Do Photons Have Mass? - Debate & Questions

In summary, there is still a debate about whether photons have a rest mass, as the current measurements do not have enough precision to detect it. However, even if they do not have a rest mass, they still have inertial mass and passive gravitational mass, which means they can be affected by gravity and follow geodesic paths in curved spacetime. The concept of gravity in general relativity is based on the curvature of spacetime, not just the mass of objects, so even light can be affected by it. The argument about whether photons have mass or not is more about the definition of mass rather than the physics behind it.
  • #1
duu57f
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Many people have been arguing for a long time that it doesn't. Of course, they couldn't actually give solid proof for this. They based their theory on the fact that if photons had mass at rest than many laws and theories we know today would be wrong. But the question still remains, if photons have no mass at rest, then why is light sucked into black holes. I mean, if light has no mass at rest, then the concept of gravity doesn't apply to it. Also, where does all the energy and momentum come from. I know about the concept of relative mass, but still, even with this, the energy has to come from a source and in my opinion that source has to be an initial mass.
 
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  • #2
It is not known absolutely for sure that photons do not have mass. However, there is an experimental upper limit on what that mass could be; and it's pretty darn small.

Additionally, if photons had mass, there should be a third possible polarization for light, and electrostatic potentials should fall off as [tex]\frac{1}{r} e^{-\frac{m_\gamma c r}{\hbar}}[/tex].

To understand the statement that even light can't escape from a black hole, you have to understand a little bit about how general relativity describes gravity.

General relativity says that the presence of mass (or energy or momentum or pressure, etc.) actually bends the fabric of space and time. When the path of a particle is affected by gravity it happens, not because the particle is feeling a force, but because the particle is traveling along what is effectively a straight line path on a curved surface. When you think about it this way, it seems natural that even light should be affected.

A black hole is simply the case where space and time are so bent that every single straight line path that exists leads to one single place. (Of course, to be exact, we should say that every path that exists inside the event horizon leads to one single place. Outside the event horizon, there are paths that don't lead into the black hole.)
 
  • #3
When the path of a particle is affected by gravity it happens, not because the particle is feeling a force,
this isn't entirely true as gravity does exert a force. in the example you used youre correct, but if that applied everywhere then two masses at rest relative to each other would feel no gravitational force as there is no inital motion, which I am pretty sure isn't true (correct me if I am wrong anyone)

photons are said to have no mass, or specifically no rest mass, for two reasons. well really theyre the same one but anyway. firstly because an inertial observer can never catch up with a photon and view it at rest. secondly because mass addition requires something traveling at the speed of light to have infinite mass (as a product of its initial mass) which requires an infite amount of energy to accelerate to c. thus nothing with mass can get to speed c, but because the mass addition is a product value something with zero rest mass can.
 
  • #4
duu57f said:
But the question still remains, if photons have no mass at rest, then why is light sucked into black holes. I mean, if light has no mass at rest, then the concept of gravity doesn't apply to it.

If that is such a glaring evidence for light having a mass, then would something as obvious as that be missed by the whole physics community. I mean, let's get real here. How dumb do you think physicists are to miss such a thing?

This issue has been discussed to death in several threads in both the Quantum physics forum, and the SR/GR forum. Please do your search there and figure out how gravity is a spacetime curvature, and why light follows the "geodesic" of that spacetime curvature. It has NOTHING to do with light having a mass.

Zz.
 
  • #5
duu57f said:
Many people have been arguing for a long time that it doesn't.
The argument is not about the physics of whether photons have mass. Its a debate about the definition of "mass" which will give either a yes or no according to the definition.

There is a possibility that a photon has a finite rest mass. The best of current measurements of the photon's proper mass does not have the precision to detect any photon proper mass.

I mean, if light has no mass at rest, then the concept of gravity doesn't apply to it. Also, where does all the energy and momentum come from. I know about the concept of relative mass, but still, even with this, the energy has to come from a source and in my opinion that source has to be an initial mass.
The concept of mass that you speak of here is not proper mass but inertial mass and passive gravitational mass. And yes. The photon has both

Best wishes

Pete
 
  • #6
duu57f said:
But the question still remains, if photons have no mass at rest, then why is light sucked into black holes.
It seems you are mistaken in thinking that gravity only works between objects that have mass, that is not the case.

