Are gravitons a certainty like electrons in reality?

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In summary, the conversation discusses the existence of electrons and gravitons. While it is certain that electrons exist in reality, their exact nature is still unknown. On the other hand, gravitons are purely hypothetical and their existence is not yet confirmed. They are predicted by string theories and have definite properties, but there is no experimental evidence for them. It is uncertain if stringy physics is the way to the final answer or if gravitons are real. Overall, there is more certainty about the existence of electrons compared to gravitons.
  • #36
Originally posted by Beast

Its always been clear to me the gravity would arrive at the same time as light until I read this thread.

I just went back and re-read Patrick van Esch post
where he says among other things that news of changes in the gravity field propagates at c, just like news of changes in the electric field.

You might like a caltech animation of a the field around a moving pointcharge, if you haven't seen it. There is a subtle point about linear motion---the electric and so presumably the gravitational field "anticipates" it. (It can be seen as static in some frame I guess.) So it's only when something accelerates that it counts as news. I'll look up the caltech link, circular motion makes a nice picture---they have various motions including where you drag the charge around with the mouse and see the effects ripple out at the speed of light.

http://www.cco.caltech.edu/~phys1/java/phys1/MovingCharge/MovingCharge.html

Never heard of macroscopic BH going "nova". Microscopic holes may be able to evaporate in a flash of Hawking radiation, but the big ones radiate by sucking in ordinary matter, which gets hot on the way in. So I can't picture a SMBH doing what you say.
But so-called "hypernovae" or powerful "gammaray bursts" are observed and sometimes attributed to the sudden collapse of a neutron star into a BH. In that case, if we had gravity wave detectors sensitive enough, it would be like what you picture. We would not get fried but we would detect the collapse-wave at the same time as we "see" the gamma flash. Nice thought, maybe will happen sometime.
 
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  • #37
Originally posted by marcus
Carefully chosen words!

Patrick perhaps you have a reference for this: I have read several places that "graviton" may be an artifact of using a flat space----but now I cannot lay my hand on the reference.

yes, of course gravitons are an artifact of flat spacetime! and what's more, so are all particles!

what i mean by that is, well you noticed how the original poster said we were sure about the existence of electrons. but in nonflat spacetime, what is an electron in one frame might not be an electron in another!

a particle has quantum numbers that are invariants of its symmetry group, which is the Poincaré group, in flat spacetime. so mass and spin are how we characterize the spacetime properties of particles, in flat spacetime.

all that goes out the window in nonflat backgrounds. not only do you not have a graviton, you do not have an electron or a photon! it is possible to to perturbation around a nonflat background of course, but depending on what the symmetries of the background are, it may be very hard to decide on what you want to call a particle.

also, the situation is analogous for the electromagnetic field. if you are in a vacuum, then perturbation theory makes a photon a useful approximation. but if there is some strong field electromagnetic background, then this notion becomes more troublesome. you can treat the background as classical, and photons as perturbations around that classical background, but it is difficult to construct a strong classical background out of particles.

(i guess this has something to do with coherent states. i don t know much about that)

the point of the story is: a particle interpretation is most useful in perturbation theory around a flat background, and it becomes strained, if not completely useless, in other situations.

nevertheless, we expect to be able to do physics in these weak field regimes, where the particle interpretation is intact, so we expect there to be a graviton in any quantum theory of gravity.


Maybe you can confirm this, or perhaps it is a misconception which you can correct. I have concluded, then, that the idea of an
electron is very useful because it is not just an artifact of mathematical circumstances and it does NOT go away when you change the problem. You can accelerate it, make atoms with it, run it through wires, charge a battery, and you can make it live in curved space, like around a black hole.
this is not correct! an electron is a relative term as well!


Or as you say (and there may be a difference) "gravitons" appear in the math when one uses a "linearized" model. This makes me think that we are talking about an approximation out of, say, a pertubative analysis. Please be more specific, if it would not be too much trouble for you. Thanks,

marcus

of course it is perturbative.
 
  • #38
Original Topic Questions

Let's say there are gravitons as wave/particles.

If they actually travel at c, then we can expect them to have zero rest mass.

Would gravitons be red/blue shifted by relative motion, and if so, how? What about red/blue shifting by gravity?

How would graviton radiation interact with mater? Do graviton theories provide for e.g. the analog of Cherenkov radiation? Would it be possible to use some kind of lens to bend gravitons or mirror to reflect them?

Would the graviton have the same kind of quantum restrictions as a photon regarding energy states?
 
  • #39
The dynamics of the string theory graviton are governed by Einstein's field equation, so it behaves in a GR-ish way. It does have zero mass, and coherent gravitons can create gravitational waves. In order to create a Cerenkov effect you would have to find a substance in which gravity travels more slowly than it does in a vacuum.
 
