Thanks a lot, I appreciate your helpNugatory said:Give this thread a read https://www.physicsforums.com/showthread.php?t=758363 and come back with any further questions.
ElmorshedyDr said:Planck assumed that light must be quantized to explain the actual distribution of the blackbody radiation which reaches a Max intensity at a certain frequency then it approaches zero at higher frequencies, I still have a problem understanding how Planck's assumption explained it.
It should be said that quantum theory of thermal EM radiation (I believe due to Debye) leads to a divergent spectral function too:WannabeNewton said:...A quantized theory of the electromagnetic field is sufficient in removing the divergence.
ElmorshedyDr said:... I still have a problem understanding how Planck's assumption explained it.
parkner said:Planck never assume any photons.
...There is a simple boundary condition for the standing waves, which gives the quantisation, not any energy corpuscles - the photons, are necessary, nor possible.
Jano L. said:The boundary condition of standing waves is not that important to the derivation of the Rayleigh-Jeans or Planck formula. One can do the same derivation for any cuboid in vacuum - the walls do not need to be reflective at all.
Jano L. said:Quantization does not refer to discrete indexing of modes, but to discrete values of energy of each mode. The latter does not follow from the boundary condition of standing waves.
Let's keep our focus on the equilibrium heat radiation. You said that the boundary condition of standing waves leads to quantization. Please explain why do you think that.parkner said:The observed quantisation is always just a consequence of the boundary conditions,
and this applies to the atom, the Hall effect, flux quantisation in the superconductivity, tunneling effect, etc.; all the so-called quantum effects without exception.
In the common derivation of the equilibrium spectrum, energy of mode is supposed to have preferred values - multiples of ##h\nu##. So there is restriction in the calculation - values like ##1.3h\nu## are not allowed.Quantity of energy can be anything - there is no fundamental restriction,
which shows just a black body.
Jano L. said:It should be said that quantum theory of thermal EM radiation (I believe due to Debye) leads to a divergent spectral function too:
$$
\rho(\nu) = \frac{8\pi \nu^2}{c^3}\left(\frac{h\nu}{e^{h\nu / (k_B T)}-1} + \frac{h\nu}{2} \right)
$$
The divergent term ##h\nu/2## in the braces is the lowest energy eigenvalue of a quantum harmonic oscillator. This due to the presence of the so-called zero-point fluctuations of the field. The corresponding contribution to the spectral function diverges even more rapidly than the Rayleigh - Jeans function. It is usually removed by hand. The rest then gives the Planck function and resembles measurements very well.
UltrafastPED said:Do you mean Debye's model for specific heats?
Jano L. said:You said that the boundary condition of standing waves leads to quantization. Please explain why do you think that.
Jano L. said:In the common derivation of the equilibrium spectrum, energy of mode is supposed to have preferred values - multiples of ##h\nu##. So there is restriction in the calculation - values like ##1.3h\nu## are not allowed.
parkner said:The black body radiation is just a sum over all possible wavelengths in the box.
There is a simple boundary condition for the standing waves, which gives the quantisation
...
This is standard... check the calculations in QM, for example the hydrogen atom, and you should find the cause - explanation of the quantisation.
Jano L. said:These boundary conditions do not imply any quantization of energy of EM modes.
Jano L. said:If you meant the latter, I agree that boundary conditions are an important part of the derivation of the discrete values ##(1/2)h\nu, (1+1/2)h\nu, (2+1/2)h\nu,...##
Nugatory said:Informally... If light can only be emitted in quantized packets, then if there's not enough energy concentrated in one area of the object to create a packet of light at a given frequency then nothing at that frequency will be emitted. The higher the frequency of the light the more energy is needed, and the hotter the object the more energy is likely to be concentrated in one area. Combine these two results and you conclude (after some fairly huge oversimplifying of stuff discussed in that other thread) that for any temperature there are frequencies high enough that they're unlikely to be emitted; and that the hotter the object the higher the frequencies that will be emitted can be.
parkner said:This is standard... check the calculations in QM, for example the hydrogen atom, and you should find the cause - explanation of the quantisation.
with respect to an oscillator with fundamental frequency denoted as ##\nu## ...
dauto said:I think you need to relearn quantum mechanics. Your understanding of quantization is lacking. The boundary conditions gives a discrete set of oscillation modes true, but that's not what quantization is. Quantization is the fact that each mode will be occupied by an integer number of particles. In classical physics each mode may have any amount of energy.
Is that related to Boltzmann distribution ?Nugatory said:Informally... If light can only be emitted in quantized packets, then if there's not enough energy concentrated in one area of the object to create a packet of light at a given frequency then nothing at that frequency will be emitted. The higher the frequency of the light the more energy is needed, and the hotter the object the more energy is likely to be concentrated in one area. Combine these two results and you conclude (after some fairly huge oversimplifying of stuff discussed in that other thread) that for any temperature there are frequencies high enough that they're unlikely to be emitted; and that the hotter the object the higher the frequencies that will be emitted can be.
The evidence for the existence of photons comes from various experiments, such as the photoelectric effect, Compton scattering, and the behavior of light in a double-slit experiment. These experiments have shown that light behaves as both a wave and a particle, and photons are the particles that make up electromagnetic radiation.
Blackbody radiation is the electromagnetic radiation emitted by a perfectly opaque and non-reflective object at a certain temperature. The distribution of this radiation follows a specific pattern, known as the Planck curve, which can only be explained by the existence of photons. This phenomenon provides further evidence for the particle nature of light and the existence of photons.
No, photons cannot be detected directly as they have no mass or charge. However, their presence and behavior can be observed indirectly through various experiments, such as those mentioned above, which show the effects of photons on matter.
Yes, all objects emit blackbody radiation, regardless of their temperature. However, the amount and distribution of this radiation depend on the temperature and properties of the object. For example, a warmer object will emit more radiation at higher frequencies, while a cooler object will emit more radiation at lower frequencies.
The evidence for the existence of photons and blackbody radiation plays a crucial role in our understanding of the nature of light and the behavior of matter at the atomic and subatomic levels. It also has practical applications in various fields, such as optics, quantum mechanics, and astrophysics.