I knew it! I leave this topic over night, and it get filled with appalling errors, muddled explanations and mysticism!
Blinded: you've been fed rubbish. I'll post clarity separately.
The Hall of Shame:
First off, me! (oh the shame!):
Spaceman Spiff wrote:Particles of light, photons, do travel at the speed of light. They have no kinetic energy because they have no inertial mass, ...
I should have written 'rest' mass, not 'inertial' mass. Bad!
d.m.falk wrote:But photons do have mass, with its observable effects- Recoil, decay, gravitationally lensing or bending, and resistance to medium density. (That is, light slows down in an atmosphere, and moreso in fluids and solids.)
The fact that photons are observed to have momentum is not inconsistent with Einstein's Special Relativity theory. It simply holds that phtotns have no rest mess, and that it is the energy of the photon that contains its mass. Gravitational bending of light is stated to be due to light following goedesic curves through warped spacetime, influenced by the mass of a body different from the photon (e.g., a galaxy): it is not the mass of the photon (that is, its energy) that causes the photon to be pulled by gravity. If one says this, one returns to the Newtownian model, and one is back to having the Principle of Equivalence unexplained again, something which Einstein's General Relativity does admirably.
What does 'resistance to medium density' mean? The slowing of light in media is nothing to do with photons having mass. It is to do with an increased electric permittivity of the medium.
d.m.falk wrote:If photons have no mass, they cannot have any energy, ...
In which you seem to follow the masses in misunderstanding that only rest mass is the subject of the
E =
mc?? equation. It is the energy of the photon that has mass.
d.m.falk wrote:The speed of light is also not infinite, but actually rather slow; however, our present understanding of physics has difficulties grasping that it isn't, and may, with much reluctance, require revision of standard theories to account for observed anomalies that appear to defy long-held theory.
Speak for yourself! What is the difficulty with modern physics over a finite speed of light? This has been know since R??mer. What are the observed anomalies?
If you bother to read and understand what you found, you'd notice that this paper is posting a reduced
upper limit to photon rest mass from experimental observations. Fridger has put the exact right notion to you about how to deal with evaluating the theoretical notion of photons having zero rest mass. This link you post is a precise example of that. It does
not say that photons are found to have finite (non-vanishing) rest mass.
d.m.falk wrote:And I never said his theory was fundamentally wrong; only that the conclusion is incorrect.
What is the conclusion that is incorrect (with Einstein's Special Relativity theory)?
d.m.falk wrote:And thus you hit on what I was saying in the first place: The continuous attempts to fit the anomalous nature of photons within Einstein's Theory of Special Relativity, rather than trying to quantise the nature of photons themselves. A better way of putting it is that Einstein was on the right track, but came up with the wrong conclusion. Yes, photons have energy, and thus they have mass. This is observable, and has been measured. However, it conflicts with Einstein, and just as you observed, you can't really have something from nothing- The exchange between mass and energy exists on all levels. A photon's mass is just marginally above that of a quark's. Heck, I'd even say that it's best to state that mass and energy are just two states of matter, which would be accurate, giving the mutual exchange that usually results between both, and the energy for the exchange is subtracted from the total.
You don't list the anomalies. Thus I see no conflict, except your misunderstanding of relativity compared to what Einstein meant. The photon's mass comes from its electrical energy - it is carrying electrical energy from one place to another. The energy has mass. You use Einstein's
E =
mc?? equation to find out what that is, and that is the mass of the photon. What on Earth you mean by 'A photon's mass is just marginally above that of a quark's.'? There are six quarks and they have extremely different masses. You can make a photon much heavier or lighter simply by increasing or decreasing the photon's frequency, hence energy. It's arbitrary.
d.m.falk wrote:Even the most basic of mathematics will tell you that anything multiplied or divided by zero is zero.
d.m.falk wrote:If you devide by 2, you have two equal products totaling the original value. If you devide by 1, you have a single product, equal to the original value. If you divide by zero, you have no products divided from the original. Anything divided by 0 is 0. There is no product.
Gak! You achieve F-!! A blatant crime against scientific orthodoxy!!! Back to school for indoctrination again!!!!
No. If you divide by 2, you have two equal products, each equaling half the total, totalling the original value. So, if you divide by half, you have half a product equaling twice the value of the original, totalling the original value? You get the total by multiplying the half with the twice, or multiplying the twice with the half? Why allow division by two, not half? So there
is a product, because multiplication is the inverse function of division. But, if you divide by zero, you have zero products each equaling infinity times the total. This does not necessarily equal zero.
