Can only photons travel at c?

In summary, the conversation discusses the speed of light and whether particles with mass can travel at the speed of light. It is mentioned that neutrinos and gluons, particles without mass, are able to travel at the speed of light. However, there is uncertainty about whether neutrinos actually have mass. The conversation also touches on the concept of the speed of light as an upper limit for the rate at which information can travel and the possibility of redefining it. There is also a mention of a theoretical particle that may travel faster than the speed of light. The conversation ends with a discussion about the Cherenkov effect and how particles can exceed the speed of light in certain mediums.
  • #1
brum
81
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can only photons travel at the speed of light?

can a particle that has mass travel at c?
 
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  • #2
No, a particle with mass cannot move at the speed of light.
 
  • #3
ok, so are there any other particles that are massless, besides photons, that can travel at c?
 
  • #4
Neturinos, if you believe in them...
 
  • #5
I would hold back on any difinite answer of yes or no. I'm not comepletely convinced anymore that any particle has mass, or even that there is such a thing as a paticle at all. At least not in the way we might normally think of a particle as being.

Hows that for covering the bases to confusion.
 
  • #6
what exactly is your working definition for mass
 
  • #7
dave,

why don't you believe neutrinos exsist?

pete
 
  • #8
Neutrinos have been found to have mass.

The strong force carriers, gluons, are the other massless particles in the Standard Model.
 
  • #9
Originally posted by Dave
Neturinos, if you believe in them...

It's not known for sure if neutrinos have a non-zero proper mass.

Pete
 
  • #10
Selfadjoint is correct, latest studies have found neutrinos to have mass. Which would mean it can't be going the speed of light.

Pete
 
  • #11
There is at the moment no final word on whether neutrinos have mass or not (though they are considered a good candidate for the WIMPs that must make up non-baryonic dark matter). Again, if they can travel at light speed or nopt is unknown (they have even been suggested as possible candidates for tachyons).
 
  • #12
Uhm, didn't they determine gravity moved at the speed of light? If so I suppose a gravity particle would as well, if there is such a thing.
 
  • #13
Well those results are now being disputed bya Post Doc at Cal Tech. And I would have to agree they made many many assumptions to get their results.

Pete
 
  • #14
hehe
is photons travel in the speed of light?what is the difinition of the speed of light? isn't the speed of the free photons?
do photon have mass? if not, why there is the effect of the light pressure? and i think it has ,and i think the mass is the carrier of momentum and energy.
and i think if we redifine a limit of speed(theoretical light speed?) ,the speed of photons cannot make it,and all things or particles cannot
 
  • #15
Many questions...

Originally posted by leoant
hehe
is photons travel in the speed of light?what is the difinition of the speed of light? isn't the speed of the free photons?
do photon have mass? if not, why there is the effect of the light pressure? and i think it has ,and i think the mass is the carrier of momentum and energy.
and i think if we redifine a limit of speed(theoretical light speed?) ,the speed of photons cannot make it,and all things or particles cannot

You shouldn't think of the "speed of light" as JUST being the speed at which photons travel, I would suggest you think of it more generally. The speed of light is an upper-limit on the rate at which INFORMATION can travel, where information is being used in a broad sense.

Although photons have absolutely zero mass, yes they do have momentum associated with them. The amount of momentum a single photon carries is related to its wavevector, or frequency, or wavelength (although talking about "frequency" / "wavelength" and "photon" simultaneously kind of mixes up its wave and particle properties simultaneously). An easy way to understand why they have ENERGY associated with them is by considering the time-average power associated with the electric and magnetic fields that self-perpetuate as an EM wave (or series of photons) travels.

With regards to explaining why photons have momentum (LINEAR MOMENTUM), I can simply tell you that the math. tells us this is the way it must be. When you solve Schrodinger's equation using time-dependent perturbation theory for an atom in the excited state, when the atom decays to the ground state emitting a photon, the centre of mass of the atom recoils (thus to conserve momentum, the photon MUST carry linear momentum).

In addition, photons have ANGULAR MOMENTUM. This can be seen in many optics experiments, and especially in spectroscopy (atoms obey dipole "selection rules" that would only be possible to fulfil if photons carried angular momentum).

I am not sure how to respond to the rest of your questions...you may want to sleep on the idea of redefining the speed of light - most people like the current definition.
 
  • #16
I have heard of a type of theoretical particle that travels faster than the speed of light; but only remembr vague details about it.. It is not the neutrino, some of which do have mass,; but something else.
 
