Intensity of different color light & its relation to energy AND Amplitude

In summary: No, the two beams would have the same amplitude if the number of photons in each beam was the same. If the number of photons in each beam was different, then their amplitude would be different as well.
  • #1
mlgpawnstar
4
0
Hi Let's stick to the classical limit.

We have 2 monochromatic light waves of same intensity. Let's say one is blue and one is red.

Now this means the individual photons of the blue light have more energy(obviously, higher frequency) and the red light photons have lower energy. But since the two light waves have equal intensity, they have the same energy arriving/second.. Right? I think this part is obvious. This then means that the red light wave has more photons and the blue light wave has fewer photons.

Well let's move on to amplitude of the light wave, now this sort of scales with the intensity squared so these two light beams should have the same Amplitude? But Amplitude can also be seen as a function of the number of photons..

Here in lies my current confusion. Sorry if this is so simple. Anyone know of a basic way to get around this and stay consistent?

Either the two light is going to have different amplitude or the same amplitude while the have the same intensity but different frequencies.
 
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  • #2
There is no contradiction. The number of photons in a light wave is dependent on the amplitude. You can calculate the number per second exactly as you described, by looking at the power of the light, and using [tex]E_{photon}=\hbar \nu[/tex] so red light of the same intensity has more photons.
 
  • #3
Hi, light intensity or energy flux is proportional to photon flux, i.e number of photons per unit time per unit surface and to individual photon energy. Does that answer your question?
 
  • #4
Hi 0xDEADBEEF if # of photons depends on Amplitude, and if Amplitude comes from Intensity, since these two beams have the same intensity, they will have the same Amplitude, and thus the same # of photons?? (Obviously this isn't the case.)

"amplitude" is what is throwing me off here.


Alkim: I understand this but how does this relate with Amplitude?
 
  • #5
mlgpawnstar said:
Hi 0xDEADBEEF if # of photons depends on Amplitude, and if Amplitude comes from Intensity, since these two beams have the same intensity, they will have the same Amplitude, and thus the same # of photons?? (Obviously this isn't the case.)
How do you make that conclusion? If 'amplitude' relates to the amount of energy flux and short wavelength photons have more individual energy then either the same amplitude would imply more red photons or the same number of red photons would imply lower amplitude. (Two ways of looking at the same thing.)
 

1. What is the relationship between the intensity of different color light and its energy?

The intensity of different color light is directly proportional to its energy. This means that as the intensity of a particular color of light increases, so does its energy. This relationship can be seen in the electromagnetic spectrum, where colors with higher frequencies (such as blue and violet) have higher energy levels compared to colors with lower frequencies (such as red and orange).

2. How does the amplitude of light affect its intensity?

The amplitude of light refers to the height of its wave. The larger the amplitude, the more intense the light will be. This is because a larger amplitude means that the wave is carrying more energy. In other words, a larger amplitude equals a higher intensity.

3. Can the intensity of light be changed by altering its color?

Yes, the intensity of light can be changed by altering its color. As mentioned earlier, colors with higher frequencies have higher energy levels compared to colors with lower frequencies. Therefore, changing the color of light can also change its intensity. For example, blue light (which has a higher frequency) will have a higher intensity compared to red light (which has a lower frequency).

4. How does the intensity of light affect its wavelength?

The intensity of light does not affect its wavelength. Wavelength refers to the distance between two consecutive peaks or troughs of a light wave, while intensity refers to the amount of energy carried by the wave. These are two separate properties of light and do not have a direct relationship.

5. Is there a limit to the maximum intensity of light?

Yes, there is a limit to the maximum intensity of light. According to the Planck's law of blackbody radiation, there is a maximum limit to the amount of energy that a light wave can carry. This limit is known as the Planck's constant and is a fundamental constant in physics. Therefore, there is a maximum intensity that a light wave can reach, regardless of its color or amplitude.

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