Help understanding the Higgs field?

In summary, the way I understand it is that certain particles move through the Higgs field and encounter no resistance, giving it no mass. The others that do encounter resistance are the ones that have mass. But if increasing resistance means increasing mass, why wouldn't things become infinitely massive? Also, why don't all of the Higgs bosons come together, seeing as they basically are mass, shouldn't they just keep attracting each other through gravity? Lastly, (for now at least) how can a W or Z boson be less massive than a single Higgs boson?
  • #1
RagingHadron
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So the way I understand it is that certain particles move through the Higgs field and encounter no resistance, giving it no mass. The others that do encounter resistance are the ones that have mass. But if increasing resistance means increasing mass, why wouldn't things become infinitely massive? Also, why don't all of the Higgs bosons come together, seeing as they basically are mass, shouldn't they just keep attracting each other through gravity? Lastly, (for now at least) how can a W or Z boson be less massive than a single Higgs boson? :confused: :confused: :confused:
 
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  • #2
The 'resistance' picture is very misleading. What really goes on is quite different - we say the Higgs field is coupled to the fermionic fields that represent the matter particles. In empty space, the Higgs field takes a value - called the vacuum expectation value (or VEV) - at every point. When particles interact, we can represent this by a Feynman diagram (do a google search for some pictures of what a Feynman diagram looks like). The interactions occur at points called vertices. At each vertex, the particle interacts with the VEV of the Higgs field. This is called a Yukawa interaction, and we plug it into the Standard Model Lagrangian (a Lagrangian is a term that essentially express the energy of the system, in the form kinetic minus potential energy) and declare that the fermions have mass given by the value of the VEV, and the strength of the coupling of each fermionic field to the Higgs field.

Gravity is negligible at the scale of particle physics. Only at extremely high energies is gravity relevant in particle physics.

Why does is seem odd that the W and Z bosons have less mass than a Higgs boson?
 
  • #3
Wait, so just to make sure I'm understanding, fields describing fermions are coupled to another field, the Higgs field, and so they interact. The Higgs field comes with a value that, since it comes with the fermionic field passes that value onto the fermion?

And if the Higgs takes a value at every single point in space, wouldn't any small amount of gravity be significant? Do they not interact with each other for some reason?

Also, is it the same for leptons?

Many thanks
 
  • #4
Oh and it seemed odd that they had less mass because I was thinking of the Higgs as like a single "unit" of mass, not as a particle whose interactions constitute mass <--(correct?)
 
  • #5
RagingHadron said:
Wait, so just to make sure I'm understanding, fields describing fermions are coupled to another field, the Higgs field, and so they interact. The Higgs field comes with a value that, since it comes with the fermionic field passes that value onto the fermion?
Essentially, that's the idea. The Higgs field couples to fermions, and the strength of the coupling determines the mass of those fermions.
And if the Higgs takes a value at every single point in space, wouldn't any small amount of gravity be significant? Do they not interact with each other for some reason?
Well, yes, the Higgs field carries a potential. But this is irrelevant. Similar to how gravity is irrelevant when describing electromagnetism and the strong force.
Also, is it the same for leptons?
Leptons are fermions, so yes.
 
  • #6
Ahhh thanks!
 
  • #7
RagingHadron said:
Oh and it seemed odd that they had less mass because I was thinking of the Higgs as like a single "unit" of mass, not as a particle whose interactions constitute mass <--(correct?)

The Higgs boson is the quantum of the Higgs field. It doesn't make up a unit of mass, since it's the VEV of the Higgs field that determines fermion masses.
 
  • #8
So since the fields are coupled the VEV will always have/be giving a value because an interaction is always occurring? Is that how it works?

Sorry...I'm trying to think of a way to visualize this in my mind and it's proving to be pretty difficult..
 
  • #9
RagingHadron said:
So since the fields are coupled the VEV will always have/be giving a value because an interaction is always occurring? Is that how it works?

Sorry...I'm trying to think of a way to visualize this in my mind and it's proving to be pretty difficult..

Right. Every fermionic field has a coupling constant that determines how strongly it couples to the Higgs field. Together with the Higgs VEV, this determines the particle masses.

Don't worry, there really isn't anything you can do to visualize it. That's why I said it's misleading to describe it as some kind of 'molasses'.
 
  • #10
Ahhhh thanks so much for all of your help!
 

1. What is the Higgs field?

The Higgs field is a fundamental concept in particle physics that is thought to give particles their mass. It is a field that permeates all of space and is responsible for the existence of the Higgs boson, a particle that was first observed in 2012.

2. How does the Higgs field work?

The Higgs field works by interacting with particles as they move through it. This interaction slows down the particles and gives them mass. The more a particle interacts with the Higgs field, the more mass it has.

3. Why is the Higgs field important?

The Higgs field is important because it is believed to be responsible for the existence of mass in the universe. Without the Higgs field, particles would not have mass and the universe would be very different from what we observe today.

4. How was the Higgs field discovered?

The Higgs field was first theorized by physicist Peter Higgs in the 1960s. It was later confirmed in 2012 by the Large Hadron Collider at CERN, where scientists observed the Higgs boson, a particle predicted by the theory of the Higgs field.

5. What are the implications of understanding the Higgs field?

Understanding the Higgs field could lead to a better understanding of the fundamental forces and particles that make up our universe. It could also help scientists develop new technologies and potentially lead to new discoveries in particle physics.

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