How do fermions acquire mass as opposed to gauge bosons?

In summary, the Higgs mechanism allows for fermions to obtain masses via a Yukawa coupling between the fermion and Higgs field. This coupling is different for each fermion, but the vev of the Higgs field is the same for all fermions. However, this does not lead to the quantization of the coupling constant, as it is an input to the theory. The quantization of electric charges in the standard model is due to the compactness of the gauge groups, but the quantization of fermion masses is not explained in the standard model. Additionally, the majority of the mass of protons and neutrons does not come from the Higgs mechanism, but from the binding energy that holds the three quarks together.
  • #1
mmaa
6
0
Hello, if someone could enlighten me I'd be most grateful.

Also, if anybody could point me in the direction of some really good free resources that would be great too. Thanks.
 
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  • #2
The fermions can obtain masses in a gauge-invariant way via the Higgs mechanism, just like the gauge bosons. One way to implement this is to consider a Yukawa coupling between the fermion, [itex]\psi[/itex], and the Higgs field, [itex]\phi[/itex] in the Lagrangian:

[tex]\mathcal{L}_{\rm Yukawa} \sim g\bar{\psi}\phi\psi[/tex].

When symmetry breaking occurs and the Higgs takes on its vacuum expectation value, terms of the form [itex]g \bar{\psi}v\psi[/itex] develop, where [itex]v[/itex] is the vev. These are mass terms with [itex]m\sim gv[/itex].

Not sure about specific references, but there should be plenty of information on the internet.
 
  • #3
Since the vev is just one value, the only difference in the terms for each fermion would then be is "coupling constant" with the Higgs field. Why isn't this quantized like the coupling with the electric field -> quantized electric charge or strong nuclear force -> quantized color charge?
 
  • #4
The gauge quantum numbers such as electric charges are quantized because the gauge groups are compact. In contradistinction, the Poincare group is not compact, so the mass (as a Casimir invariant classifying the Lie representation) cannot have a discrete spectrum.
 
  • #5
JustinLevy said:
Since the vev is just one value, the only difference in the terms for each fermion would then be is "coupling constant" with the Higgs field. Why isn't this quantized like the coupling with the electric field -> quantized electric charge or strong nuclear force -> quantized color charge?

The Yukawa couplings are inputs to the theory, we can't do anything about the fact that flavor symmetries are badly broken in nature. However for each fermion, there is a global flavor charge, one for each quark and lepton (associated to the U(1) rotation on the fermion and its antiparticle). This charge is quantized naturally in all bound states.
 
  • #6
humanino said:
The gauge quantum numbers such as electric charges are quantized because the gauge groups are compact.
I don't think it's so easy. One must distinguish between the coupling constant e, g, ... in QED, QCD, ... which could have any value, and the charge Q, Qa, ... as qm generators of U(1), SU(n), ... The latter one is quantized in the sense of the first Casimir QaQa. But how is this related to the coupling constant? The charge operator in QCD is something like

[tex]Q^a = \int d^3x\, g\,\bar{\psi}_i (T^a)_{ik}\psi_k[/tex]

The Casimir operator has a discrete spectrum, but still g is an arbitrary multiplicative constant which is not "quantized"
 
  • #7
Tom, I do not see where the difficulty you are raising relates to my comment. I agree that there is a distinction between coupling constant and charge. You agree that charges in compact Lie groups are discrete, which is all I was saying. I did not say that the quantization of the charge was related to the coupling constant (vev of the Higgs).

Neither I nor the standard model offer an explanation for what the fermion masses are unfortunately. They just are what they are in the standard model, a set of ad-hoc numbers. JustinLevy was asking why those numbers are not quantized as say electric charges. The quantization of electric charges stem from the compactness of U(1).
 
  • #8
My guess was that JustinLevy didn't see the distinction between "charge e" and "charge Q". That was the reason for my comment. Sorry!
 
  • #9
tom.stoer said:
My guess was that JustinLevy didn't see the distinction between "charge e" and "charge Q". That was the reason for my comment. Sorry!
Thank you for the clarification, that is an important distinction. I now understand the difficulty you are raising. After re-reading JustinLevy's post, I realize this might indeed be the confusion.
 
