Is the higgs field required to have space-time warping?

In summary, the conversation discusses the relationship between spacetime curvature and mass, specifically in relation to the Higgs model. It is mentioned that the Higgs field is not the sole source of mass, but rather allows it to be nonzero. The proportion of mass due to the Higgs mechanism varies for different particles. There is also mention of the role of energy density and pressure in causing spacetime curvature. However, it is agreed that it is incorrect to say that spacetime curvature and mass are completely unrelated, although there may be different models and understandings of their relationship.
  • #1
cdux
188
0
I wonder if there's a connection and it's a requirement or it's a completely different matter and space(time) warps anyway.
 
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  • #2
It is completely unrelated. Space-time curvature is due to stress-energy tensor.
 
  • #3
cdux said:
I wonder if there's a connection and it's a requirement or it's a completely different matter and space(time) warps anyway.

No, the Higgs is not required. For instance, gravitational waves are vacuum solutions; they have curvature but no matter fields.

The Higgs is not even required in order to get mass. Most of the mass content of ordinary matter comes from the kinetic energy of the quarks, not from the Higgs field. Popularizations have spread the inaccurate idea that the Higgs is the source of all mass.
 
  • #4
bcrowell said:
Popularizations have spread the inaccurate idea that the Higgs is the source of all mass.
Then it's a responsibility of many popular scientists appearing on film and tv movies and segments. I'm not an expert but I distinctly remember people in their effort to describe it for the layman using phrases such as "it's what gives mass to particles" and leaving it at that.
I guess some people have to learn when to stop trying to explain something in simplistic terms if those terms make it not just simplistic but also inaccurate.
 
  • #5
I think the above answers are literally correct in that they say spacetime curvature and mass have aspects other than Higgs effects. So in that sense, you can have spacetime curvature without mass...and without Higgs...energy density and pressure would be examples of phenomena [part of the stress energy tensor] causing space time curvature.

On the other hand I am somewhat troubled if the inference is that they are 'completely' unrelated. Within the context of existing models and understanding, that could be argued, I guess, but I'd rather see something like 'we don't have a clear understanding' or 'we have different models with different insights':

http://en.wikipedia.org/wiki/Origin_of_mass

Ben: any reference you can suggest to learn more about what portion of mass arises from the Higgs model??
 
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  • #6
In the Higgs model, the mass of a fermion is vC where v is the magnitude of the Higgs field and C is a coupling constant, different for each type of particle. C represents the strength of the particle's coupling to the Higgs field, and its value cannot presently be predicted. It's fair to say that the Higgs field is not the "origin of mass", whatever that might mean, but only allows it to be nonzero. The particle masses must derive from some yet-to-be-discovered theory.

Regarding the proportion of the proton's mass due to the Higgs mechanism, see this Wikipedia page:
The mass of the proton is about 80-100 times greater than the sum of the rest masses of the quarks that make it up, while the gluons have zero rest mass. The extra energy of the quarks and gluons in a region within a proton, as compared to the rest energy of the quarks alone in the QCD vacuum, accounts for almost 99% of the mass.
 
  • #7
The problem is that even if elementary fermions are massless, dressed fermions will have a mass due to dynamical chiral symmetry breaking. I don't know how much this would affect mass of electrons, only that they wouldn't be massless either way, but mass of protons and neutrons would be almost identical if you assume perfectly massless quarks.

I can probably do a mass estimate for chiral electrons via rainbow-ladder truncation of QED gap equation, though, if you would like.
 
  • #8
Bill_K said:
In the Higgs model, the mass of a fermion is vC where v is the magnitude of the Higgs field and C is a coupling constant, different for each type of particle.

This is for a fundamental fermion, right? E.g., this wouldn't apply to a proton.
 
  • #9
Fundamental and bare, yes.
 
  • #10
Naty1 said:
I think the above answers are literally correct in that they say spacetime curvature and mass have aspects other than Higgs effects. So in that sense, you can have spacetime curvature without mass...and without Higgs...energy density and pressure would be examples of phenomena [part of the stress energy tensor] causing space time curvature.

On the other hand I am somewhat troubled if the inference is that they are 'completely' unrelated.
I agree that it's wrong to say they're completely unrelated.

Naty1 said:
Within the context of existing models and understanding, that could be argued, I guess, but I'd rather see something like 'we don't have a clear understanding' or 'we have different models with different insights':
I don't think there's any big mystery here. It's very clear in GR how and why spacetime curvature exists. I think it's also pretty well understood in the standard model what role the Higgs plays in generating mass. Unresolved details would be things like whether the Higgs is really the standard model Higgs, multiple Higgses, or whatever -- but I don't think those affect the fundamental question.
 

1. What is the Higgs field?

The Higgs field is an invisible force field that exists throughout the universe. It is responsible for giving all particles their mass.

2. How does the Higgs field relate to space-time warping?

The presence of the Higgs field causes space and time to become curved, which is known as space-time warping. This is due to the interaction between the Higgs field and other particles in the universe.

3. Is the Higgs field necessary for space-time warping?

Yes, the Higgs field is required for space-time warping to occur. Without it, particles would not have mass and therefore there would be no interaction between the Higgs field and other particles to create the warping of space-time.

4. Can space-time warping occur without the Higgs field?

No, it is not possible for space-time warping to occur without the Higgs field. As mentioned earlier, the Higgs field is responsible for giving particles their mass, which is necessary for the warping of space-time.

5. Are there any other factors that contribute to space-time warping?

Yes, there are other factors that can contribute to space-time warping, such as the presence of massive objects like planets and stars. However, the Higgs field is a crucial factor in this phenomenon and without it, space-time warping would be significantly different or potentially not exist at all.

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