  • #17
As far as c being the upper limit for travel of information, what about quantum entaglement? I'm not an expert, but I believe the flavor of the concept is that when two quantum particles interact, their respective wave functions become 'attached' such that when you collapse the wave function of one by taking a measurement on it, the wave function of the other is collapsed simultaneously and <i>instantaneously</i>, regardless of distance. Therefore quantum entaglement is an example of information traveling faster than c, in fact, traveling with infinite speed since the transmission of information takes no time at all.
 
  • #18
You people are smarter than i, but what about the Cherenkov effect - y'know the blue glow you get with tank reactors ATL, caused by particles hitting c like a plane hits mach 1 and you get a shock wave.

correct me if I'm wrong, but doesn't that prove that they exceed c. I believe that a similar idea is used to prove neutrinos exist,
 
  • #19
Remember now, we are specifically talking about the speed of light in a vacuum. It is common place for particles to travel faster than light in a certain medium. For example in nuclear pool reactors. Neutrons shoot through water faster than light can and thus emit a blue glow (in water) known as Cerenkov radiation. Information can be sent faster than light also but only by quantum physics, this has been shown by sending a music modulated microwave beam into a quantum barrier. On the other side of the barrier is an extremely sensitive detector witch detects microwave photons that tunnel through space and arrive at the other side unblocked by the barrier (usually a sheet of metal) using very large bandwith O-scopes scientists have shown that they can send nusic up to 4+ times the speed of light. Although technicly that is cheating because the photons simply travel less distance since they tunnel through space traveling less distance.

As far as explaining why only massless particles can travel at C, it is because the faster you go, the more energy is required to achieve a higher acceleration. The curve that describes the energy required to accelerate at the same rate is exponential. The curve climbs in steepness rapidly (x^2) and you will approach infinity as to reach the top you would have to eiter have a given amount of energy exerting a velocity on the object for an infinite amount of time to reach C or you could have your energy reach infinite, climbingin speed till you are just under the speed of light. To send matter to the top where the slope of the line is undefined it takes an infinite amount of energy just to achieve C

I would like someone to try and exert an infinite amount of anything on any object. You will see that no amount of work will let you achieve infinity :-p .

Anyways if you take the time to work out the gamma in a relitivistic equation for acceleration to the speed of light you will see that gamma (speed at witch delta (increase of slope)changes) will climb to as high a number as you want it to, still working out the formulas with any mass will still require an infinite amount of energy or time to reach C.
 
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  • #20
hmm...
if it is impossible for a particle with mass to achieve the speed of light, then how is it possible for a mass-possessing neutron to exceed c?
 
  • #21
another clarification if you please...
from my understanding, the instantaneous information transfer of quantum entanglement does not involve tunneling through space, since collapsing the wave function of particle A will simultaneously collapse the wave funcion of B regardless of distance. Tunneling seems inadequate to describe this phenomena unless there is some way in which A and B are already directly connected through just such sort of a tunnel through space.
 
  • #22
Ok, I'm sorry if I confused you a bit there, I understand quantum wave/particle duality and entanglement but didn't want to go into the gory details above since I felt that the simple explination showed the possible applications for it to send signals faster than light. Anyways, The neutrons witch do have mass do not exceed C, C is the constant speed an EM wave will travel at through a vacuum. The constant for light traveling in diffrent mediums such as water is know, and it is known that neutrons flung out from nuclear reactions exceed this speed often enough for the water to emit a bluish glow.
 
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  • #23
oops, thanks for the clarification. I see now that what you said initially made sense.
As for the entaglement thing... I wouldn't mind listening to the gory details if you wouldn't mind telling them.
 
  • #24
Corrections

I wanted to correct some of the statements others have made and answer a few of the questions that came up in response to particles traveling faster than c. Some of these answer have already been clarified by Peter_C. Note that I am NOT answering any of these questions based on a "guess" or a cool dream I had or an Isaac Asimov book. If I am unsure, I will let you know and not mislead anyone. Also, please correct me if I am wrong.

1.
"a type of theoretical particle that can travel faster than c"

These particles are indeed theoretical, in the sense that someone conceived of them simply to make physics look more symmetrical. These particles are called "tachyons" and have NEGATIVE MASS. Note that this hypothetical negative mass is DIFFERENT from the negative EFFECTIVE mass you define in a crystal lattice for electrons and holes. I will stress that, to the best of my knowledge, there is NO THEORETICAL EVIDENCE to support their existence.


2.
"quantum entanglement being interpretted as an instance in which information travels faster than c"

The relevant theory explaining this is called EPR (Einstein-Podolsky-Rosen). Please visit this link (I will could consider it a reliable source). Read the article VERY CAREFULLY and at least twice before coming to any conclusions.

http://www.wikipedia.org/wiki/EPR_paradox

Here is a quote:

"a detailed analysis of the EPR scenario shows that quantum mechanics violates locality without violating causality, because no information can be transmitted using quantum entanglement"

Thus, to emphasize, "NO INFORMATION CAN BE TRANSMITTED USING QUANTUM ENTANGLEMENT".


