Quark decay and particle materialization

In summary, in the beta decay case, a neutron becomes a proton, electron and antineutrino are created, but the electron and antineutrino are not made of the same particles as the neutron.
  • #1
rustynail
53
0
Hello!

I have read that in the case of beta decay, a neutron becomes a proton

neutron = proton + electron + antineutrino

but the electron and antineutrino are ''materialized'' by the emission of an intermediate w- boson. What does ''materialize'' mean in this context? I have thought of the w boson inputting the necessary energy to collapse the electron's and antineutrino's wafe function in some place where their probabilities are nonzero.

Can anyone help me understand the meaning of 'materialize' in this context ?
 
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  • #2
Sounds like they just mean that it is created. How could the wavefunctions collapse if the particles didn't exist before that?
 
  • #3
How are they created?
 
  • #4
Would anyone mind shedding some light on this problem?
How can a boson create a particle-antiparticle pair without breaking the energy conservation law?
 
  • #5
rustynail said:
Would anyone mind shedding some light on this problem?
How can a boson create a particle-antiparticle pair without breaking the energy conservation law?

What about it breaks the conservation law? The energy is removed from a down quark as it is converted to an up quark which is lighter in mass.
 
  • #6
Ok thank you.

But, now, wouldn't it imply that electrons and antineutrinos are some of the constituents of the W boson, and by extension, of the neutron?
 
  • #7
rustynail said:
Ok thank you.

But, now, wouldn't it imply that electrons and antineutrinos are some of the constituents of the W boson, and by extension, of the neutron?

Nope. They are created by the mass/energy of the particle when it decays. Note that in particle colliders it is routine to collide two or more particles together and get a shower of newly created particles that have a rest mass GREATER than the rest mass of the original colliding particles. This does not imply that the original particles were made up of all these other particles, but that the energy of the original particles is converted into mass for creation.

See here for more: http://en.wikipedia.org/wiki/Elementary_particle

Edit: Forgot to mention the fact that W-Bosons can also decay into quark-antiquark pairs. In this case and in the beta decay case, the energy and mass is completely accounted for. If both quark-antiquarks AND electrons and neutrions were created at the same time that would be a violation, as there isn't enough energy. So clearly a W-Boson cannot be composed of any of these particles as we should see them in every decay, which we don't.
 
Last edited:
  • #8
Thank you, I appreciate !
 

1. What is quark decay?

Quark decay refers to the process in which a quark particle transforms into a different type of quark particle. This occurs due to the weak nuclear force, which is responsible for changing the flavor of quarks.

2. How does quark decay contribute to particle materialization?

Quark decay plays a crucial role in particle materialization by allowing for the creation of new particles with different combinations of quarks. When quarks decay and combine with other particles, such as gluons, they form new particles, which contribute to the materialization of matter.

3. What are the implications of quark decay for the Standard Model of particle physics?

Quark decay is a fundamental process that is incorporated into the Standard Model of particle physics. It helps to explain the behavior and properties of subatomic particles, and its inclusion in the model has led to successful predictions and discoveries in the field of particle physics.

4. Can quark decay be observed in experiments?

Yes, quark decay can be observed in experiments, although it is a rare process due to the high energies and short lifetimes involved. Scientists use particle accelerators to create and study quarks and their decay products, providing evidence for the existence of quark decay.

5. How does quark decay differ from other forms of decay, such as alpha or beta decay?

Quark decay is a distinct process from other forms of decay, such as alpha or beta decay, which involve the transformation of atomic nuclei. Quark decay occurs on a much smaller scale, within the subatomic realm, and is governed by different fundamental forces and laws of physics.

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