This is pretty straightforward if we're allowed to use trigonometry, so I guess my question is
Are there any nice (trigonometry-less) proofs of the fact that a regular pentagon in the plane must have some irrational coordinate?
Now, it's possible to translate a trigonometric proof into an algebraic proof since $\sin(18^\circ)$ can be written in terms of the golden ratio, so I should say that something along these lines would be less than ideal.
I've been thinking about a proof using the fact that the (orientation-preserving) symmetries of the dodecahedron can be identified with $A_5$ (the alternating group on 5 letters) and the 3 dimensional irreducible representations of $A_5$ can't be expressed over the rationals, but I'm not quite sure how this would go. Is proof along these lines possible?
Maybe a better (or worse?) way to say what I'm looking for is this: Is there a proof that is so specific to the pentagon that we couldn't hope to generalize it to other polygons? (Maybe with the exceptional embedding $S_5\hookrightarrow S_6$ lurking in the background...?)