3.
"Cerenkov radiation violating causality - i.e. sending info. faster than c"

As Peter_C explained, Cerenkov radiation does not travel faster than c, it travels faster than the speed of light in a dielectric medium. This is analogous to a sound wave traveling faster to the speed of sound in a gas. Approximately, the speed of light in a medium is given by c/n, where n > 1 (lets not talk about meta-materials). Therefore, the speed of light in a medium is LESS than the speed of light in vacuo.

In addition, quantum tunelling has nothing to do with quantum entanglement, other than the fact that they are both separate effects of QM.


4.
"how is it possible for a mass-possessing neutron to exceed c"

Neutrons never exceed the speed of light in vacuo. They can, however, exceed the "local speed of light" in a medium. For perhaps a better explanation than what I have provided, see, once again, Wikipedia:

http://www.wikipedia.org/wiki/Cerenkov_radiation


5.
"the gory details of EPR theory and quantum entanglement"

A suggestion: not many people are qualified to give you the gory details. Make sure the person you are talking to is qualified to answer tough questions on this. Even simple questions rely on careful interpretations. Don't be shy to ask them if they are qualified if you are looking for a straight answer. It is VERY EASY to misinterpret results. I am NOT qualified to answer questions on EPR, I have only seen a handful of lectures on the topic. Keep in mind that people like Einstein and Bell (not A. G. Bell) argued over the interpretation.
 
  • #25


Originally posted by sdeliver645
I wanted to correct some of the statements others have made and answer a few of the questions that came up in response to particles traveling faster than c. Some of these answer have already been clarified by Peter_C. Note that I am NOT answering any of these questions based on a "guess" or a cool dream I had or an Isaac Asimov book. If I am unsure, I will let you know and not mislead anyone. Also, please correct me if I am wrong.

1.
"a type of theoretical particle that can travel faster than c"

These particles are indeed theoretical, in the sense that someone conceived of them simply to make physics look more symmetrical. These particles are called "tachyons" and have NEGATIVE MASS. Note that this hypothetical negative mass is DIFFERENT from the negative EFFECTIVE mass you define in a crystal lattice for electrons and holes. I will stress that, to the best of my knowledge, there is NO THEORETICAL EVIDENCE to support their existence.

Actualy tachyons have negative mass squared. Specifically in the equation;

&minus;p2+E2=m2

the parameter m2, which has the dimensions of a component of four momentum has a negative sign. A less confusing description might be to say that they have a "rest momentum" as opposed to a rest energy for ordinary matter.

The Higgs particle is a spinless tachyon, and in the form of pseudo particles they have be used to describe ferromagnetism.

http://math.ucr.edu/home/baez/physics/ParticleAndNuclear/tachyons.html
 
  • #26
tachyons

Tyger, you must be a particle physicist by the look of your units (hbar=c=1).

Thanks for the correction, indeed you are right!
 
  • #27


Originally posted by sdeliver645
Tyger, you must be a particle physicist by the look of your units (hbar=c=1).

Thanks for the correction, indeed you are right!

Nah, not a particle physicist, just a hobby kind of guy, but the units I usually use for myself are length, time, quantum mechanical phase and plane angle. Here's a post I put up about my preferred system.

https://www.physicsforums.com/showthread.php?s=&threadid=3163
 
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  • #28
forgive my ignorance if I am missing the point, but...
I understand that the EPR paradox violates locality without violating causality; or at least, I think I do. If I'm reading this right, causality is not violated because the outcome of the measurement on spin (say) on photon A is a random outcome, not deterministic. Thus, the outcome of the spin of the entangled photon B is not caused by the outcome of the measurement on A, just correlated; in actuality the spin of B was just as probabilistic as that of A, since in effect they are measurements of the same thing; knowing one let's you know the other, but this is a logical conclusion from the constraints of the system, not an instance of physical causation. Please correct me if I'm wrong or going down the wrong path..

But even if I am not correct in my understanding of the causality issue, I don't see how it pertains to transmission of information. Let's take observor Jon on Earth and Jane on Mars, who are involved in an EPR experiment. Before any measurements are performed, the state of information regarding the spin of the respective photons for both Jon and Jane are the same: they both know there is 0.5 chance that the spin they measure will be positive. Say Jon takes a measurement on his photon at a predetermined point in time and finds that its spin is negative. At this point in time Jon's knowledge of the state of the spin is unity, while Jane's is still 0.5. Jane then measures the spin of her photon after the predetermined time to ensure that her photon's wave function has already been collapsed via entanglement (they have very elaborately taken into account the effects of relativity to ensure that their respective watches can be regarded as existing within an absolute time frame). So Jon's information about the state of the system has been transmitted instantaneously to Jane. Since Jane did not collapse the wave function of her photon, she has not gotten a random measurement; the measurement was already fixed, and she had only to measure it. Thus, information has been trasmitted instantaneously, even if the information is only the outcome of a random process. (If I tell you that my coin flip has resulted in heads, then I am still giving you information.)

