Sorry If I seem to be stubborn, but according to my (humble) understanding of general relativity the entity which can produce modifications in space-time is the energy density. Matter and light have energy density patterns associated to themselves. Therefore, it would be natural to me the statement that both matter and light can produce effects on space-time. A remarkable fact, however, is that matter are more likely to produce non negligible effects, due to the typical magnitude of its energy density.jerromyjon said:Photons have 0 rest mass, 0 inertia, 0 gravitational impact on matter. Perhaps the effect of the photonic fields leads to an increase in the mass of the matter it affects, but the fields themselves do not warp space in a gravitational sense.
mfb said:It is possible to assign a mass to the whole system (cavity+radiation). This mass increases if you increase the amount of light in it, as the rest energy of the system increases.
I reached this conclusion based on the definition of mass as energy in the rest frame.DaTario said:Is this statement based on the same principles used in that gedanken experiment with a photon inside a box (it is a demonstration of the relation ## E = mc^2 ##), typically presented in relativity's classes?
Their speed (in vacuum) stays the same, the velocity can change.jerromyjon said:But photons can't accelerate or decelerate. Their velocity remains the same regardless of "energy" they contain...
That's like saying "more red cars around means a higher car density, so car density is directly related to red car color". You can have a high and a low photon density with any frequency.Revolucien said:So if measured density at this focal point is based on the energy and momentum of the photons, and the frequency determines the energy and momentum of the photon...my question from earlier (#17)- Isn't photon density in direct relation to frequency? A higher frequency will take more energy and momentum creating a higher density at a measured point. Sorry, if I'm missing something basic just trying to understand.
Depends on the unspecified energy density in the cylinders. Take a dim blue LED and a bright red laser...Revolucien said:If I took a cylinder 10cm diameter x 1 meter long as my volume measurement, then through one tube had a red beam of light, and through another had a blue beam of light, the blue beam would have a higher energy per volume than the red.
I was mentioning this derivation.my2cts said:I reached this conclusion based on the definition of mass as energy in the rest frame.
The rest frame is the frame in which the total momentum vanishes.
This definition of rest frame avoids the complication of a massless particle or wave.
I have no reference for these statements.except a letter by myself to the publication my local physics society
and I did not learn this explicitly in a physics class.
The reason I had said red was just to say the difference in wavelength/frequency has different energy--> E=ħƒ where ħ is Planck's Constant or Energy=(6.62607004 × 10-34 m2 kg / s)frequency.mfb said:Their speed (in vacuum) stays the same, the velocity can change.
That's like saying "more red cars around means a higher car density, so car density is directly related to red car color". You can have a high and a low photon density with any frequency.
mfb said:Depends on the unspecified energy density in the cylinders. Take a dim blue LED and a bright red laser...
I know, but the following question didn't make sense.Revolucien said:The reason I had said red was just to say the difference in wavelength/frequency has different energy--> E=ħƒ where ħ is Planck's Constant or Energy=(6.62607004 × 10-34 m2 kg / s)frequency.
What exactly does "amount of energy" mean here? If the energy density of blue light and red light (energy per volume) is the same, then the "photon density" (problematic concept) is lower for blue light, because the energy per photon is higher and we fixed the overall energy density.Revolucien said:If you use a red and blue LED of the same value of luminosity, based on the E=ħƒ would the frequency/wavelength determine a different amount of energy for each?
It's a simple linear relationship, is it not?Revolucien said:based on the E=ħƒ would the frequency/wavelength determine a different amount of energy for each?
I did not say the energy density was the same, that is where I am thinking there is a difference. By increasing the dim blue light or decreasing the red so they are equal in luminosity is it possible that they could have different energy per volume based on the wavelength? Does it take more energy to create the same luminosity in different wavelengths?mfb said:What exactly does "amount of energy" mean here? If the energy density of blue light and red light (energy per volume) is the same, then the "photon density" (problematic concept) is lower for blue light, because the energy per photon is higher and we fixed the overall energy density.
That's what I'm thinking.jerromyjon said:It's a simple linear relationship, is it not?
is luminosity a "result" of "total energy", or is it a "result" of "number of photons"? I'm not sure if that is asked clearly or specifically enough...Revolucien said:luminosity
A logarithmic scale is just a different way to represent the same thing. "+5", "-3" etc. are more handy than large exponents. The magnitude of stars is also a historic thing.jerromyjon said:that all makes sense, but this confuses me:
The absolute bolometric magnitude (Mbol) of an object is a logarithmic measure of its total energy emission.
Is that just a loose analogy like "moles of atoms"?
If it doesn't have any mass how does light move things?russ_watters said:Welcome to PF!
If you are talking about mass density, no, light does not have mass so it doesn't have density.
It has momentum. Also, to the extent that light is omni-directional, it can have energy density and, hence, mass density. [An ideal laser beam remains massless. It has non-zero energy density but has a matching momentum density according to ##E=pc## so that the 4-vector sum has zero magnitude].Bkat2d11 said:If it doesn't have any mass how does light move things?