Suppose we have an object with mass. It will curve spacetime and as a consequence all inertial paths are curved in its neighborhood. So any other object nearby, regardless whether it has mass or not, will be subject to these conditions of spacetime.

Consider flat spacetime. Each particle that is inertial for a given time interval shows a straight line segment, and each particle that is not inertial for a given time segment shows a curved line segment.

Now an object that has mass influences the curvature of spacetime.

Then it follows that near an object of mass anything else that showed a straight line segment before does not longer show a straight line segment and the curved line segments are also different. And by the way not only the spatial dimensions of spacetime are subject to curvature, the time dimension is subject to curvature as well. At low relativistic speeds the time curvature is actually stronger than the spatial curvature.

Now with regards to black holes sucking in light, it depends on the direction of the light, most light paths will simply approach and then leave the vicinity of the black hole. But some light paths will encounter such curvature that it will be directed to go to the center of the black hole.
 
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  • #7
MeJennifer said:
It seems you are mistaken in thinking that gravity only works between objects that have mass, that is not the case.
Why not? The development of GR was based on the hypothesis that all objects have mass (whether inertial or proper mass). If this is not true then there would be no justification of the Equivalence Principle and hence particles without any kind of mass would not follow a geodesic. To see that this is the case I would suggest that one follows the development of GR from the beginning and leave out the postulate that all objects must have passive gravitational mass. That isn't an easy task by far. But it would be highly instructive. In fact I intend to do that myself soon.
Now an object that has mass influences the curvature of spacetime.
Its quite possible that an object with an extremely high energy density and an extremely hi tension would have a zero active gravitational mass. This would yield a zero spacetime curvature outside the body. Geodesics would then be straight. However the topology of the spacetime could be changed such that these straight geodesics would intersect. Such an object is postulated to exist and the topology would be that of a cone. E.g. a straight cosmic string is just such an example.

Pete
 
  • #8
I've said this once or twice or ten times before, but in GR, gravity is not based on "mass", but on the stress-energy tensor. In fact, mass is only defined in GR under special circumstances, such as asymptotically flat space-times, or stationary space-times.
 
  • #9
Mass is usually used as a comparative measure. Further, the more mass a space object has the more 'gravitational influence' that space object presents.

In this respect for any other object, be it light or a space ship, their mass is not relevant as we all know things fall at the same speed. So whether light has almost no mass and a spaceship has greater mass, all things fall at the same rate.

What does affect the apparent rate of fall over ground distance covered is velocity. If the spaceship is traveling faster sideways then it will fall to the ground at a greater distance. Give it enough distance and it will miss the Earth all together and continue falling (also called orbiting).

The same with respect would go for light if it has mass. Light travels extremely fast so it should be bent from its path much less than the rocket which is traveling much slower. It is not because light weighs less but simply because it is going faster. Hence why we need stars and galaxies to gain noticeable bending of light as they need to exert greater gravitational influence to overcome the light's speed in sufficient time.

But the key difference for light, if it has mass, is frequency. Frequency represents the oscillation of light through a point of space as it passes through. We have already established that it does not matter how much mass the light has so if higher frequencies were say heavier than lower frequencies then this would make no difference to the path of either frequency as their mass is inconsequential.

However I mentioned frequency because frequency represents how quickly the crests and troughs of the light pass through a point of space. The faster the light rises and falls (the higher its frequency) through its oscillations should effect the path of the light around a gravitational body.

Higher frequency light which is oscillation faster should bend less around a gravitational body than should lower frequency light which is oscillating slower. This effect would be similar to the effect found when passing light through triangular prisms.

However according to science light is achromatic. This means that the different frequencies are not supposed to bend different degrees around large graviational bodies.
 