Please poke at any holes that need to be poked, I just want to get a solid grasp on this whole thing. Thanks.
 
  • #29
In response to hypnagogue

Hypnagogue:

It is sometimes difficult to read another person's response and understand their train of thought. So, I will TRY to address the issue you raise by quoting from an article from Nature* that addreses the issue of whether "practical communication can be performed at speeds greater then c", which should addresses all related questions in one way or another.

You asked:
----------
"...I don't see how [causality] pertains to transmission of information" and mentioned "...thus, information has been trasmitted instantaneously, even if the information is only the outcome of a random process".

My response:
------------
I think the crux of the argument that prevents information travel faster than c is that two spatially separated photons which are entangled are not truly DISTINCT in the sense that (from Nature arcticle, *):

"...it is impossible to assign individual local properties (local physical reality) to each photon. In some sense, both photons keep in contact through space and time."

In addition, to try and put to rest the main question about info. travel faster than c, the author says:

"It is worth emphasizing that non-separability, which is at the roots of quantum teleportation, does not imply the possibility of practical faster-than-light communication. An observer sitting behind a polarizer sees an apparently random series of - and + results, and single measurements on his side cannot make him aware that the distant operator has suddenly changed the orientation of his polarizer"

* Alain Aspect, "Bell's Inequality test:more ideal than ever", News and Views - Nature, 398, 189 (1999).

For easy access to the article:
http://www-ece.rice.edu/~kono/ELEC565/Aspect_Nature.pdf
 
  • #30
Thanks for the info sdeliver645. I agree, it seems quite clear that "practical communication" cannot be transmitted faster than c, since the only information the EPR experiment can transmit is randomly generated. But randomly generated information is still information of some sort; if nothing else, in the EPR experiment information about the outcome of a measurement on one photon is transmitted instantaineously (faster than c) to the other. This is a philosophically important result; it states that there is no universal speed limit on information transfer, since in the (admittedly limited) case of EPR, information is indeed trasmitted with, effectively, infinite speed.

And just for the hell of it... How about we suppose that Jane, sitting on some distant planet (Mars won't quite do), is feeling quite ambivalent about dinner, and decides to choose between Italian and Chinese based on the results of a coin-flip. Except Jane happens to be somewhat superstitious and believes than Jon back on Earth has better luck when it comes to letting chance determine the future. But Jane is also quite hungry and can't wait to eat, so the only practical (heh-heh) course of action is for Jon to measure the spin of his photon A on Earth; once Jon collapses his photon's wave function, Jane will instantaneously know what her dinner will be by measuring the spin on her quantum-entangled photon B.

(And also, uh, Jon and Jane have devised this whole scenario beforehand using c-bound communication channels and have made careful relativistic calculations to ensure that Jane only measures her photon's spin after Jon has done his measurement... yes even taking into account the different frames of reference etc... just work with me here :smile: )
 
  • #31
To my knowledge, gravitation travels at the speed of light.
 
  • #32
Generalization

One could make the generalization that all massless particles travel at the speed of light. They have no choices, one could argue (correct me if I am wrong), due to the symmetry predicted by special relativity. So, this would include a few force carriers, such as:

EM force carrier: photon
Strong force carrier: gluon
Gravitational force carrier: graviton(?)

Does not include the carriers of the strong force, the W+, W-, and the Z0. They have a NON-ZERO mass.
 

1. Can anything besides photons travel at the speed of light?

No, according to the theory of relativity, photons are the only particles that can travel at the speed of light, also known as the speed limit of the universe.

2. Why can't other particles travel at the speed of light?

Other particles have mass, which means they require energy to move. As an object approaches the speed of light, its mass increases, making it more difficult to accelerate and ultimately impossible to reach the speed of light.

3. Can photons travel faster than the speed of light?

No, according to the theory of relativity, the speed of light is the maximum speed at which anything can travel. Photons are massless particles, so they can reach this speed without any increase in mass.

4. Is it possible to slow down photons?

Yes, photons can be slowed down by passing through a medium, such as air or water. This is due to the photons interacting with the particles in the medium, causing them to temporarily lose energy and slow down.

5. How is the speed of light related to the fabric of space-time?

The speed of light is a fundamental constant in the fabric of space-time. It is the same for all observers, regardless of their relative motion. This is one of the key principles of the theory of relativity.

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