Why in general speaking the mass of gauge boson is zero?

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Discussion Overview

The discussion revolves around the mass of gauge bosons, particularly why most gauge bosons are considered massless, with exceptions noted for the W and Z bosons. Participants explore theoretical implications, self-energy considerations, and gauge symmetries, touching on concepts from quantum field theory and the Higgs mechanism.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • Some participants suggest that gauge bosons must be massless because they are associated with forces that propagate at the speed of light, implying their rest mass must vanish.
  • Others question the mass of gluons and the propagation speed of gravitons, indicating that these particles also exhibit massless behavior.
  • It is noted that Goldstone bosons inherently have zero mass, while W and Z bosons acquire mass through the Higgs mechanism.
  • Some participants argue that gauge bosons are massless due to gauge symmetry, which forbids mass terms in the Lagrangian, although self-energy contributions to mass are acknowledged as a complex issue related to gauge invariance.
  • There is a mention of Ward identities as a subtle aspect of gauge invariance that explains why self-energy does not contribute to gauge boson masses.

Areas of Agreement / Disagreement

Participants express differing views on the implications of gauge symmetry and the conditions under which gauge bosons can have mass. There is no consensus on the nuances of self-energy contributions or the broader implications of gauge invariance.

Contextual Notes

The discussion includes references to specific theoretical frameworks and concepts, such as the Higgs mechanism and gauge invariance, which may require further elaboration for clarity. Some assumptions about the nature of gauge bosons and their interactions remain unexamined.

ndung200790
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Please teach me this:
Why in general speaking the mass of gauge boson particle is zero(except W,Z bosons)?Because if we consider the self-energy of the bosons,we might think of the mass of gauge bosons.
Thank you very much for your kind helping.
 
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ndung200790 said:
Please teach me this:
Why in general speaking the mass of gauge boson particle is zero(except W,Z bosons)?Because if we consider the self-energy of the bosons,we might think of the mass of gauge bosons.
Thank you very much for your kind helping.

Well, both EM and gravitational radiation propagates at the speed of light; that means that their force carrying vector bosons must travel at the speed of light, therefore their rest mass must vanish. There are other, deeper, more mathematical reasons as well, but this I think is the simplest and most straightfoward explanation.
 
But how about gluon and why we know the speed of graviton is c(meaning speed of the propagation of gravity interaction is c)?
 
ndung200790 said:
But how about gluon and why we know the speed of graviton is c(meaning speed of the propagation of gravity interaction is c)?
We can analyse the classical, linearized field equations and we find a standard wave equation with

\partial_0^2 - \nabla^2

This is interpreted as a free, massless field propagating with c (plus interaction terms which have been neglected due to linearization)
 
I think the better way to think of it is 'why do the W and Z bosons have mass'? Gauge bosons are always massless unless something special happens to give them mass.
 
The reason gauge bosons are massless is exactly because they are GUAGE bosons. That is they obey a gauge symmetry which forbids mass terms in the Lagrangian (since we require the action to be gauge invariant - not change under gauge transformations).

However the mass terms in the Lagrangian only represent tree level masses. It is, as the question asks, not so obvious that self energy diagrams would not contribute to the gauge boson masses. The fact that they don't is again down to gauge invariance but is more subtle and is seen via the Ward identities (themselves a result of gauge invariance). This is all nicely explained on pages 20-23 of Willenbrock's excellent review of "Symmetries of the Standard Model".

The fact that the Ws and Z can have masses is because the gauge symmetry is spontaneously broken by the Higgs vev, but that is a whole other story...
 

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