A massive force carrying particle? The weak nuclear force, the W boson has mass?

In summary, the W boson of the weak nuclear force has mass and does not travel at the speed of light. It can emit other gauge bosons and has spin and electric charge. The concept of virtual particles also applies to the W boson.
  • #1
filegraphy
93
0
I was looking at the list of the force carrying particles and all of their masses read zero other than the W boson of the weak nuclear force.

Q: Does the W boson travel at the speed of light even if it is massive? (I am guessing not)
Q: If the W boson is massive then it emits other gauge bosons in a gravitational field. How can this be? A boson emit other bosons?
Q: Does the W boson have spin or charge?

Thank you for answering.
 
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  • #3
filegraphy said:
I was looking at the list of the force carrying particles and all of their masses read zero other than the W boson of the weak nuclear force.

The Z boson also has mass.

filegraphy said:
Q: Does the W boson travel at the speed of light even if it is massive? (I am guessing not)

No, a W boson will not travel at the speed of light.

filegraphy said:
Q: If the W boson is massive then it emits other gauge bosons in a gravitational field. How can this be? A boson emit other bosons?

I don't really want to talk about gravitons, but a W boson has electric charge and so it couples directly to photons (see the next question). So there's no problem with a boson emitting other bosons.


filegraphy said:
Q: Does the W boson have spin or charge?

The W is a spin 1 particle with electric charge of +1 or -1. See the pdf that mathman linked to for more details.
 
  • #4
the_house said:
No, a W boson will not travel at the speed of light.

why not, it is virtual and does not satisfy E^2 = P^2 + M^2
 
  • #5
The W-boson need not be a virtual particle; it is only a particle with a rather short lifetime; but in that sense even neutrons are only virtual particles.

A virtual particle does not have a velocity at all. A virtual particle is not a single particle but a "bunch of all particles possible in momentum space" with an "integral over momentum space".
 
  • #6
Thank you all for the answers. That makes sense that the W and Z bosons cannot travel at the speed of light because there fore would require infinite amount of energy to get it to that speed causing it to have an infinite amount of mass.
 

1. What is a "massive force carrying particle"?

A massive force carrying particle, also known as a gauge boson, is a fundamental particle that carries a specific type of force in the universe. These particles are responsible for mediating the interactions between other particles.

2. What is the weak nuclear force?

The weak nuclear force is one of the four fundamental forces of nature, along with gravity, electromagnetism, and the strong nuclear force. It is responsible for nuclear decay and is the reason why some particles can transform into other types of particles.

3. What is the W boson?

The W boson is a subatomic particle that is the force carrier for the weak nuclear force. It has a mass of about 80 times the mass of a proton and is essential for the process of beta decay.

4. How does the W boson have mass?

The W boson, like all particles, has mass due to its interaction with the Higgs field. This field gives particles their mass by slowing them down as they move through it. The more a particle interacts with the Higgs field, the more massive it becomes.

5. What are the implications of the W boson having mass?

The fact that the W boson has mass is a crucial component in the Standard Model of particle physics. It helps explain the phenomenon of weak interactions and is necessary for understanding the behavior of subatomic particles. Additionally, the mass of the W boson can provide insight into the properties of the Higgs field and the origin of mass in the universe.

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