Difference between polarization and phase

In summary: So, in summary, the polarization of light is a description of the direction of the E field vector and the phase describes the time variation of the oscillation. The two are not the same, and they have nothing to do with each other.
  • #1
Choisai
26
1
So I know how polaroids and 0.5λ plates work, but does this mean that the polarization of the light and the phase of light are the same, but that the polarization of light is actually a vector description of light? Or something like that? Are these two the same?
 
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  • #2
Think of a graph of a single, simple, sine wave, then take the line and make it a solid wavy rod that you are holding in your hand 6" away from your body and horizontal with the waves going up and down. Now push it another 6" away from you. This changes the phase and does nothing to the polarity. Now twist your wrist so that the waves point at a an angle to the vertical. This changes the polarization but does nothing to the phase. So, no, phase and polarization are not only not the same thing, they have nothing to do with each other. The confusion, I think, comes in when you start talking about multiple waves and circular polarization and phase is brought into the discussion because it has to do with the relationship between TWO waves and the way they combine (which is where vectors come in)
 
  • #3
Choisai said:
So I know how polaroids and 0.5λ plates work, but does this mean that the polarization of the light and the phase of light are the same, but that the polarization of light is actually a vector description of light? Or something like that? Are these two the same?

Polarisation and phase are two different aspects of EM waves. The polarisation is the direction of the E field vector and the phase describes the time variation of the oscillation (relative to some reference).

To appreciate how quarter and half λ plates work, you need to sort out the distinction between polarisation and phase. If you want to produce polarised light from unpolarised light, you have to use either a birefringent material, a reflecting surface (Brewster angle etc.) or a (relatively modern) dichroic material that will absorb one particular polarisation component and pass the other.
The Concept Map on the Hyperphysics Site will take you to many of the topics that are relevant here.

With my RF based past, I often think that polarisation is easiest to grasp in terms of radio antennae - which inherently produce waves with a specific polarisation and do not produce the randomly polarised waves that large numbers of light emitting atoms tend to do. There are RF equivalents to all the well known optical devices and their operating principles can be much easier to understand as there are fewer layers of knowledge involved (quantum mechanics, random behaviour of atoms etc. can be ignored).

If you can separate out two quadrature (at right angles) polarised beams then you can change the relative phases of the beams so that the vector sum of the E field has various polarisations. If the phase of one polarisation is chosen to be 90o relative to the other, then the resultant E vector will never be zero amplitude but will rotate around the axis to give circular polarisation.
 

1. What is polarization?

Polarization is a phenomenon in which the direction of a wave's electric field is restricted to a certain plane. This can occur in transverse waves, such as light, when the electric field oscillates in a specific direction.

2. What is phase?

Phase refers to the position of a wave in its cycle at a given point in time. It is measured in degrees or radians and determines the relative position of two waves with the same frequency. Waves with the same phase are in sync, while those with opposite phases cancel each other out.

3. How are polarization and phase related?

Polarization and phase are two distinct properties of waves. Polarization refers to the direction of the electric field, while phase refers to the position of the wave in its cycle. However, polarization can affect the phase of a wave, as it can change the direction of the electric field and therefore alter the wave's position in its cycle.

4. What are the different types of polarization?

There are three main types of polarization: linear, circular, and elliptical. In linear polarization, the electric field oscillates in a single plane. In circular polarization, the electric field rotates in a circular motion. In elliptical polarization, the electric field follows an elliptical path.

5. Why is polarization important in science and technology?

Polarization plays a crucial role in many areas of science and technology, including optics, materials science, and telecommunications. It allows for the manipulation and control of light and other electromagnetic waves, making it essential for applications such as LCD displays, 3D glasses, and polarized sunglasses.

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