Unlocking the Mystery of Light Particle Mass

[jcsd]

I'm not denying that kinetic energy doesn't add to the gravitational attraction between objects, for example even photons are graviatationally attracted to and attract masses.

It's just the case nowdays 'rest mass' is much preferred by physicists as a defintion for mass and the mass of a photon is always quoted as zero.

Yes the particle will appear to be mopre graviationally attracted in S'.

 

[pmb]

Originally posted by jcsd
Yes but rest mass is more useful as it tells you how to work out the relatvistic mass in a different reference frame.

Rest mass is useful - Sure. I agree. But that doesn't mean that relativistic mass is not useful.

Weight and mass are two different things. I ignore the question, as it involves a gravitational field, which should properly be described by GR.

You did read what I wrote right? I said that they are different but are intimately related. In fact weight is defined in terms of mass.

Its extremely simple to solve this problem - trivial even. If you think in terms of relativistic mass then the answer will jump out at you - give it a try.

Imagine a simlair situation that you are traveling at a certain velocity past a neutron star, though if you measure the Chanderskar limit using relativistic mass you may find that the neutron star shoukld collapse into a balck hole, but it doesn't.

That's not correct. The Chandrasekhar limit is an invariant quantity. It's not something that depends on the frame of referance to measure. You must be thinking about the mass of a black hole and if mass increases then it must form a black hole - That's a poor way of looking at it - the Chandrasekhar limit is a scalar - it refers to rest mass - not relativistic mass.

However the intensity of a gravitational field increases with speed - not something one would guess if youy just say that mass does not increase with speed.

Pmb

 

[pmb]

It's just the case nowdays 'rest mass' is much preferred by physicists as a defintion for mass and the mass of a photon is always quoted as zero.

That depends on the physicist. If one is a particle physicists then I don't see why they'd want to use relativistic mass. That's not what a particle physicists studies. They study intrinsic properties of particles. For example: You'll never see the lifetime of a neutron stated as anything but 15 minutes. But that doesn't mean the lifetime increases the faster the particle moves.

However if one is into other areas of relativity then this changes. Then it finds more use. For example: if you were studying the inertial properties of a charged capacitor then you can't think in terms of rest mass or relativistic mass exclusively - both mass and energy are fully described by a second rank tensor.

Pmb

 

[marcus]

Hello Pete,
if possible I would like to contribute to making peace (as an independent agent, speaking solely for myself) and also to lend support both to minority rights and clear communication.

Ive appreciated a number of your posts---especially those which didnt depend on using the "relativistic mass" concept---and I recognize your good humor, broad knowledge, and intelligence.

The troubling issue is the DEFAULT meaning (absent some special redefintion) and the issue of proselytizing.

It is pretty clear that the majority meaning of mass, these days, is the body's "inertia at rest", and that the photon has zero mass.
It is also pretty clear that people don't want some zealous missionary coming in and trying to change the way they talk.

Tom, a working physicist I gather, has come down unequivocally on this issue. A majority of the trained people actually doing physics have dropped the "relativistic mass" idea because it is confusing or because it's awkward in a QFT context----or for the reasons Lev Okun gave in that landmark Physics Today 1989 article which you know well. Or perhaps out of respect for Einstein, who advised against using the "relativistic mass" idea.

But indeed Rindler (an eminent guy of approx. emeritus age) did
answer Okun back and give arguments favoring "relativistic mass" and moreover Rindler did come out with a 2001 edition of his book. And so on. There are respectable recent instances for you to cite. And people can't be expected to be 100% consistent.
But this doesn't change the basic linguistic picture, as I see it anyway.

I value your posts a lot and just hope that when you use the
"relativistic mass" idea you make that explicit and do not suggest that it is the predominant concept or that people should change back to using it as the default.

Quite a number of people at PF have remonstrated with you and argued with you about this, including me, and now jcsd is having the same discussion. But folks get tired of arguing, so I have been avoiding threads where you talk about mass. Jcsd SHOULD be supported in upholding the majority usage of a word, for the sake of clear communication. But if my feelings are any guide, I guess people don't want to get into it with you because it leads to just one more repetitive and useless argument.

Anyway here is the standard view of mass one more time: mass is inertia (a force per acceleration idea).
Force and acceleration are primitive measurable quantities, so inertia is right down there with the most nitty-gritty concrete measurable un-theory-dependent ideas. It is good to have some
foundations-type ideas that have clear operational meaning and don't change every time you change your theory and upgrade and so on.
People can argue about what energy is and it depends to some extent on what theory they are using and theories change, and
energy is not so directly measurable----because more abstract and general---different kinds of it.
So it is a really bad idea to confuse inertia with energy. Inertia is primitive and un-abstract. Energy is something you have to calculate based on some formulas that seem to be valid.

