Frequency of the polarization of light

In summary, the polarization of light is often represented with an unlabeled axis in animations. The fluctuation frequency of the electrical field is questioned to match the wavelength of the photon and it is assumed that the magnetic/electrical fluctuation happens faster and over a shorter distance than the 21cm wavelength of a microwave photon. The wavelength of light is the distance it travels in one cycle of its electric and magnetic fields, while frequency is the number of times it switches per second. It is acceptable to label a photon's movement in nanometers and variation in time in zeptoseconds. However, using a second axis for amplitude makes it difficult to model refraction. This representation also raises questions about the location of the photon and the uncertainty principle.
  • #1
edguy99
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"Frequency" of the polarization of light

You often see the polarization of light represented this way:
polarized_light.jpg


Unfortunately, the axis is seldom labeled in this type of animation. I assume the horizontal axis is meant to represent space or time. The question I have is "Does the fluctuation frequency of the electrical field match the wave length of the photon?"

To be a little clearer, if you have a photon with quite a long wavelenth (say microwave at 21cm), the wavelength represents the changing probability of things like the photon being reflected when it hits a surface. I assume that the magnetic/electrical fluctuation represented by this picture happens much faster over a much shorter distance then 21cm.

Is that assumption correct, or does the electrical/magnetic fluctuation rate of the photon match its frequency?
 
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  • #2


To my knowledge the wavelength is the distance that the light travels in 1 cycle of its changing electric and magnetic fields while the frequency is how many times it switches per second.
 
  • #3


Wiki actually has some pretty good animations on this:
http://en.wikipedia.org/wiki/Electromagnetic_radiation

One cycle of the oscillating magnetic or electric field is one wavelength, yes. Frequency is 1/wavelength.
 
  • #4


Wavelength in free space (meters per cycle) * frequency (Hz : cycles per second) = c (speed of light in meters per second)
 
  • #5


I also like the graphics on this page http://en.wikipedia.org/wiki/Polarizer

So there is nothing wrong with labeling a 532nm photon moving though space scaled in nanometers like this:
polarized_light1.jpg


And the photon varies in time scaled by zeptoseconds like this:
polarized_light2.jpg


This certainly makes things like Newtons rings easier to understand. It also makes it pretty obvious why the probability of reflection off a surface varies depending on how far the photon travels to get to this surface. The only thing I don't like about these animiations is the use of the second axis for the amplitude. You can model reflection in one dimension this way, but you cannot model refraction as the second and third axis are already in use.

Finally, does this not specifically tie down the location of the photon to a particular point in space at a particular time? Is this a violation of the uncertainty principle?
 

1. What is the frequency of polarization of light?

The frequency of polarization of light refers to the rate at which the electric field oscillates in a specific direction. It is measured in Hertz (Hz), which represents the number of oscillations per second.

2. How does the frequency of polarization affect the properties of light?

The frequency of polarization determines the energy and wavelength of light. Higher frequencies correspond to shorter wavelengths and higher energy levels, while lower frequencies have longer wavelengths and lower energy levels. This can impact the behavior of light, such as its ability to be absorbed or reflected by certain materials.

3. Can the frequency of polarization be changed?

Yes, the frequency of polarization can be changed through various processes such as refraction, reflection, or absorption. For example, when light passes through a polarizing filter, the frequency of polarization changes as it is filtered to only allow light waves with a specific orientation to pass through.

4. How does the frequency of polarization relate to the polarization angle?

The frequency of polarization is independent of the polarization angle. This means that regardless of the angle at which light is polarized, the frequency remains the same. However, the intensity of light may vary depending on the angle of polarization.

5. What is the significance of the frequency of polarization in scientific research?

The frequency of polarization is an important factor in various areas of scientific research, such as optics, materials science, and quantum mechanics. It is used to study the behavior of light and its interactions with matter, and has practical applications in technologies such as LCD displays, polarimeters, and optical filters.

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