Electromagnetic waves and phase difference

AI Thread Summary
Electromagnetic waves consist of electric and magnetic fields that oscillate perpendicularly to each other and to the direction of wave propagation. The phase difference between the electric field (E) and magnetic field (B) is zero, meaning they reach their peak and zero values simultaneously. Confusion arose regarding the phase relationship when comparing E and B to other waveforms, but it was clarified that E and B are in phase as they oscillate together. The discussion emphasized that while E and B are perpendicular, they cannot be directly compared to other waveforms that may appear out of phase. Understanding this relationship is crucial for grasping the nature of electromagnetic waves.
logearav
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Homework Statement



Electromagnetic waves contain time varying electric and magnetic field perpendicular to each other and also to path of progression. The phase difference between electric field vector and magnetic field vector is zero

Homework Equations





The Attempt at a Solution


How the phase difference is zero? Because when E is at ∏/2, B is at -∏/2. When phase difference is zero, Both E and B are in phase with each other, which means when E is at zero, B should also be at zero and when E is at ∏, B should also be at ∏. I am confused. Revered members, please help
 
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logearav said:
Because when E is at ∏/2, B is at -∏/2.
Why do you say that?
 
Thanks for the reply. Now I have provided the image for EM wave and also another image --- two coloured curves representing two completely out of phase waves.
Both look similar. Then how can we say EM waves are in phase with each other?
 

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The two illustrations, while looking similar, really have nothing to do with each other.

In the first one, you have two waves of different types which point in perpendicular directions. One is the electric field; the other is the magnetic field. They don't add to together or anything like that. Note that E and B peak at the same time, and they vanish at the same time. They oscillate in phase.
 
vela,
Now if i assume the coloured curves as a EM wave, Red representing E, and Blue representing B, can i say they are in phase?
 
E and H are perpendicular. For example, E vibrates in the x direction and H vibrates in the y direction. You can not plot them in the same graph as the left picture in your attachment. There the curves have opposite phases, as one is minimum and the other maximum at the same time.
But E and H can not be compared this way. You can compare vectors by their magnitude, but can not say that the vector (2,0) is larger than (0,-2).

E and H in phase means that both have peak value at the same time and zero at the same time, as Vela pointed out.

ehild
 
@ehild,
I got it now. Thanks a lot.
@Vela
Thanks for clarifying. I read your post again with inputs from ehild and i got it now. Thanks a lot, Vela, for your reply.
 

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