So a lot of people, myself included, have a strong linguistic preference---almost you could say an instinct---to keep it simple and reserve mass to mean inertia.

Not the least of them being Einstein-----BTW his 1905 paper calls it "inertia" as I recall. I think the word "inertia" even occurs in the title, instead of mass. Maybe I can get the German title of the original E=mc² 1905 paper and edit it in.

YES BY JOVE! The German title of his 1905 article Annalen der Physik volume 18 page 639 was
"Ist die Traegheit eines Koerpers von seinem Energiegehalt abhaengig?"

"Is the Inertia of a Body on it's Energy-content dependent?"

And this was where the E=mc² formula first appeared, except that, interestingly enough, he wrote it
m = L/c²

Traegheit (the word Einstein used) is a wonderful German word
meaning laziness, sluggishness, indolence, slow-to-get-started, and (in physics) resistance to acceleration.

I guess the English cognate would be "Drag-hood" or "Drag-ness" except that Traege does not mean Drag but rather
lazy, sluggish, indolent, inert, dull etc.

"Is the Sluggishness of a Body on its Energy-content dependent?"

Great language, the concretness compared with english can be stunning.

 

[pmb]

if possible I would like to contribute to making peace (as an independent agent, speaking solely for myself) and also to lend support both to minority rights and clear communication.

Peace? I didn't know it was missing? To me this is just a friendly conversation.

The troubling issue is the DEFAULT meaning (absent some special redefintion) and the issue of proselytizing.

That's because I don't believe that its true. In fact observation tells me otherwise. Just look in

assets.cambridge.org/0521422701/sample/0521422701WS.pdf

for a counter example. On page 18 Peacock uses the term "mass" and he does **not** mean rest mass. I've looked at many relativity texts, new and old, various physics journals, many online lecture notes from many universities across the world as well as spoken directly to many physics teachers. The opinions are diverse and can hardly be predicted never mind counted.

It is pretty clear that the majority meaning of mass, these days, is the body's "inertia at rest", and that the photon has zero mass.
It is also pretty clear that people don't want some zealous missionary coming in and trying to change the way they talk.

You're putting words into my mouth. I've never tried to convince anyone of any such thing. What I've done is point out facts when I've seen statements made which were not true. For example: I have one text which doesn't use the term "mass" exclusively to mean "rest mass." That's Ohanian's text. Others are not always consistent - MTW is a good example. While they use the term 'mass' to mean 'rest mass' almost exclusively they use the term 'mass' to mean what you call relativistic mass. And that's used to prove that T^0j = T^j0

Tom, a working physicist I gather, has come down unequivocally on this issue. A majority of the trained people actually doing physics have dropped the "relativistic mass" idea because it is confusing or because it's awkward in a QFT context----or for the reasons Lev Okun gave in that landmark Physics Today 1989 article which you know well. Or perhaps out of respect for Einstein, who advised against using the "relativistic mass" idea.

And I'm a physicist as well. I choose otherwise. I don't see why everyone should have the same opinion anyway. In fact I think it'd ve an extremely bad idea if I just ignored what I believe to be erroneous comments just because somone else doesn't want to to correct them. In this case the comment was made that no physicists and no journal article uses the term 'mass' to mean 'relativistic mass.' I've read many articles to the contrary. Rorhlich comes to mind off hand.

Lev Okun has made some serious errors in that paper. In fact I believe all of his arguements are flawed. And as far as Einstein goes - that famous comment that's always quoted is decieving. He did mean it for particles with non-zero rest mass. However he did not mean it to apply to light. Einstein himself used the concept of 'relativistic mass' in several of his most important and most widely known papers.

I value your posts a lot and just hope that when you use the
"relativistic mass" idea you make that explicit and do not suggest that it is the predominant concept or that people should change back to using it as the default.

What's the point of any of this? If I'm going to answer a question someone asks then I'm going to as precise as I can and use terms which I choose and not terms which Lev Okun has chosen for me. Expecially due to the fact that each of his arguements are wrong.

Quite a number of people at PF have remonstrated with you and argued with you about this, including me, and now jcsd is having the same discussion. But folks get tired of arguing, so I have been avoiding threads where you talk about mass.

You do understand that this is a discussion forum don't you? I'm not about to cease thinking the way I do because somone doesn't like a particular idea. Nobody has to discuss anything with me in fact. In fact they can just not respond.

Jcsd SHOULD be supported in upholding the majority usage of a word, for the sake of clear communication.