  • #10
gonegahgah said:
Mass is usually used as a comparative measure. Further, the more mass a space object has the more 'gravitational influence' that space object presents.

In this respect for any other object, be it light or a space ship, their mass is not relevant as we all know things fall at the same speed. So whether light has almost no mass and a spaceship has greater mass, all things fall at the same rate.

What does affect the apparent rate of fall over ground distance covered is velocity. If the spaceship is traveling faster sideways then it will fall to the ground at a greater distance. Give it enough distance and it will miss the Earth all together and continue falling (also called orbiting).

The same with respect would go for light if it has mass. Light travels extremely fast so it should be bent from its path much less than the rocket which is traveling much slower. It is not because light weighs less but simply because it is going faster. Hence why we need stars and galaxies to gain noticeable bending of light as they need to exert greater gravitational influence to overcome the light's speed in sufficient time.

But the key difference for light, if it has mass, is frequency. Frequency represents the oscillation of light through a point of space as it passes through. We have already established that it does not matter how much mass the light has so if higher frequencies were say heavier than lower frequencies then this would make no difference to the path of either frequency as their mass is inconsequential.

However I mentioned frequency because frequency represents how quickly the crests and troughs of the light pass through a point of space. The faster the light rises and falls (the higher its frequency) through its oscillations should effect the path of the light around a gravitational body.

Higher frequency light which is oscillation faster should bend less around a gravitational body than should lower frequency light which is oscillating slower. This effect would be similar to the effect found when passing light through triangular prisms.

However according to science light is achromatic. This means that the different frequencies are not supposed to bend different degrees around large graviational bodies.

This is basically misguided and somewhat reminiscent of argumentative arguments that heavier objects must fall faster than lighter objects.

Just as light and heavy objects fall at the same rate, different frequencies of light are not chromatically aberrated. They both essentially follow geodesics.

Like the case of light and heavy objects falling, this argument iignores the back reaction effects.

The clearest argument is this. If you drop a light and heavy argument, the Earth "may move" (note that it won't move as a point mass!). However, the light and heavy object will both arrive at the same point at the same time. It's just that the Earth will move, and stretch by a totally insignificant amount.

Similarly, if you send a high frequency and a low frequency light beam around a black hole, the black hole "may move" by a totally insignifcant amount. But there will be no relative deflection of the high frequency vs the low frequency beam if they are sent at the same time.
 
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  • #11
so sound waves are affected by a curvature in space?
 
  • #12
everything is
 
  • #13
God pervect

Do you actually read anything I write?

Nothing I wrote in my post that you quoted disagreed with what you rehashed. I'm sorry that I don't use meaningless scientific words.

I really don't know where you get the idea that I argued that heavier objects fall faster than smaller objects.

I did deliberately ignore the "back reaction effects" as I didn't think this necessary to help the original poster. I apologise that you felt its absence. These "back reaction effects" are that while one body A falls towards another body B; body B will also fall towards body A; and this affects the combined closure speed. If you have two massive spheres of lesser density then they will fall together at a slower speed than two massive spheres of greater density. Simply because both denser spheres will experience greater acceleration towards each other than will the less dense spheres towards each other.

Think before you speak please before telling me that I'm presenting flat Earth principles.
 
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  • #14
One related question, which may be less ambiguous, would be "What happens to the mass/gravitational field of a black hole when it sucks up more photons?"

From my casual readings, I have to agree with Pete that the issue is more about what the question really means rather than what the answer is. A photon is a quantum object and terms like "stationary" mass (and "constant" momentum for that matter) are not well-defined. My understanding is that an answer like "The stationary mass of a photon is equal to X" is wrong even if you make X = 0.
 
  • #15
stone1 said:
One related question, which may be less ambiguous, would be "What happens to the mass/gravitational field of a black hole when it sucks up more photons?"
The mass of the black hole increases. Nobody who understands GR has any doubt about that regardless of whether they believe that photons have mass or not (i.e. regardless of how they define the term "mass").

