Why Higgs produces different masses for electron and muon

In summary, the Higgs field is responsible for giving mass to elementary fermions, but the actual values of their masses depend on additional physics beyond the Standard Model. The popular notion that the Higgs field is solely responsible for fermion masses is misleading, as there are other factors at play. These include independent coupling parameters between the Higgs field and fermions, and a constant (C) that varies for each fermion and its origin is unknown. The SM can also accommodate fermion masses without the Higgs mechanism, but it becomes more complicated when renormalization is taken into account. Ultimately, the Higgs mechanism replaces a variety of masses in the theory with a variety of Yukawa couplings instead.
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bcrowell
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Elementary fermions get their mass from the Higgs field. The electron and the muon have the same charge, i.e., the same coupling to the electroweak interaction. If these two particles are identical except for mass, then how can the Higgs mechanism give rise to different masses for them?
 
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All interaction terms Higgs field <-> fermions have independent coupling parameters.
 
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The popular notion that the Higgs field "gives mass" to fermions is misleading. The mass term is actually a product vC where v is the value of the Higgs field (246 GeV) and C is a constant different for each particle and of unknown origin. The Higgs field v only permits the masses to be nonzero. Their actual values depend on BSM physics which gives them mass, encapsulated in the C's.
 
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Thanks for the replies. That seems like an extremely ugly and unsatisfactory situation.
 
  • #5
Ugly it is.

To be fair, the SM accommodates fermion masses even without the Higgs mechanism, provided you don't need to renormalize. When you renormalize, you get the condition that the mass from the Higgs mechanism is proportional to the de novo mass, which is even uglier, so most folks prefer to think that the non-Higgs component of the mass is zero, and the only mass comes from the Higgs.

So essentially, you replace a bunch of random masses in the theory with a bunch of random Yukawa couplings in the theory.
 

Related to Why Higgs produces different masses for electron and muon

1. Why does Higgs produce different masses for electron and muon?

The Higgs field is responsible for giving particles their mass. The difference in mass between the electron and muon is due to the strength of their interactions with the Higgs field. The muon has a stronger interaction, resulting in a larger mass compared to the electron.

2. How does the Higgs field give particles mass?

The Higgs field interacts with particles through the Higgs mechanism, which gives particles their mass by slowing them down as they move through the field. The more a particle interacts with the Higgs field, the more massive it becomes.

3. Why do the electron and muon have different interactions with the Higgs field?

The strength of a particle's interaction with the Higgs field is determined by its coupling constant, which is a fundamental property of the particle. The electron and muon have different coupling constants, resulting in different interactions with the Higgs field and therefore different masses.

4. Is the Higgs field responsible for the mass of all particles?

No, the Higgs field only gives mass to some particles. The mass of other particles, such as photons, is zero because they do not interact with the Higgs field at all.

5. Can the Higgs field change the mass of a particle?

No, the Higgs field cannot change the mass of a particle once it has been determined. The mass of a particle is a fundamental property and cannot be altered by any external force or interaction.

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