EM wave - nodes at metal surface

In summary, the book explains that in a standing electromagnetic wave between two metal plates, only nodes would be at the metal plates due to the infinite high conduction of metal. This is one of the boundary conditions of an electric field at the surface of a conductor, where the electric field inside the conductor will be cancelled out by the movement of charges. This also applies to the wave, where any electric field at the surface will be cancelled out by the electrons' movements, resulting in zero electric and magnetic fields at the surface. However, the component of the electric field parallel to the surface is zero, while the component perpendicular to the surface is not. For the magnetic field, the opposite is true.
  • #1
Edgardo
706
17
I've read in a book, that if you had a standing electromagnetic wave between two metal plates, only nodes would be at the metal plates. This is due to the infinite high conduction of metal, the book says.

Why is that so?
 
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  • #2
This is one of the boundary conditions of an electric field at the surface of a conductor. Inside the conductor, the electric field will be zero since any electric field will cause the charges to move around as to cancel this field (practically instantaneously).
Same reasoning applies with the wave. Any E-field at the surface of the metal plate will cause the electrons to move around as to cancel this field. So it will always be zero.
 
  • #3
So the E-field (and the B-field) at the surface is zero, since the electrons' movements cancel out the E-field? And the movement is so fast that it is really zero?
 
  • #4
Yes, it is practically instantaneous. Mathematically it IS in the case of an ideal conductor.
Any field in, say, the x-direction will push on the charges and cause positive to accumulate x direction and negative charge in the -x direction. This arrangement will produce its own field in the -x direction as to cancel the original field, so the total field will be zero.
 
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  • #5
It is only the component of E parallel to the metal'surface that is zero. The component perpendicular to (and just outside) the surface is not zero. For B, it is the opposite. The normal component is zero and the tangential component is not. If the wave vector (k) is perpendicular to the surface, E at the surface is zero, but B is not.
 

1. What are EM waves and how do they interact with metal surfaces?

EM waves, short for electromagnetic waves, are a type of energy that is produced by the acceleration of electric charges. When these waves encounter a metal surface, they can be reflected, absorbed, or transmitted depending on the properties of the metal.

2. What are nodes in an EM wave and how do they form at metal surfaces?

Nodes in an EM wave refer to points of zero amplitude or energy. At a metal surface, the electric field of the wave is reflected and inverted, creating standing waves. The points where the reflected wave and incident wave cancel out are known as nodes.

3. How do the properties of metals affect the formation of nodes in EM waves?

The properties of metals, such as their conductivity and surface roughness, can affect the formation of nodes in EM waves. Metals with higher conductivity tend to have more distinct nodes at their surfaces, while rougher surfaces can cause nodes to form at different depths within the metal.

4. Can nodes in EM waves at metal surfaces be manipulated?

Yes, nodes in EM waves at metal surfaces can be manipulated by changing the properties of the metal or by using external fields. For example, the use of a magnetic field can alter the formation of nodes in a metal surface.

5. How are nodes in EM waves at metal surfaces used in practical applications?

Nodes in EM waves at metal surfaces have various practical applications, such as in the field of optics. They are used in devices like optical filters and polarizers, which rely on the manipulation of nodes to control the transmission and reflection of light. They are also used in antenna design to improve signal reception and transmission.

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