Pete
 
  • #16
Does a photon have mass? in a word, No.
Light is not a substance; light is electromagnetic energy.
a "photon" is a unit of measure of that energy. a photon is no more a particle of light than a phon is a particle of sound.
rg
 
  • #17
W.RonG said:
Does a photon have mass? in a word, No.
Whether light has mass or not will depend on how it is defined. Without stating a definition then its impossible to say whether light has mass or not.
Light is not a substance; light is electromagnetic energy.
Light is, by definition, an electromagnetic wave. It has energy. It cannot be said to be energy. Also, perhaps there are people who wish to think of light as not being a substance. When this is the case then such people will seek out a definition of the term "substance" such that light is not a substance. As of now the term "substance" is an undefined term in physics. It is only used loosely. Einstein himself referred to electromagnetic fields as being "matter" and as such I'd hazard to guess that he'd also refer to light as a "substance." Einstein referred to light as matter in his 1916 review article on the foundations of general relativity.
a "photon" is a unit of measure of that energy. a photon is no more a particle of light than a phon is a particle of sound.
rg
I disagree. By definition a photon is a quantum of light. A photon is not energy. It merely has energy. Your analogy regarding phonons and photons is flawed because you are thinking of it in a way which is inconsistent with how it is defined in physics.

Best wishes

Pete
 
  • #18
Way back in 10/14/06, FunkyDwarf said:

“photons are said to have no mass, or specifically no rest mass, for two reasons.
...firstly because an inertial observer can never catch up with a photon and view it at rest.
secondly because mass addition requires something traveling at the speed of light to have infinite mass
(as a product of its initial mass) which requires an infite amount of energy to accelerate to c. thus
nothing with mass can get to speed c, but because the mass addition is a product value something
with zero rest mass can.”

The first point is incorrect. If you could “catch up” to a photon you would still measure its velocity as c, the speed of light, because c is an invariant. You would, however, measure its frequency as 0 due to red shift.

The second point is correct but misses the point. The point is that anything that travels at the speed of light can ONLY travel at the speed of light. It can never be “at rest” because it IS light and the speed of light in a vacuum is invariant. Therefore, the “rest mass” of a photon is NOT zero; the photon has no rest mass because it can NOT be “at rest”.

I know this is an old thread and my response is to a 2 year old post but the thread, in total, has helped me think through some basic issues in a concise way.

The discussion about photons being E&M waves versus being or having energy has nothing to do with “rest mass” and is more metaphysics (or semantics) than physics. Interesting and correct, but not on point.

The point is: photons are light, light travels at an invariant speed, c, in a vacuum and cannot be at rest; therefore photons cannot have “rest mass” which does NOT mean the “rest mass” of a photon is zero.

Incidentally, it is not a "theory" that the speed of light in vacuum is invariant; it is an axiom.
It is the foundation on which both Special and General Relativity are built.
 
  • #19
hmmm
 
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  • #20
according to Einstein E= mc^2
photons deffinatly have energy
this is soemthign no one can deny
so let's say the photon has a standard unit of 1 where energy is concerened
so
1 = mc^2 when dealign with a photon
therefore its mass when in motion is m = 1/c^2
if a photon stops moving under this model it has 0 energy and 0 mass
and cannot exist
it can only exist if it is in motion

at least logically anyway, but then again nothing works the same in the quantum world anyway , but it still leaves the question why doesn't it have infinate mass when it is in motion , using it as a standard for 1 unit of energy would certainly show it has a mass.
 