You've never really answered my question as to why you think that this is how the majority uses the term or why it matters what the majority does. Take a particular student - convince him that whenever he sees the term "mass" that it means "rest mass." Then how do you expect him to react when he picks upp a journal and its not used that way? We don't know who we are discussing physics with. We don't know if a particular person will want to be a particle physicists or a cosmologist. And these two groups do not use the term in the same way.

Not the least of them being Einstein-----BTW his 1905 paper calls it "inertia" as I recall. I think the word "inertia" even occurs in the title, instead of mass. Maybe I can get the German title of the original E=mc² 1905 paper and edit it in.

Speaking of which - have you read Schutz's text on general relativity? He clearly and explicitly states that "inertial mass" is frame dependant.

So long story short - I will not hesitate to correct a statement that I believe to be in error. And its not very productive to try to force others not to post ideas which they don't agree with.

By the way - Can provide proof that 99% of all physics literature (journals text etc) after 1989 use mass to mean "rest mass"? Please explain why you think most people think that way when it's quite clear that many people don't. Frankly I don't see how its possible to arrive at such a conclusion since there are millions of physicists and hundreds if not thousands of physics journals - and that's not even mentioning astronomy texts.


But here - take a browse and see
http://www.geocities.com/physics_world/relativistic_mass.htm

That's a short list. I've also seen physicists at Oxford University and Harvard University do the same thing.

There are physicists who agree with me on this point about light. E.g. From
http://www.astro.washington.edu/tmurphy/phys110/faqs/AB05.05.html

But the most honest answer to your question is yes--light has mass.

Same with mass
http://www.phys.virginia.edu/classes/109N/lectures/mass_increase.html

Mass Really Does Increase with Speed

I just happened to run across another example where the term "mass" is used and the context dictates that this mass is relativistic mass. It's in Peacock's text "Cosmological Physics." On page 18 Peacock explains the energy-momentum tensor

T^00 = c^2 x (mass density) = energy density
[...]
Both momentum density and energy flux density are the product of mass density and a net velocity,..

The terms used here mean "relativistic mass" and **not** "rest mass."

The section in which this comes from is actually online so you can check it out for yourself.
http://assets.cambridge.org/0521422701/sample/0521422701WS.pdf

This text is used in Edmund Bertschinger's cosmology course at MIT.


Pmb

 

[pmb]

Originally posted by marcus
..defined one way the "relativistic mass" of some light would be infinite if the light had any mass to begin with and defined another way the "relativistic mass" is just a redundant jargon synonym for the energy of the light and is not infinite but simply E/c².

The relation

m = m_o/sqrt[1-(v/c)^2]

Applies only to particles with non-zero rest mass. This follows from the definition of relativistic mass which is the m in p = mv. The relation p = mv holds in all cases. If the particle has a non-zero rest mass then it can be shown the m is as above. But to try to apply the relation above to light is an error. To use relativistic mass consistenty then one must rever to the definition of relativistic mass and that's the ratio of momentum to velocity (magnitudes of course).

Also - relativist mass is defined according to momentum and speed. The fact the energy is proportional to it does not mean its redunant. It's just a law of nature. In fact it would be incorrect to refer to relativist mass as energy since energy, unqualified, should only mean total energy E which is the sum of kinetic energy, rest energy and potential energy. The E in E = mc^2 is the total energy of a free-particle and not energy (as in total energy). Unfortunately the term "total energy" is an overloaded term since people use it in some cases to mean free-particle energy and in other cases to mean sum of kinetic energy, rest energy and potential energy.

Pmb

 

[theriddler876]

ummm I think that light or any energy on the electromagnetic specturm could be a sub-sub atomic particle,

say you have a radioactive substance giving off just gamma radiation, one would say that gamma has no mass and no charge, but eventually after giving enough gamma radiation it will change composition, now how can it change if it's fundamentally giving nothing, I mean I can give you a whole lot of nothing and still have some left and I wouln't change because I gave you nothing right..? so say eventually an element changed to one that was equal to one atomic number less, assuming it's neutral, then it would have lost an electron and a proton, so, perhaps radiation is made of the particles that make up a proton and electrons, which would mean the mass could be calculated by how long it takes for an amount of an element giving off gamma radiation to change, and it would be a ratio of time it takes, to amount ,or mass of the change.

 

[pmb]

Originally posted by theriddler876
ummm I think that light or any energy on the electromagnetic specturm could be a sub-sub atomic particle,..

