The discussion centers on the wave theory of light and the relationship between energy, frequency, and intensity. Participants clarify that while classical wave theory suggests energy per cycle is independent of frequency, the energy of light is indeed dependent on frequency as expressed by the equation E=hf, where h is Planck's constant. The intensity of light, defined as energy per unit time, is proportional to the square of the amplitude and is independent of frequency. This leads to the conclusion that higher frequency light results in more energy due to a greater number of cycles per unit time.
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kkmans said:For wave theory of light, it said that energy of light is depend only on its brightness and independent of its frequency.
I would like to ask which equation shows that wave energy is independent of frequency..??
kkmans said:For wave theory of light, it said that energy of light is depend only on its brightness and independent of its frequency.
I would like to ask which equation shows that wave energy is independent of frequency..??
thank you.
americanforest said:Then energy of light actually is dependent on frequency by the relation E=hf where h is Planck's constant.
ranger said:That can be restated:
The energy of a photon is dependent on the frequency. I think its incorrect to say the energy of light with respect to that equation.
americanforest said:But the light is made up of photons. The only way this dependancy couldn't be extended to light frequencies in general is if there were less photons in high frequency light than in low frequency light. Is this true?
ranger said:It doesn't mean less or more photons
cesiumfrog said:When one later discovers light quantised in packets of energy proportional to frequency, one must infer (to avoid contradiction) that for a red and blue light source of equal measured brightness there will be a higher rate of photons received from the lower frequency source.
kkmans said:>You should cite this source. That is the one thing we try to make people do when they talk about something they read or heard.
oops, I read this from wikipedia.
let's forget about the light, what about other waves like sound and water ?
If we consider wave as the particles performing SHM, their energy is depends on the frequency.
Is there anything wrong with my concept..??
thank you.
ZapperZ said:Actually, it DOES! Maybe the energy PER CYCLE or per period isn't dependent on frequency in classical wave theory of light, but energy in a unit time does! Think about it. The higher the frequency, the more cycles in that unit time that you measure, the more energy you will get. So yes, even in classical wave theory of light, frequency does matter IF you are looking at it per unit time.
Like other waves, the particles are performing SHM, and their energy is proportional to the square of the frequceny.
Do you have a reference to support that?ZapperZ said:The higher the frequency, the more cycles in that unit time that you measure, the more energy you will get. So yes, even in classical wave theory of light, frequency does matter IF you are looking at it per unit time.
cesiumfrog said:Do you have a reference to support that?
ZapperZ said:No I don't. Rather, look at a mass-spring system. Find the energy per second of the system at a particular amplitude. Now replace the spring so that you have a system that doubles the natural frequency. Now measure again the amount of energy of the system per second with the SAME amplitude. Are you telling me you need a "reference" to figure out that the amount of energy in that unit time has increased?
cesiumfrog said:According to both Griffiths Electrodynamics (p.381) and Saleh & Teich Photonics (p.44), the intensity of a monochromatic light wave is proportional to the square of the amplitude and independent of frequency (just like the average of cos^2\ \omega t over t). Energy per second is simply intensity, integrated over an area.
In the 3rd edition, a section with that name derives that for a monochromatic wave with electric field amplitude E_0 the intensity is \frac 1 2 c \epsilon_0 E^2_0 (eq. 9.63).ZapperZ said:I have the 2nd Edition of Griffiths, and pg. 381 has nothing of that sort. If you look in the section titled "Energy and Momentum of Electromagnetic Waves" [..]
And just as clearly, if you average this over unit time (as you https://www.physicsforums.com/showthread.php?p=1224951#post1224951" specify, rather than integrating over just one cycle), that frequency term will disappear.ZapperZ said:U = \epsilon_0 E^2_0 cos^2(\kappa x - \omega t + \delta)This clearly has a frequency term.
Regardless of the behaviour of such a system, the fact it contains non-zero rest-mass is enough for me to doubt the equivalence. It seems more analogous to a free electron in an electric field.ZapperZ said:Again,[..] a mass-spring system is the simplest visual example.
cesiumfrog said:In the 3rd edition, a section with that name derives that for a monochromatic wave with electric field amplitude E_0 the intensity is \frac 1 2 c \epsilon_0 E^2_0 (eq. 9.63).
And just as clearly, if you average this over unit time (as you https://www.physicsforums.com/showthread.php?p=1224951#post1224951"specify, rather than integrating over just one cycle), that frequency term will disappear.
ZapperZ said:All you need to do is sum up the total energy that impinges on a surface for a particular time. Then do the same for another EM wave with a different frequency. Is the energy "received" the same?
You haven't addressed my simple example with the mass-spring system.
cesiumfrog said:(I haven't addressed your mass-spring example because it is fundamentally unlike the situation in question.)
Yes, the total energy "received" impinging on a surface for a particular time will be equal and the same if repeated with EM waves of different frequency (but equal amplitude). This is what the textbooks are saying, with the caveat that the "particular time" must not be small compared to the period of oscillation, and it completely contradicts your initial answer to the OP.
Look in any first-year general physics textbook for the energy transmitted by any classical wave (string, sound, EM, etc).kkmans said:I would like to ask which equation shows that wave energy is independent of frequency..?
Clearly this is the authoritive source (albeit a less developed version) so you should be able to find in the following paragraphs an expression for the intensity (likely represented as "I" rather than "U").ZapperZ said:(section 8.2.2 in Griffiths 2nd Edition), you would have seen that the energy of a monochromatic plane wave is
U = \epsilon_0 E^2_0 cos^2(\kappa x - \omega t + \delta)
This clearly has a frequency term. The confusion comes in when you are looking at the total energy [..] THEN you have integrated out the effects of frequency
You're asking why, given a particular amplitude, the energy transmitted through a particular point by possible electromagnetic waves (with different frequencies) is not proportional to the internal energies of different stationary isolated mass-springs (in which the position of the mass changes, but also with a particular amplitude, and the frequencies are equivalent with those of the EM waves)?ZapperZ said:Why is it not the same?
cesiumfrog said:Look in any first-year general physics textbook for the energy transmitted by any classical wave (string, sound, EM, etc).Clearly this is the authoritive source (albeit a less developed version) so you should be able to find in the following paragraphs an expression for the intensity (likely represented as "I" rather than "U").
The first thing you should notice about the dependence you're giving is that it does not cause the "integrated" energy (over any period of time exceeding about a 10^{-15}th of a second) to increase with frequency, and this really should contradict what you have said. Moreover, if you cling to this definition, then you can never define a practical "energy per unit time" on any measurable scale.