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  • #21


Let us suppose light has mass. Take the usual Lagrangian density with the Maxwell field interaction term and add a massive term:
[itex]
\mathcal{L} = - \frac{1}{4} F_{\mu \nu}F^{\mu \nu}- \frac{1}{2}m^{2}A_{\mu}A^{\mu}
[/itex]
It turns out you need to add another couple of terms, otherwise the Lagrangian is not invariant under gauge transformations, so you end up with:
[tex] \mathcal{L} = - \frac{1}{4} F_{\mu \nu}F^{\mu \nu}- \frac{1}{2}m^{2}A_{\mu}A^{\mu} - \frac{1}{2}\partial_{\mu}\phi\partial^{\mu}\phi +mA^{\mu}\partial_{\mu}\phi[/tex]
Now you have added a scalar field to correct for gauge invariance. That is okay so far, but it has a number of problems (including a massive scalar field we should have observed a long time ago), and I am fairly sure its predictions are irreconcilable with our current observations.
As to why light gets "sucked into" a black hole - if you take a look at the solutions to the Schwarzschild geometry inside the event horizon, you will see that the form of the metric effectively switches the space and time coordinates. Don't go reading too much into this, this is simply a mathematical consequence of taking r<R, where R is the event horizon. Because the time coordinate CANNOT go backwards, even for light, inside the black hole, you get that the position of light cannot go backwards, so it must keep going forward and forward in black hole geometry means into the singularity - so it never "escapes". This phenomenon has nothing to do with the "mass" of the light. The only mass term that appears in the Schwarzschild metric is the mass of the black hole.
As for the post above mine, [tex] E^{2}=p^{2}+(mc^{2})^{2}[/tex]. Light has momentum and energy, just not mass.
 
  • #22
...but it has a number of problems (including a massive scalar field we should have observed a long time ago), and I am fairly sure its predictions are irreconcilable with our current observations.

It is not ruled out, as pointed out here:

http://arxiv.org/abs/hep-ph/0306245
 
  • #23
I am a novice to these parts but it is my understanding that photons themselves do NOT have mass. They appear to be packets of compressed electromagnetic waves:

-->-------\/\/\/\/\/\/\/\/--->---------\/\/\/\/\/\/\/\/\/\/\/\---->---------\/\/\/\/\/\/\/\/-->

the above is a depiction of a light ray or any electrometic ray moving to the right at a speed of c (300,000 km/sec)

The curvature of llight around the sun (as depicted by Ettinger in 1919 and some others later) was and is because of the warping of what would be a homogenous space-time frame work (i.e., 4th Dimension) by the masses in the universe, and in Ettinger's case, that mass would be the sun (and maybe even the moon as it traversed to sky above the observers.)

Since we do live in a 4-D world with time being the unseen coordinate, then the geodesics would be created due to the mass-energy effect of all bodies which have mass (and that is everything.) The universe is not homogeneous in energy-mass. Also,time, no matter what frame of reference one uses, always marches on. It never stops. There is no universal central point of time clock but in each frame of reference, the t-component is always getting longer and longer. Every world line in every frame of reference will always bend a little (meaning acceleration) and this is gravity because the world lines of "stationary" objects is always moving along the geodesic.

With regards to the black hole gravity, that would probably mean that the curvature in spacetime in that locale is so great that even the speed of light cannot escape it.

That is just my take.
 
  • #24
stevmg said:
I am a novice to these parts but it is my understanding that photons themselves do NOT have mass.
[...]
mass-energy effect of all bodies which have mass (and that is everything.)
Hmm?

Anyways, there is a difference between relativistic/gravitational and rest mass. Photons have former, but not later. I'm sure that's been mentioned in this thread already. No need for wild speculations.
 
  • #26
K^2 said:
Hmm?

Anyways, there is a difference between relativistic/gravitational and rest mass. Photons have former, but not later. I'm sure that's been mentioned in this thread already. No need for wild speculations.

Interestigly enough that if a photon does have a mass at light speed as depicted above (relativistic mass) in a mathematical sense this could be possible.

Any "real" object not in motion does have a rest mass. There is no way such an object could ever be "pushed" to relativistic speed by the now famous equation:
m = m0/[tex]\sqrt{(1 - v^2)/c^2)}[/tex] = m0[tex]\gamma[/tex]. Hence, any object at relativistic speed cannot be "derived" from any object that has mass and "lives" in subrelativistic speed because its mass would be infinite at light speed.