  • #10
Then one should add that in the context of the Higgs phenomenon applied to fermions Q doesn't play a role at all, only different g's.
 
  • #11
Wow, thanks everybody. This forum is great!
 
  • #12
humanino said:
The quantization of electric charges stem from the compactness of U(1).

Actually, as far as i know there is no reason in U(1) for the charge to be quantized. If you postulate magnetic monopoles, you get the Dirac quantization condition, but if not there is no restriction.
 
  • #13
humanino said:
The gauge quantum numbers such as electric charges are quantized because the gauge groups are compact.
Thinking about that I can't find a good reason that compactness alone is sufficient and whether electric charge Q is necessarily quantized.

hch71 said:
Actually, as far as i know there is no reason in U(1) for the charge to be quantized. If you postulate magnetic monopoles, you get the Dirac quantization condition, but if not there is no restriction.
Here you are confusing e and Q. The Dirac monopole forces e to be quantized, but humanino is talking about Q being quantized (better: the spectrum of the operator Q).

As I tried to explain in my previous post one must distinguish between Q (charge of a physical state) and e (coupling constant) which is not directly observable.
 
  • #14
I rembember learning that most of the mass of protons and neutrons does not come from the Higgs mechanism, but from the binding energy that holds the three quarks together.

Is that correct? And could someone explain a bit further what goes on there..

thank you
 
  • #15
Lapidus said:
I rembember learning that most of the mass of protons and neutrons does not come from the Higgs mechanism, but from the binding energy that holds the three quarks together.
Yes, this is correct.

In deep inelastic scattering one probes the "high energy sector" of QCD. Here one finds "asymptotic free" quarks. These elementary quarks only have a mass of a few MeV, which means that be taking three times their mass cannot explain nucleon mass at the GeV scale. (In the old constituent quark model before invention of QCD one used three quarks and nothing else; these constituent quarks are not fundamental degrees of freedom but something like "dressed" quarks with surrounding "virtual" quark and gluon "clouds"; please don't take this too literally).

Unfortunately I do not know a simple picture that is able to describe - based on nearly massless elementary quarks plus QCD interaction - how the nucleon masses do arise. One could try to visualize the nucleon as a lump of energy with quark and gluon chromo-electric and chromo-magnetic fields forming a nucleon.
 
  • #16
Lapidus said:
I rembember learning that most of the mass of protons and neutrons does not come from the Higgs mechanism, but from the binding energy that holds the three quarks together.

Is that correct? And could someone explain a bit further what goes on there..

thank you

That is correct. The mass of a quark is not a experimentally accessible quantity, but the light (up and down) quarks have a mass of ~2-5MeV. The proton on the other hand has a mass of ~940MeV. So the contribution of the individual quarks' masses is very small.

The rest of the mass of the proton is in fact the kinetic and binding energy of the quarks. Quarks interact via the strong interaction and this strong interaction has the peculiar feature that it does not allow any particle that carries a strong charge (such as a quark) to exist alone. So quarks under normal circumstances only appear in combinations that are neutral to the strong force. One such combination is the proton. This phenomenon is called quark confinement.

Inside the proton, quarks are not at rest. They strongly interact and consequently there is a lot of energy. It is this energy that - via the energy mass equivalence - we see as mass.

In fact, there is one theory, called technicolor, that asserts that the mechanism for electroweak symmetry breaking is very similar to this mechanism of the strong force.
In this scenario all particles gain mass in a similar way as the proton through the strong force. Hence the Higgs would be a composite particle such as a hadron in the strong force.
 
  • #17
tom.stoer said:
My guess was that JustinLevy didn't see the distinction between "charge e" and "charge Q". That was the reason for my comment. Sorry!
Yes I was making that confusion. Is there a technical name for these, to help distinguish them? I'm realizing now in retrospect that a gradstudent and I were severely misunderstanding each other when discussing this a month ago. (He seemed to talk as if there were only the "Q" and I thought there were only the "e", and only confused each other. Neat to see that we were both missing something very important.)

I assume the same applies for the other forces as well.
So the standard model can't explain why the "e" charges for electromagnetism or color force are quantized? (Are the 'charges' for the weak force also 'quantized' in the sense that 'e' charges are? ... or does the symmetry breaking ruin this.)
 
