Quantization of Energy: Does Mass Follow?

In summary, the conversation revolved around the idea of whether mass is quantized, similar to energy, and whether this could be applied to the unification of general relativity and quantum mechanics. Some participants argued that mass is not a quantum observable and is instead an input parameter, while others discussed the potential for a mass operator and the need for a mathematical description of a quantized mass to unify the two theories.
  • #1
SeReNiTy
170
0
Since energy only exists in quanta, does this mean mass is also quantized according to einstein's famous equation?
 
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  • #2
Who said energy is always quantized/exists only in quanta...?

Daniel.
 
  • #3
I thought this was what plank discovered, damn i must of been very wrong!
 
  • #4
Not wrong,just unaware of the fact that a Hamiltonian operator may have a continuous spectrum as well.

Daniel.
 
  • #5
dextercioby said:
Not wrong,just unaware of the fact that a Hamiltonian operator may have a continuous spectrum as well.

Daniel.
Ok the other day i heard they did experiments with a neutron that verified gravitational energy was indeed quantized, hence the neutron at the lowest graviational potential energy existed a certain distance above the ground...now would mass also exist in quantized levels?
 
  • #6
There are tricks with mass generation in the Higgs mechanism,but that's one thing, claiming that mass is quantized (hence attributing a densly defined selfadjoint linear operator to it) is something totally different and I've never seen the latter in any of the books I've read or lectures I've taken.

Usually,we see mass as in input parameter in QFT.In GR,we don't have mass,but the energy-momentum 4 tensor.

That's the little bit i know.I won't comment on any experiments,it's not my domain.

Daniel.

EDIT:Yes,Pete,of course we do,i just blanked for a while... :frown:
 
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  • #7
dextercioby said:
There are tricks with mass generation in the Higgs mechanism,but that's one thing, claiming that mass is quantized (hence attributing a densly defined selfadjoint linear operator to it) is something totally different.

Usually,we see mass as in input parameter in QFT.In GR,we don't have mass,but the energy-momentum 4 tensor.That's the little bit i know.I won't comment on any experiments,it's not my domain.

Daniel.

Hmmm, is there a problem with my reasoning? Step aside from the maths for a second and can you tell me is it wrong to think mass is quantised as well if energy is quantised, after all the two are related by a equation we all know!
 
  • #8
In GR,we don't have mass,but the energy-momentum 4 tensor.
Huh? Of course we have mass in GR. Mass is fully described by that tensor. Recall what Einstein said
The special theory of relativity has led to the conclusion that inert mass is nothing more or less than energy, which finds its complete description in a symmetrical tensor of second rank, the energy tensor.
Mass is not a component of this tensor. One integrates the momentum density over the object whose mass we seek and then we divide by the speed of the object. The result is mass.
 
  • #9
Here's Einstein's equation

[tex] E^{2}=\vec{p}^{2}c^{2}+m^{2}c^{4} [/tex].

As you may have heard,to this equation equation one cannot apply Dirac's quatization scheme (included in the second/quantization postulate),as it would give erroneous results when interpreting 0-th component of the probability current 4-vector.

So it shouldn't have to do with a possible mass quantization.As i said,there's no QM observable for mass.It is an input scalar parameter (or a finite dimensional square matrix,if one refers to quarks or some other particles) and just that.

I don't know what superstring theory has to say on a possible mass quantization.

Daniel.
 
  • #10
The energy is quantised in some systems, not all. Planck quantised the energy levels for stable electromagnetic equilibrium modes inside a cubical cavity - analogous, in a way, to the quantised energy levels of a 3D harmonic oscillator. Note 'stable equilibrium modes', which are of course a function of wavelength, box dimensions and 'quantum numbers' [itex]n_{1,2,3}[/itex]. The quantisation comes as a result of the system being looked at.
 
  • #11
Indeed, he (or she) who unifies GR and QM gets a big pat on the back!
 
  • #12
dextercioby said:
As i said,there's no QM observable for mass.
I've seen the term "mass operator" many times. However that kind of thing I never learned and it appears over my head. There is an article on this point at

http://www.imath.kiev.ua/~fushchych/papers/1968_1.pdf
 
  • #13
Do you know any of the mathematics behind QM? Measureable quantitied (position, momentum, energy) are represented by certain mathematical objects, called operators. They 'operate' on the wavefunction to describe it's evolution when a measurement of that operator is performed.

What DexteroIforgettherest is saying is that you can not construct one of these operators which when applied to the wavefunction, yields the mass.

Essentially you can realize this as the mass is a fundamental part of the wavefunction description (the Hamiltonian, which is an operator which decribes the total energy of the system, contains the mass as a fixed quantity, so the system is defined, in part, by the mass).
 
  • #14
dextercioby said:
Here's Einstein's equation

[tex] E^{2}=\vec{p}^{2}c^{2}+m^{2}c^{4} [/tex].

As you may have heard,to this equation equation one cannot apply Dirac's quatization scheme (included in the second/quantization postulate),as it would give erroneous results when interpreting 0-th component of the probability current 4-vector.

So it shouldn't have to do with a possible mass quantization.As i said,there's no QM observable for mass.It is an input scalar parameter (or a finite dimensional square matrix,if one refers to quarks or some other particles) and just that.

I don't know what superstring theory has to say on a possible mass quantization.

Daniel.

Ah i see now, so this is the problem why QM cannot merge with GR...

So to unify GR with QM one has to come up with the maths that describes a quantised mass hence a quantised gravity field?
 