Any object with a mass m at subrelativistic speed mathematically an infinite mass at relativistic speed = [tex]\infty[/tex]. Any object that exists at relativistic speed with a mass of m0 would have a zero mass at subrelatistic speed. Photons only exist at the speed of light. They would have no mass subrelativistically:

[tex]\infty[/tex] [tex]\bullet[/tex] 0 = any number you want.

Remember gravity is caused by the spacetime curvature so it would appear as there is bending of the world line which means acceleration and implies mass to light or any other electromagnetic "ray."

Geroch, General Relativity from A to B
 
  • #27
Does a photon have mass? in a word, No.
Light is not a substance; light is electromagnetic energy.
a "photon" is a unit of measure of that energy. a photon is no more a particle of light than a phon is a particle of sound.
rg

if that is so then please explain the black hole phenomena.
 
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  • #28
lennyf said:
Does a photon have mass? in a word, No.
Light is not a substance; light is electromagnetic energy.
a "photon" is a unit of measure of that energy. a photon is no more a particle of light than a phon is a particle of sound.
rg

if that is so then please explain the black hole phenomena.

Never experienced it...
 
  • #29
duu57f said:
Many people have been arguing for a long time that it doesn't. Of course, they couldn't actually give solid proof for this. They based their theory on the fact that if photons had mass at rest than many laws and theories we know today would be wrong. But the question still remains, if photons have no mass at rest, then why is light sucked into black holes. I mean, if light has no mass at rest, then the concept of gravity doesn't apply to it. Also, where does all the energy and momentum come from. I know about the concept of relative mass, but still, even with this, the energy has to come from a source and in my opinion that source has to be an initial mass.

I have had these questions for a longtime.
1. Is it the photons that travel at such speed or is it that they are pulled by gravity?
2. if photons are pulled by gravity how do they retain such speed in space where G is negligible?
3. Anything that has a shape should have mass or am i simply arguing?
4. when photons collide with each other coming from straight opposite sources/directions will they disintegrate because of such enormous speeds?
5? where does all the light go if they don't have a mass they can't be sticking with something or absorbed and they should always travel if they do have mass then we can should be able to contain them. either way i still wonder where all the photons ever produced went to?
 
  • #30
First of all, photons are not "pulled" by gravity, and certainly not in the way that other objects with mass are pulled. This has already been explained in the FAQ thread in the General Physics forum. So maybe you want to start there.

This is also a rather OLD thread.

Zz.
 
  • #31
ZapperZ said:
First of all, photons are not "pulled" by gravity, and certainly not in the way that other objects with mass are pulled. This has already been explained in the FAQ thread in the General Physics forum. So maybe you want to start there.

This is also a rather OLD thread.

Zz.

"photons are not "pulled" by gravity, " Amazing and i like the way you said it and will start from where you directed though:)
 
  • #32
I came upon your forum and found the discussion on whether photons have or do not have mass stimulating.

I’m not a PHD physicist, just an elderly amateur astronomer who has always enjoyed physics, I’m not an expert on either, however, I wanted to share a small comment with the group on the subject of photons.

On one side (General Relativity), photons are said to be mass-less, on the other side, Quantum Physics (Hawking Radiation), photons, neutrinos, and electrons are said to have mass.

Recently, Brian Green release his new book “The Hidden Reality” in 2011, in that book there’s a section titled “Hawking Radiation”, in it he states the following:

“But proper treatment of matter and radiation of particles like photons, neutrinos, and electrons that can carry mass, energy, and entropy from one location to another requires quantum physics.”

So, on one hand we have mass-less photons and on the other hand we have photons that have and can carry mass.

Please forgive my lack of presentation on the subject, several years ago I fell victim to numerous strokes that resulted in a significant loss of memory, mathematics, and musical abilities, don't be too hard on me if I have it too terribly wrong.

Thank you for allowing me to post this comment.

Bob
 
  • #33
Astro9154 said:
I came upon your forum and found the discussion on whether photons have or do not have mass stimulating.

I’m not a PHD physicist, just an elderly amateur astronomer who has always enjoyed physics, I’m not an expert on either, however, I wanted to share a small comment with the group on the subject of photons.