Don't believe me? So, tell me why does sinc(
x) = 1 when
x = 0, and not zero ?
Surprise: zero times something only equals zero if something is a number. Infinity is not a number, it's a concept. Zero times infinity is not necessarily zero. Otherwise you can all go back to that Equation 1 of Cham's and be happy that you can set
m0 to zero, and pull out zero kinetic energy for all photons. The conclusion is true, but this is not the mathematical proof of it.
And. A number divided by zero may be zero, it may not be zero. All that oddities like this tell you is that you have to use a different way to find the result... Look up sinc(
x) = 1 for
x = 0.
d.m.falk wrote:Actually, "no product" is just that, since it's an absolute, and not a relative, statement.
I bet calculus is beyond you: "so if I divide the area under the curve into strips of zero width, then there's none of them, and I can't add them up into the finite area under the curve? <scratches head>".
Calculus is an excellent mathematical method that divides an area under a curve into an infinite amount of infinitesimally thin strips and adds them up to a finite area. But not necessarily zero.
d.m.falk wrote:We know now that all particles have mass, and all forces do not.
Gak! Again! Pointless comment: energy has mass, whatever type it is: kinetic, gravitational potential, electrical, or that 'frozen' kind referred to by the term 'rest mass'. All particles have energy in some form. This energy has mass. All particles have mass. The point is: do all particles have 'rest mass'. Answer: to date: 'NO!'. Example: photon. Has mass (due to its energy), has no rest mass (thus travels at
c). Photons are the
force carrier particles of electromagnetism. Which brings me to:
d.m.falk wrote:Gluons do not, however, because they're not particles, but rather forces.
Gak! Yet again! Gluons
are particles: they are the
force carrier particles of the strong nuclear force. They have mass! They even have rest mass. That's why they decay and don't get far outside the nucleons: they don't travel at the speed of light, don't have time dilated to zero, and we can catch them decaying.
Cham wrote:When Einstein made his special relativity theory, the photon wasn't yet known at that time. Light was only of a wave nature, until Einstein himself suggested its quantum nature.
d.m.falk wrote:Nope. It's defined as a quantum particle, with the characteristics of both a wave and a particle- Even Einstein realised this some years after the Theory of Special Relatiivity he proposed.
Nooo! Both wrong!! Einstein published his paper on the Photoelectric Effect in 1905, the same year he published Special Relativity. In it, he proposed light as a quantum particle right there and then. It is that very
photoelectric effect paper he was awarded the Nobel Prize for. Please!
d.m.falk wrote:Photons have observed, measured masses, but the value is far, far less than that of even an electron.
Gaa-a-ak! Have you not heard of Compton scattering? The measured mass of high energy gamma rays far exceeds the (rest) mass of an electron. Why do you supposed the annihilation of electrons with positrons generates two gamma rays each of energy 511keV? And do you suppose it's a coincidence that the summed mass of the energy of those two gamma rays happens to equal the summed rest masses of the electron and positron?
d.m.falk wrote:Short answer: No. Magnetism is a force not carried by any particle, but are emitted by elecvtrons. (Some atoms are more magnetic than others.)
We call it the "electromagnetic spectrum" because photons are the products of the interactions between electrons and their magnetic forces.
&^%$??&*9! NOOOO! Magnetism is predicted by Special Relativity as an apparent reduction of an electron charge relative to its mass (by the Lorentz transform) when it has a relative velocity to other charged particles! Magnetism is therefore just a relativisitic effect of electricity. Maxwell's equations are predicted by Einstein's theory of Special Relativity.
No wonder Fridger has written in CAPITALS LETTERS AGAIN!
Cham wrote:Today, relativity theory strongly suggest (but doesn't prove) that photons should travel at the velocity "c". But the theory can easily accept the other way (v < c) if experiment gives a tiny mass to the photon. It just happened, historically, that Einstein discovered the "c" constant inscribed in vacuo using the properties of light, but this is just an happy coincidence.
No no no! This is completely back to front. Einstein took it as the
starting assumption to the theory of Special Relativity that light would always appear to travel at the same speed in a vacuum,
c. It does not predict it, it assumes it. Special Relativity makes predictions from the assumption. Details about Cherenkov radiation for when matter exceeds the
local speed of light in media is irrelevant. The value of
c comes from the values for the electrical permittivity and magnetic permeability of free space:
c = 1 / ??? (
?µ0??0 ). Nothing more, nothing less. Einstein, Maxwell and others were well aware of this.
