Mass, Rest Frames & Neutrinos: Explained

In summary: This is a consequence of special relativity, which tells us that the energy and momentum of a particle are linked in such a way that as the mass goes to zero, the energy becomes infinite and the momentum becomes finite.In summary, as a particle's mass decreases towards zero, it becomes increasingly difficult to keep the particle at rest. This is due to the principles of special relativity, where the energy and momentum of a particle are linked in such a way that as the mass approaches zero, the energy approaches infinity and the momentum becomes finite. Quantum physics does not allow for a varying mass, so this situation is not possible in the quantum realm. Overall, the transition from a massive particle with a rest frame to a massless particle with no rest
  • #1
Lapidus
344
11
So every particle with some mass, even if the mass is very, very close to zero has a rest frame. A neutrino, say, could sit right next to me. But a photon, a massless particle, of course, can't, it has to zip by with light velocity.

But when I would reduce the mass of a particle slowly towards zero, how is this sudden and abrupt change of behaviour, that there is no rest frame anymore for zero mass, explained?
(Which equation shows that best?)

Or does it require more and more energy to keep a ever lighter particle at rest? But then all frames a equal by Lorentz transformation, and there is always a rest frame for a particle which does not move with c...

confused!

thanks
 
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  • #2
Hi Lapidus! :wink:
Lapidus said:
… But when I would reduce the mass of a particle slowly towards zero, how …

But we can't reduce (or increase) the mass of a particle …

the mass (ie rest-mass) of each particle is fixed. :smile:
 
  • #3
Lapidus said:
So every particle with some mass, even if the mass is very, very close to zero has a rest frame. A neutrino, say, could sit right next to me. But a photon, a massless particle, of course, can't, it has to zip by with light velocity.

But when I would reduce the mass of a particle slowly towards zero, how is this sudden and abrupt change of behaviour, that there is no rest frame anymore for zero mass, explained?
(Which equation shows that best?)
in addition to tiny tim's comments, don't forget that light has energy. For any fixed E the v goes smoothly to c as m goes to 0.
 
  • #4
DaleSpam said:
in addition to tiny tim's comments, don't forget that light has energy. For any fixed E the

Right, v goes smoothly to c as m goes to 0, so that the denominator and numerator of the expression for the relativistic energy become both zero.

But isn't it that for very small masses quantum physics has to come into play?

Does not quantum physics, with its Broglie wavelength or even Comton wavelength for particles, blur the concept of localization and thus the concept of a rest frame?

Does quantum physics (relativistic quantum physics) give a more smooth transition to the massless case with no rest frame?
 
  • #5
Lapidus said:
Right, v goes smoothly to c as m goes to 0, so that the denominator and numerator of the expression for the relativistic energy become both zero.
No, the relativistic energy is well-defined even for a massless particle. You do not get division by 0.

Lapidus said:
Does quantum physics (relativistic quantum physics) give a more smooth transition to the massless case with no rest frame?
For quantum physics I think the only answer is tiny tim's answer that mass of quantum particles does not vary so your situation is simply not possible quantum mechanically. For non-quantum relativistic physics the transition is smooth already, as I mentioned above.
 
  • #6
To answer your original question, you can imagine a series of particles with smaller and smaller mass. As the mass becomes small, it becomes more and more difficult to keep the particle at rest. The slightest bit of energy will cause it to go scooting off at near light speed.
 

Related to Mass, Rest Frames & Neutrinos: Explained

1. What is mass and how is it related to rest frames and neutrinos?

Mass is a fundamental property of matter that measures the amount of resistance an object has to a change in its motion. Rest frames are the reference frames in which an object is at rest, and neutrinos are subatomic particles that have a very small mass. The mass of a neutrino is important in determining its behavior in different rest frames.

2. How does special relativity explain the concept of rest frames?

Special relativity is a theory that describes the relationship between space and time. According to this theory, the laws of physics are the same for all observers in uniform motion. This means that there is no preferred rest frame, and all rest frames are equally valid. Special relativity also explains how the mass of an object changes as its velocity approaches the speed of light.

3. What is the significance of rest frames in the study of neutrinos?

Rest frames are crucial in the study of neutrinos because they help us understand the behavior of these particles in different reference frames. Since neutrinos have a very small mass, they can travel close to the speed of light and exhibit properties predicted by special relativity. By studying neutrinos in different rest frames, scientists can gain a better understanding of their properties and behavior.

4. How do neutrinos differ from other subatomic particles in terms of mass and rest frames?

Neutrinos are unique among subatomic particles because they have a very small mass. This allows them to travel close to the speed of light and behave differently in different rest frames. Most other particles, such as protons and electrons, have much larger masses and cannot reach such high velocities. Additionally, neutrinos have a very weak interaction with matter, which makes them difficult to detect.

5. Can neutrinos have rest mass and still travel at the speed of light?

No, according to the theory of special relativity, an object with mass cannot travel at the speed of light. As an object's velocity approaches the speed of light, its mass increases, and it requires an infinite amount of energy to reach the speed of light. Therefore, neutrinos, which have a very small but non-zero mass, cannot travel at the speed of light.

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