This answer describes why EM waves from inside a microwave are blocked by the metal mesh screen:
The incident EM wave induces oscillations in the metal of the screen, and these oscillations reradiate EM that interferes with the incident wave. It's this process that blocks the incident wave. The process is purely classical and requires no appeal to the existance of photons.
and refers to another answer for a calculation (Which is based on setting up a standing (and partially traveling) wave equation and solving for boundary conditions representing the screen waveguide. It's then shown from it that low frequency EM waves will exponentially decay with distance from the screen. This is my superficial understanding of it, so my summary might be wrong)
I have two questions on this:
The incident EM wave oscillates electrons, so there must be some delay (as these electrons oscillate) which seems like it'd be manifested as a phase difference between the reradiated EM wave and the incident one. Also, the electrons can only oscillate along the plane of the metal screen so the reradiated wave caused by such oscillations would seem to be produced at some angle to the incident wave. If so, how does the reradiated wave exactly cancel out the incident wave, if it's neither in phase nor in the same direction as it?
The reradiated wave would seem to go in all directions, including backwards into the microwave. So why doesn't it also interfere with (or cancel) the incident wave there?
(Since this likely has a classical explanation, I would appreciate if possible an answer that uses classical electromagnetism).
