How does polarisation of EM wave work?

In summary: Therefore, the TM case will be stronger on one side of the polarizer and the TE case will be stronger on the other side.
  • #1
serverxeon
101
0
Does it removes either the electric wave of magnetic wave component of the EM wave?

And if so, won't the wave exiting the polariser not a EM wave anymore? More like an E wave or M wave.

If the above argument is correct, won't the speed of light become[tex]\frac{1}{\sqrt{\epsilon_{0}}}[/tex] or [tex]\frac{1}{\sqrt{\mu_{0}}}[/tex]
 
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  • #2
No, an EM wave always has both electric and magnetic fields. The direction of polariztion refers to the direction of the electric field, by convention. A linear vertically polarized wave has the electric field oscillating up and down, and the magnetic field oscillating left and right. A linear horizontally polarized wave has the electric field oscillating left and right, and the electric field oscillating up and down.
 
  • #3
Boundary conditions. An EM wave can always be thought of as being the superposition of two polarizations that are normal to each other. You can reorient the basis vectors of your polarizations to be parallel and perpendicular to the axis of polarization of your polarizer. When striking a perfect electrical conductor (PEC), the tangential E and normal H components are zero on the surface. These three vectors are all contained in one polarization (let's call it the transverse electric (TE) case). The other polarization, the transverse magnetic (TM) case, consists of the the normal E and tangential H fields. The TM fields do not need to be zero on a PEC surface.

A simple polarizer is a grid of wires with gaps between the wires smaller than the wavelength of desired operation. When the light passes through, the TE case (with respect to the wires) will see the metal surfaces along its vector and must be zero along the surface. Since the spacing is so small, this removes most of the TE energy from the wave after it has transmitted through. But the TM case is mostly unperturbed by the wires since they do not have to be zero along the surface. It should be noted though that both the TE and TM cases will completely reflect off of the PEC wires when striking them, it is only when they move along the surface will they behave differently.

Another way to think about it is to note that waves are canceled out inside of a PEC because an incident wave creates currents on the surface of the PEC. The first order currents are due to the electric field in the EM wave and oscillate in the same plane as the electric field in the EM wave. These currents create secondary fields which cancel out the incident field inside of the PEC. With a polarizer, the TE case has an electric field oscillating along the wire. This means that the first order currents can be excited along the wire which results in the fields that are necessary to cancel out the TE fields on the opposite side of the polarizer. However, the TM case has the E field moving perpendicular to the wires. The electrons cannot oscillate against the grating due to the air gaps. So the TM case cannot excite the currents necessary to cancel itself out.
 

1. How does polarisation affect the direction of an EM wave?

When an EM wave is polarised, it means that the electric and magnetic fields are oscillating in a specific direction. This direction is perpendicular to the direction of propagation of the wave. This means that the polarisation of an EM wave can affect the direction in which it travels.

2. What is the difference between linear and circular polarisation of an EM wave?

Linear polarisation refers to an EM wave where the electric field oscillates in a single plane, while circular polarisation refers to an EM wave where the electric field rotates in a circular motion. In linear polarisation, the direction of the electric field remains constant, while in circular polarisation, the direction of the electric field changes continuously.

3. How is the polarisation of an EM wave determined?

The polarisation of an EM wave is determined by the orientation of its electric field. This can be measured using a polarisation filter, which only allows light waves with a specific polarisation orientation to pass through. By rotating the filter and observing the intensity of the light passing through, the polarisation of the EM wave can be determined.

4. Can the polarisation of an EM wave be changed?

Yes, the polarisation of an EM wave can be changed by passing it through a polarising filter or by reflecting it off a surface at a specific angle. These methods work by filtering out certain orientations of the electric field, resulting in a change in polarisation.

5. What are the applications of polarisation in EM waves?

Polarisation of EM waves has various applications in telecommunications, optics, and astronomy. It is used in the transmission and reception of radio and television signals, in 3D movie technology, and in studying the magnetic fields of stars and galaxies. It also plays a crucial role in the functioning of polarising filters in cameras and sunglasses.

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