Did someone say it wasn't? If so then its not considered a sub-atomic particle since its never actually part of an atom or nuclei. You can't crack open an atom/nucleaus and find a photon.

say you have a radioactive substance giving off just gamma radiation, one would say that gamma has no mass and no charge,..

A photon has no rest mass. However it does have mass as in mass-energy. To see what that means exactly read the following two pages
http://www.geocities.com/physics_world/sr/mass_energy_equiv.htm
http://www.geocities.com/physics_world/sr/nuclear_energy.htm

The first link has the same spirit as Einstein's first derivation except this one is more straightforward. See also
http://arxiv.org/ftp/physics/papers/0308/0308039.pdf
And note that this "mass" is the m in p = mv. So anything with momentum will have mass and light has momentum. As a quantity radiates it gives off radiation and its rest mass decreases. If the body is in motion then its momentum decreases as so does its mass-energy.

Pmb

 

[theriddler876]

well if the photon is a particle, would it still be governed by conventional laws, I.E. would it slow down and stop at absolute zero, since hypothetically a super strong grativational field affects it

 

[theriddler876]

Originally posted by pmb
You can't crack open an atom/nucleaus and find a photon.
Pmb

I was referring more like cracking open a neutron, and finding a photon, or even cracking open what we find when we crack open a neutron, and finding a photon,

According to the law of conservation of mas if you have an element to start with, if it gives off alpha, then it has lost four mass, and two atomic #, but if it gives of gamma, it has lost neither mass nor, an atomic #, like I said I could give you nothing and still have some left, however, if an element gives enough gamma, or "nothing" it will change in composition, until it becomes stable

 

[pmb]

Originally posted by theriddler876
well if the photon is a particle, would it still be governed by conventional laws, I.E. would it slow down and stop at absolute zero, since hypothetically a super strong grativational field affects it

That is untrue. There's no reason to assume that a photon behaves inertial like, say, and electron. One can't assert an electric force on a photon. However one can assert a gravitational force on a photon. And a photon in a gravitational field changes speed.

Pete

 

[pmb]

Originally posted by theriddler876
I was referring more like cracking open a neutron, and finding a photon, or even cracking open what we find when we crack open a neutron, and finding a photon,..

Actually that was how the term "photon" was first used. However it became clear that this was wrong.

According to the law of conservation of mas if you have an element to start with, if it gives off alpha, then it has lost four mass, and two atomic #, but if it gives of gamma, it has lost neither mass ..

That is not true. If a nucleus emits a gamma ray its mass **will** decrease.

What is "four mass."?

Pete

 

[theriddler876]

Well photons are not affected by an electrical forces because they Have no charge, however plasma, a fourth state of matter can be created with extreme electrical forces, such as lightning

And the electromagnetic spectrum would all be photons, just at diffrent wavelenghts

and that's was what I was saying, that it will decrease, however according to the law of conservation of mass, it shouln't, since the mass and charge of gamma are zero and atomic number and mass should be conserved

what I meant by four mass was

244Pu ----> 4Hg + 240 U
94 2 92

If you add the two, you will get that the mass and atomic number are conserved,

 

[pmb]

You're using the term "mass" in two different ways in the exact same sentance. The term "mass" has two different meanings. (If can mean m = "relativistic mass" and it can mean m_o = "proper mass" (aka "rest mass"). The proper mass, m_o, of a particle is defined in terms of the particle's free-particle energy, E, and the particle's momentum, p. They are related as

E^2 - (pc)^2 = m_o^2 c^4

m is defined as the "m" in p = mv (there is a more precise definition but this is good enough for now). It can be shown that for partilces for which m_o is not zero

m = m_o/sqrt[1-(v/c)^2]


It also follows that E = mc^2

what I meant by four mass was

244Pu ----> 4Hg + 240 U
94 2 92

If you add the two, you will get that the mass and atomic number are conserved,

In this reaction m is conservered (for the same reason energy is conserved). Not m_o. I.e. the sum of the m's are constant and the sum of the m_o's is not constant.

Not that mass is conserved when there are no external forces acting on the particle. If there is then the particle will change its velocity and the mass will change. The particle exchanges energy and momentum with the source of the force.

For a worked out example of how mass is conserved in a nuclear reaction see
http://www.geocities.com/physics_world/sr/nuclear_energy.htm

Pmb

 

[theriddler876]

well a photon would have no rest mass, well we just can measure it, since it is constantly moving however if it is a particle, then it can be stopped, probably by an extreme gravity field, and relative mass is just that, it's relative, a better way to measure it would be in quanta,

say it takes 10 seconds of light shining on a metal to give off one electron, if you know the frequency, then you can find the amount of mass, in relation to the electron, per wave, does that make sense?