  • #18
So when you talk about strong interaction that's gluons right? I know its all a bit hazy in terms of what particles/forces/fields etc are, but since we are talking about bosons already would it be fair to say that most of the mass of the proton and neutron resides in gluons?
 
  • #19
And also, in QCD/QFT what is the best way to think of the idea of a field? Is it strictly a reference frame/ geometry, or does it have a physical meaning? I was under the impression you can think of them a sort of energy storage devices, but a friend of mine thinks not. Specifically, I am doing a written project as part of an application, and I decided to write about the Higgs boson, and this is the sentence that is causing contention:

"Particles can be described as the quanta (minimum units) of fields, and forces as the exchange of particles"

Is this unreasonable? The audience is completely non specialist, so I can't really go into detail.
 
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  • #20
mmaa said:
"Particles can be described as the quanta (minimum units) of fields, and forces as the exchange of particles"
This is pretty reasonable, although I'd say that particles are quantized excitations of fields.
 
  • #21
Thank you bapowell, i thought so, but now I'm not so clear. i suppose I'm assuming people know what a field is, when i probably shouldn't, so i might as well say something about excitations as well.. But can I say for example that an electron is the quanta of an electric field?
 
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  • #22
mmaa said:
Wow, thanks everybody. This forum is great!
i disagree.. it's horrible, almost depressing, as i hate realising how many things i don't know..yet i can't look away..damn you all..:rolleyes:

i doubt it's a helpful contribution, and probably innacurate, but i think of a field as a 'potential potential'
 
  • #23
I know, i feel a bit like that too. But it's really nice that people are so stoked to help out. I always liked the 'condition of space' idea, but at uni I never got to QFT, we did quantum mechanics, but QFT was part of the masters course. I've been listening to Susskind's lectures on the standard model, and it has rather re-sparked my interest in learning more physics, except now I don't have all the libraries and teachers I could want. Anyway, according to what I have learned so far, a particle IS a field quanta, but a friend of mine, who is much cleverer than I am, says that I'm wrong, and that a particle is DESCRIBED by field quanta. I think this is true too, as they are described in terms of quantised properties of fields like those mentioned above, but I'm now doubting my grasp of the lectures. I'm also concerned with the link between spacetime and fields, do fields exist 'within' spacetime, are they part of it? To top it off, one of my final projects at uni was about themodynamical properties of spacetime, as implied by aspects of black hole physics, which evidently deals with a sort of quantised spacetime, but it wasn't a really qft of spacetime, and I wonder if there is one...
 

1. What is the difference between fermions and gauge bosons?

Fermions are particles that have half-integer spin, such as electrons and quarks. They are the building blocks of matter and have mass. Gauge bosons, on the other hand, are particles that mediate the fundamental forces of nature (e.g. photons for electromagnetism). They have integer spin and are massless.

2. How do fermions acquire mass?

Fermions acquire mass through the Higgs mechanism, which involves the interaction of the fermion field with the Higgs field. The Higgs field gives rise to the Higgs boson, which is responsible for giving particles mass through the Higgs mechanism.

3. How is the Higgs mechanism related to the Standard Model of particle physics?

The Higgs mechanism is a crucial aspect of the Standard Model, which is the most widely accepted theory for understanding the fundamental particles and forces in the universe. It explains how particles acquire mass and how the fundamental forces interact with matter.

4. Why do gauge bosons remain massless while fermions acquire mass through the Higgs mechanism?

Gauge bosons remain massless because they do not interact with the Higgs field. The Higgs field only couples to particles with mass, which is why fermions acquire mass through the Higgs mechanism. This is also why gauge bosons are responsible for mediating long-range forces, as they are able to travel at the speed of light due to their lack of mass.

5. Can fermions acquire mass through any other mechanism besides the Higgs mechanism?

There are theories that propose alternative mechanisms for fermions to acquire mass, such as supersymmetry and technicolor. However, the Higgs mechanism is the only mechanism currently confirmed by experimental evidence. Further research and experiments are needed to fully understand the origin of mass in the universe.

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