Why is there a need for the Higgs?

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In summary: I understood so far.In summary, the Higgs field gives mass to some particles, the Higgs particle is just a temporary excitation of the field, and the topic of mass in particle terms is complicated and still being studied.
  • #1
rlinsurf
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I'm having hard time getting my head around this. If E=mc2, then why do we need a Higgs Boson? Can't all matter simply be pockets of greater or lesser intensity (i.e. energy with highly stable angular momentum carrying mass, less stable angular momentum as short-lived particles, and energy as radiation as massless) in an M-Brane of energy? A Higgs Field, without the Higgs?
 
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  • #2
rlinsurf said:
I'm having hard time getting my head around this...why do we need a Higgs Boson?...
... A Higgs Field, without the Higgs?
The idea that Peter Higgs had, along with several other people about the same time, was of a FIELD, not of a particle.
It is the Higgs field, not the particle, which dissolves a symmetry in and provides certain particles with mass.
The Higgs particle is merely a temporary excitation of the field, one whose decay processes can be observed thus providing EVIDENCE for the existence of the field. Think of it as just a temporary blip in the field. Studying the blips let's physicists learn about the field (which is the main thing.)

This is all still in the context of the Quantum Field Theory elaborated in the 1970s. It does not involve "string" or "M-brane" math.

So your basic intuitive hunch, as I see it, is in the right direction. i.e. thinking about it in field terms with the often-very-short-lived field quanta, the blips predicted by QFT, arising and becoming observable in some cases comparatively rarely.

BTW Linsurf, this is actually not a Beyond the Standard Model topic!
Quantum Field Theory (QFT), the context in which this makes sense, is the basis of the Standard Model! You might, in fact, get a more focused informative discussion of the Higgs field and related phenomena if you posed your question in the neighboring forum called
High Energy, Nuclear, and Particle Physics forum, just one item up on the menu.
 
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  • #3
Hi, Marcus--

Thanks for your reply, and for making things clearer to me :)

I'm still a bit confused however. The media reports that the Higgs Boson imparts mass to all matter. So that's wrong? It's actually the field itself?
 
  • #4
Oh, and then I will move the topic to QTF. I'd just like to hear the answer from someone I can understand :)
 
  • #5
rlinsurf said:
...The media reports that the Higgs Boson imparts mass to all matter. So that's wrong? It's actually the field itself?

The media is wrong.
It is actually the field.
Actually it is only SOME of matter's mass which is imparted by the Higgs field.
You can find out more about this if you post a question in the neighbor PF form which does regular mainstream high energy physics, and related.
It is not unusual for the media to be wrong concerning technical detail, or for media language to be misleading.
 
  • #6
Ok, thank you, Marcus. Topic moved.
 
  • #7
Such stumbling is common in popularizations, sad to say.

As to particle vs. field, *every* elementary "particle" is a quantized field. The billiard-ball stereotype doesn't come close to fitting. However, it fits better for bound states like hadrons and nuclei and atoms and molecules ... and billiard balls themselves.

As to the Higgs particle making everything massive, it only gives mass to most of the other Standard-Model particles. The photon and gluon stay massless, however.


There is a certain "gentleman" whom I shall not name who claims that the Higgs particle is greatly oversold as the source of mass, on the ground the nearly all the mass of familiar matter is due to QCD effects. However, the proton and neutron are bound states, not SM elementary particles. But the electron does get its mass from the Higgs particle.
 
  • #8
Now I'm confused. So is mass, at least in some(?) particles, given by the Higgs field or the Higgs boson?
 
  • #9
I guess I've always had an idea in my head that the universe follows Einstein, and that mass is the warping of space-time. So that's what I'm having a hard time with. A Higgs field I think I can visualize. But why do we need a Higgs particle?

Please excuse my n00bness.
 
  • #10
It' simple: there are elementary particles which behaves as if they have some mass; the theory used to formulate their interactions does not allow for a simple mass-term b/c it breaks gauge invariance; therefore Higgs et al. invented a field which (in a mathematical sense!) behaves as if it creates a mass term for some of the particles. When quantizing thos field the mass-generation mechanism remains pretty classically but in addition one adds massive excitations which are interoretetd as Higgs bosons.

Regarding GR: GR does in way explain mass (or energy) in terms of spacetime curvature; it's exactly the other way round, GR explains spacetime curvature as an effect caused by energy; GR does not know further details about this energy, which fields carry this energy etc.; this is an additional input on top of GR.

And we don't ned GR in this context, the Higgs effect can be formulated using SR.
 
  • #11
I apologize. I think that's a bit above my head.
 
  • #12
rlinsurf said:
I apologize. I think that's a bit above my head.
What exactly?

What I am saying is that GR does not explain mass or energy, but that mass or energy is used in the context of GR (my car does not explain how a motor works, but it contains a motor).

Asking questions like "why do we need a Higgs particle?" are difficult to answer. We propose a theory which solves the problem of mass generation; we observe that the mechanism used does not only produce mass but that in addition it introduces an additional boson. The reason why we do this is b/c it works. The idea was not to invent a theory with a Higgs boson; the idea was to invent a theory solving the mass problem; the simplest approach comes with an additional particle which is a new prediction. The theory works fine, so we trust in this prediction and try to find the particle. Not more, not less.
 
  • #13
There is a certain "gentleman" whom I shall not name who claims that the Higgs particle is greatly oversold as the source of mass, on the ground the nearly all the mass of familiar matter is due to QCD effects. However, the proton and neutron are bound states, not SM elementary particles. But the electron does get its mass from the Higgs particle.
This is partly attributable to our current state of ignorance. The Higgs field is complicit in the mass of every elementary particle that participates in the weak interaction. But there are several other situations that may involve particles that do not see the weak interaction, and while they are currently hypothetical, would entail a mass that did not arise from Higgs.

The masses of supersymmetric partners, if they are shown to exist, would have to come from somewhere else. Likewise for axions. The mass of dark matter particles. And a Majorana mass for neutrinos.
 
  • #14
I see. Thank you, Bill. I think I understand :)
 

1. Why is the Higgs boson important in understanding the universe?

The Higgs boson is an essential part of the Standard Model of particle physics. It is responsible for giving mass to particles, which allows for the formation of atoms, molecules, and ultimately, everything we see in the universe. Without the Higgs, the laws of physics would be very different, and the universe as we know it would not exist.

2. How was the Higgs boson discovered?

The Higgs boson was discovered in 2012 at the Large Hadron Collider (LHC) in Geneva, Switzerland. The LHC is the world's largest particle accelerator, and it was used to collide protons at incredibly high energies. The resulting data showed evidence of a particle with the expected properties of the Higgs boson, confirming its existence.

3. What is the role of the Higgs field in the Higgs mechanism?

The Higgs field is a theoretical concept that permeates the entire universe. It is through interactions with this field that particles acquire mass. The Higgs mechanism explains how the Higgs field gives mass to particles and is an important part of the Standard Model of particle physics.

4. How does the discovery of the Higgs boson impact our understanding of the universe?

The discovery of the Higgs boson confirmed the existence of the Higgs field and its role in giving mass to particles. This has increased our understanding of the fundamental building blocks of the universe and how they interact with each other. It has also provided evidence for the validity of the Standard Model and opened up new avenues for further research and discoveries.

5. Are there any practical applications of the Higgs boson?

While the discovery of the Higgs boson has not led to any immediate practical applications, it has contributed to our understanding of the universe and fundamental particles. This knowledge can potentially lead to advancements in technology and medicine in the future. Additionally, the technologies developed for the discovery of the Higgs boson, such as the LHC, have practical applications in other fields such as medical imaging and material science.

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