  • #40
A long time ago, in a post far far away

vanesch/Patrick wrote: Weak effects of curvature and time dilatation, and the equivalence principle using normal matter, has been checked, so the "low field quasi-static" limit is ok. Indirect measurement of the energy loss of a pulsar is the only indication we have that classical gravity waves exist. We should first detect classical waves (Virgo experiment for example) to really know that gravity waves exist. The quantum version is then even more elusive.
IIRC, VIRGO (etc), and LISA (no etcs) look for signals predicted by theory - partly a result of weakness of the expected signals. How much work is being done to develop 'unbiased' analyses of the raw data streams?

What tests - other than gravitational wave detection - are being contemplated for 'strong field' and 'dynamic' GR regimes?
 
  • #41


IIRC, VIRGO (etc), and LISA (no etcs) look for signals predicted by theory - partly a result of weakness of the expected signals. How much work is being done to develop 'unbiased' analyses of the raw data streams?

I wouldn't say that the analyses are "biased": methods like matched filtering will pull out signals from the noise if you know what the signals look like, but they don't really introduce false signals. (It will pull out a false signal if the noise looks like the signal it's looking for, but that's what it should do: find things that look like signals.) The disadvantage of matched filtering is just that you need to know what the waveforms look like ahead of time to use it.

But anyway, there is some work being done on signal detection that doesn't rely on precalculated waveforms, namely detection of bursts and other anomalies ("things that go bump in the night"). They just look for sudden changes in the general statistics of the signal (such as its average power or variance).


What tests - other than gravitational wave detection - are being contemplated for 'strong field' and 'dynamic' GR regimes?

Not a whole lot, other than the ones already being performed to provide evidence of black holes (attempts to astronomically observe innermost circular orbits, Lense-Thirring effect, sudden vanishing of luminosity near a purported horizon, etc.) Although it depends on exactly what you mean by "strong field" and "dynamic GR" regimes.
 
  • #42
Ambitwistor wrote, re tests of 'strong field' and 'dynamic' GR regimes: Not a whole lot, other than the ones already being performed to provide evidence of black holes (attempts to astronomically observe innermost circular orbits, Lense-Thirring effect, sudden vanishing of luminosity near a purported horizon, etc.) Although it depends on exactly what you mean by "strong field" and "dynamic GR" regimes.
Taking vanesch/Patrick's comment about experimental/observational verification of GR as a starting point, the current status is:
- weak, quasi-static regimes: verified to at least 1:1,000, some aspects to 1:20,000 or better
- strong regimes: BH existence etc verifies GR to ~1:10 (or is that just a wish?)
- dynamic regimes: awaiting clear signals from colliding BHs or neutron stars (etc).

So, in the sense that GR is experimentally verified, the "classical [gravitational] waves" must exist, but 'merely' await direct observational verification.

Gravitons? Stay tuned.
 
<h2>1. What are gravitons?</h2><p>Gravitons are hypothetical particles that are believed to be the carriers of the force of gravity in the universe. They are predicted by theories of quantum gravity, but have not yet been observed or confirmed by experiments.</p><h2>2. How are gravitons related to electrons?</h2><p>Gravitons and electrons are both fundamental particles in the Standard Model of particle physics. However, they have very different properties and roles in the universe. While electrons are responsible for the electromagnetic force, gravitons are believed to mediate the force of gravity.</p><h2>3. Are gravitons a certainty in reality?</h2><p>No, gravitons are not currently a certainty in reality. They are still a theoretical concept and have not been observed or confirmed by experiments. However, many scientists believe that they are a necessary component of a complete theory of quantum gravity.</p><h2>4. How do scientists study gravitons?</h2><p>Since gravitons have not yet been observed, scientists study them through theoretical models and mathematical equations. They also conduct experiments using particle accelerators and other high-energy physics tools to try and detect the presence of gravitons.</p><h2>5. What would it mean if gravitons were confirmed to exist?</h2><p>If gravitons were confirmed to exist, it would provide significant evidence for theories of quantum gravity and would greatly advance our understanding of the fundamental forces of the universe. It could also potentially lead to new technologies and applications in the future.</p>

1. What are gravitons?

Gravitons are hypothetical particles that are believed to be the carriers of the force of gravity in the universe. They are predicted by theories of quantum gravity, but have not yet been observed or confirmed by experiments.

2. How are gravitons related to electrons?

Gravitons and electrons are both fundamental particles in the Standard Model of particle physics. However, they have very different properties and roles in the universe. While electrons are responsible for the electromagnetic force, gravitons are believed to mediate the force of gravity.

3. Are gravitons a certainty in reality?

No, gravitons are not currently a certainty in reality. They are still a theoretical concept and have not been observed or confirmed by experiments. However, many scientists believe that they are a necessary component of a complete theory of quantum gravity.

4. How do scientists study gravitons?

Since gravitons have not yet been observed, scientists study them through theoretical models and mathematical equations. They also conduct experiments using particle accelerators and other high-energy physics tools to try and detect the presence of gravitons.

5. What would it mean if gravitons were confirmed to exist?

If gravitons were confirmed to exist, it would provide significant evidence for theories of quantum gravity and would greatly advance our understanding of the fundamental forces of the universe. It could also potentially lead to new technologies and applications in the future.

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