Cham wrote:Equation (1) DEFINES what is "relativistic mass" of a particle.
It really means this: if you observe and weigh a particle 'at rest' (relative to yourself*) and find it to have a mass
m0 (the 'rest mass'), then if you observe and weigh it again when it travels at speed
v relative to you, it will appear to have a total mass ('relativisitic mass') of
m, which is
m0 modified by the Lorentz transform. This is because according to Special Relativity, the kinetic energy
Ek shoved into the particle with non-zero rest mass (a 'massive particle') also has mass:
m =
Ek/
c??.
Cham wrote:Equation (2) ... WHEN APPLIED TO A MASSIVE PARTICLE such an electron.
No. It applies to all forms of energy and mass. A photon has a quantum of energy,
E, the energy has a mass of
m =
E/
c??. That gives the photon its apparent mass, and momentum.
Cham wrote:Equation (3) is exact for any massive particle. It doesnt apply to a photon, because of equation (1) !
Equation 3
does apply to a photon, and Equation 6 proves it. Equate Equations 2 and 5, rearrange for
m, substitute into Eq. 3 while setting
v =
c, you get Eq. 6. QED.
Equation 4: you're making this up!
Equations 5 and 6, OK.
Equation 7. No, the equation is correct, especially since you do as Einstein suggests and use the Lorentz transform: substitute
??m0 for
m. It would have been wrong if you put just
m0 in there instead. Bear in mind this equation is a definition, not a 'law of physics': Newton's first and third laws of motion are just definitions, only the second is a 'law'.
Cham wrote:The only error is the interpretation of m_0. It isn't "Mass initial of something". It's the "proper mass", "true mass", "intrinsic mass" of the particle.
No.
m0 does have a very precise physical meaning: it is the special case of what a particle's mass is measured to be by you when it has
zero relative velocity to you. For that reason, it has been called the 'rest mass' even though you could not tell whether you and it are truly at absolute rest. It's also the massof an amoutn of energy one would think is tied up in a non-kinetic form in a particle. Yet, kinetic energy and rest mass energy actually change when both the particle and measurer are travelling together at a different speed. If a laboratory was rushing at 87% the speed of light from we on Earth, and both the lab and we measured the mass of an electron, the lab would find the mass of the electron to be the same as its published rest mass, because as far as the lab is concerned, the electron is at rest. We would find the electron to be twice as heavy, because the kinetic energy of that electron now has a mass equal to the rest mass of an electron.
Other matters I should tidy up...
Cham wrote:Photons DO have kinetic energy : K = h f, where "f" is the frequency and "h" is Planck's constant. However, The relativistic Newton equation do not apply to them as photons do not have an intrinsic mass.
No, this energy is not kinetic, it is electromagnetic. A photon carries an amount of electromagnetic force, hence electromagnetic energy.
As for the 'relativistic Newtonian' equation for kinetic energy, is does not apply to photons simply because the Lorentz transform term: 1 / ??? ( 1 -
v?? /
c?? ) is undefined when
v =
c. That is all.
Cham wrote:The photon interference is a pure quantum phenomenon and has nothing to do with special relativity (to which photons are just particles).
Are you thinking of interference patterns with Young's slits? What is it about quantum mechanics that explains why photons can still interfere when the light level is turned down so low that there can only be one photon at a time between the slits and the image? I'm curious about knowing whether the 'relativisitic' explanation of timelessness has any feasibility behind it.
Cham wrote:We know it's not just the electrical charge, it's not the spin, it's ... something else.
Great! How do we know this?
Spiff.
* How can you tell if you really are stationary? You can't. I suspect that the reason why the term 'rest mass' is being phased out is because you cannot prove you are at (absolute) rest, so it's misleading in that sense. Yet, no matter how fast you and the particle travel (but you always travel at less than
c), so long as your relative velocity is zero, its measured mass will always appear to you to be that rest mass. Remember,
v is relative to your own reference frame, not absolute stop! That's why the theory is called relativity theory.
DO NOT HAVE ANY PHYSICAL MEANING. IT IS USELESS AND A STRONG SOURCE OF CONFUSION. It should simply be banished from all discussions on relativity theory and especially from vulgarisation articles. That quantity "m" ISN'T OBSERVABLE. What is increasing with velocity is the Kinetic Energy, not mass. As I have shown previously, the "m" may be eliminated from all equations. And it even don't shows without ambiguity in the relativistic Newton equation :