  • #15
@Pete:It was an interesting reading,but i dunno,the fact that such theories have not transpired into books and college textbooks makes me kinda skeptic.

People are being taught worldwide that spin angular momentum is the perfect example for a quantum observable with no classical analogus,which comes from viewing rotation symmetry through the eyes of group theory representations and the axioms of quantum mechanics.

Since,classically,mass is neither a Lagrangian nor a Hamiltonian observable,i don't know what to think...:rolleyes:

Daniel.
 
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  • #16
SeReNiTy said:
Ah i see now, so this is the problem why QM cannot merge with GR...

So to unify GR with QM one has to come up with the maths that describes a quantised mass hence a quantised gravity field?

We can very simply merge GR & QM,it's just that we don't get a sound theory.
If it's ever done,maybe a lot of new things may come into the arena,not only the quantum description of mass.

Why wouldn't space-time be quantized ?

Daniel.
 
  • #17
dextercioby said:
Why wouldn't space-time be quantized ?

Daniel.

Well if mass is quantised then space can only curve at certain values, no?

Hmmm, if space is quantised, can that explain HUP? For example I'm thinking if space only exists in certain quanta, then the infomation holds must exist in finite values, hence a compromise between the infomation on momentum and displacement must be made? Is this reasoning wrong?
 
  • #18
Not wrong,just speculative.I won't pursue it.

Daniel.
 
  • #19
Surely the HUP is explained by the non commutativity of the two observables, unless, of course, you're looking for a 'deeper' (metaphysical?) explanation.
 
  • #20
James Jackson said:
Surely the HUP is explained by the non commutativity of the two observables, unless, of course, you're looking for a 'deeper' (metaphysical?) explanation.

Nope, I'm looking for a physical explanation and trying to derive certain princples from physical reality not maths...
 
  • #21
Unfortunately for you, QM is theoretical physics. The fact that it explains results with amazing accuracy doesn't make it 'physical'. People often forget that physics is only a model. It doesn't say "The world is like this because physics says so", it actually says "Physics is like this because the world says so". How one attaches physical meaning to the theories is generally the area of philosophy.
 
  • #22
James Jackson said:
Unfortunately for you, QM is theoretical physics. The fact that it explains results with amazing accuracy doesn't make it 'physical'. People often forget that physics is only a model. It doesn't say "The world is like this because physics says so", it actually says "Physics is like this because the world says so". How one attaches physical meaning to the theories is generally the area of philosophy.

Hmmm, with QM i know its all about formulism and drop a physical interpretation, but i like have that interpretation since i understand better that way...
 
  • #23
I can attempt to explain the HUP in a pseudophysical way...

A measurable operator (spin, momentum etc) has a certain number of possible results. These are the eigenvalues of the operator, and have associated eigenvectors, and together form an eigenspace. So when you hear talk of eigenspaces, it refers to all possible outcomes for a measurement.

If we perform a measurement, the result of the measurement is an eigenvalue, and the wavefunction becomes equivalent to the corresponding eigenvector.

Now, different operators can (and do) have different eigenspaces, so if I measure one operator followed by another and they have different eigenspaces one measurement yields no information about the other. They are not 'compatable observables' in QM speak because of the differing eigenspaces.

I hope that makes sense, it's difficult to explain without the formal maths!
 
  • #24
Since energy only exists in quanta, does this mean mass is also quantized according to einstein's famous equation?

Just would like to point out that all matter is quantized. You got these bunch of particles with some precise rest mass, most prominent protons, neurons and electrons. I know there is no basic mass quantum, but matter is not a continuum but comes in discrete chunks.
 
  • #25
I'd be interested if you could fill me in with the rest mass of, say, an up quark.
 
  • #26
I'd be interested if you could fill me in with the rest mass of, say, an up quark.
06-10-2005 11:05 PM


Well, I have to look up this one. But the question was if mass is quantised.
I thougth something that has mass is called matter. So is matter quantised?
I remember reading Feynman saying that if there were just one fact he could pass to a next science generation, it would be that the universe is build out of discrete particles. So before resorting to higher math, we should consider this rather simple insight.
And going to quark level or even lower, what is mass or energy anyway?

I'm just asking questions.
 

1. What is quantization of energy?

Quantization of energy is a concept in physics that states that energy can only exist in discrete, specific amounts. This means that energy cannot take on any value, but rather is limited to certain values or levels.

2. How does quantization of energy relate to mass?

In the theory of relativity, mass and energy are closely related. The famous equation E=mc² shows that mass and energy are interchangeable and can be converted into one another. This means that the quantization of energy also applies to mass, as they are essentially different forms of the same thing.

3. What is the significance of quantization of energy?

Quantization of energy is a fundamental principle in physics that has been confirmed by numerous experiments. It explains many phenomena, such as the discrete energy levels of electrons in atoms and the behavior of photons. It also plays a crucial role in understanding the behavior of matter at a microscopic level.

4. Is quantization of energy a universal law?

Yes, quantization of energy is considered a universal law in physics. It applies to all forms of energy, including light, heat, and electromagnetic radiation. It also applies to all types of matter, from subatomic particles to larger objects.

5. Can quantization of energy be observed in everyday life?

Yes, the effects of quantization of energy can be observed in everyday life. For example, the colors we see are a result of quantized energy levels of light. The functioning of electronic devices, such as computers and smartphones, also relies on the principles of quantization of energy.

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