dot{\phi}\mathbf{e_z}$. But $\mathbf{e_z}$ is perpendicular to xy plane, so $\omega$ which is always pointing in a direction on this horizontal circle should have no $\mathbf{e_z}$ component.

I feel like i'm missing something very key. Anyone help me get out?

Much appreciated.

Answer 1

$\omega$ is not in the xy plane, it is perpendicular to the plane, so the equation is correct. $\omega$ always point in the direction of the axis around which the system instantaneously rotates. If you rotates a disk around its center of mass, then $\omega$ is perpendicular to the plane of the disk.