On one side (General Relativity), photons are said to be mass-less, on the other side, Quantum Physics (Hawking Radiation), photons, neutrinos, and electrons are said to have mass.

Whoa! Back up a bit. Where in "quantum physics" did it say that photon has mass?

Recently, Brian Green release his new book “The Hidden Reality” in 2011, in that book there’s a section titled “Hawking Radiation”, in it he states the following:

“But proper treatment of matter and radiation of particles like photons, neutrinos, and electrons that can carry mass, energy, and entropy from one location to another requires quantum physics.”

Nope. You need to separate out what is accepted and verified, versus theories that are still (i) being worked on (ii) unverified (iii) still speculative.Zz.
 
  • #34
It would appear that light, as a radiant energy has two simultaneous formats (if you will)

1 - as a wave with no mass traveling through some medium - not the "ether" as disproved by Michelson & Morley in 1887 because there is no difference between light speed no matter what direction you look and the Earth is moving at 30 km/sec and there should be some shift

2 - as a particle as shown with the photo-electric effect (Einstein's Nobel Prize)

These two phenomena exist simultaneously and the energy in the electromagnetic wave can be translated into mass by the e= mc2 relationship.

Of course, the "crystallized" energy is NOT moving at the speed of light.
 
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  • #35
First you must realize that E = mc2 is not what Einstein originally wrote.
The correct equation is E subscript 0 = mc2.

In the first equation m depends on energy (on velocity) and the photon has mass.
In the second equation m is constant and the photon has no mass.

Over the years his orginal equation was changed from E subscript 0 = mc2 to E = mc2.
 
<h2>1. Do photons have mass?</h2><p>No, photons do not have mass. They are considered to be massless particles.</p><h2>2. Why is there a debate about whether photons have mass?</h2><p>The debate about whether photons have mass stems from the fact that they have energy and momentum, which are both properties typically associated with mass. However, the concept of mass in physics is more complex and can be defined in different ways, leading to differing opinions on whether photons have mass or not.</p><h2>3. How can we measure the mass of a photon?</h2><p>Since photons are massless, they cannot be measured in the traditional sense using a scale. However, their energy and momentum can be measured through experiments, and through the famous equation E=mc^2, we can calculate their "equivalent mass". This is known as the relativistic mass of a photon.</p><h2>4. What are the implications of photons having mass?</h2><p>If photons were to have mass, it would greatly impact our understanding of the fundamental laws of physics. For example, it would change the equations for energy and momentum, and would affect the behavior of light in different mediums. It could also have implications for theories such as the Standard Model and the theory of general relativity.</p><h2>5. Is there any evidence for or against photons having mass?</h2><p>Currently, there is no definitive evidence either for or against photons having mass. The debate is ongoing and there are arguments and experiments on both sides. However, the majority of scientific evidence and theories support the idea that photons are indeed massless particles.</p>

1. Do photons have mass?

No, photons do not have mass. They are considered to be massless particles.

2. Why is there a debate about whether photons have mass?

The debate about whether photons have mass stems from the fact that they have energy and momentum, which are both properties typically associated with mass. However, the concept of mass in physics is more complex and can be defined in different ways, leading to differing opinions on whether photons have mass or not.

3. How can we measure the mass of a photon?

Since photons are massless, they cannot be measured in the traditional sense using a scale. However, their energy and momentum can be measured through experiments, and through the famous equation E=mc^2, we can calculate their "equivalent mass". This is known as the relativistic mass of a photon.

4. What are the implications of photons having mass?

If photons were to have mass, it would greatly impact our understanding of the fundamental laws of physics. For example, it would change the equations for energy and momentum, and would affect the behavior of light in different mediums. It could also have implications for theories such as the Standard Model and the theory of general relativity.

5. Is there any evidence for or against photons having mass?

Currently, there is no definitive evidence either for or against photons having mass. The debate is ongoing and there are arguments and experiments on both sides. However, the majority of scientific evidence and theories support the idea that photons are indeed massless particles.

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