Momentum exchange of virtual pions

In summary, the strong force is primarily mediated by virtual pions between two nucleons, but there are also other contributions such as direct gluon exchange and other mesons. Pions are the most effective mediators due to their light mass and lack of confinement, but at smaller distances, other processes involving explicit quark-gluon exchange may occur. However, these processes are not dominant in nuclear physics due to confinement and higher masses of mediator particles.
  • #1
gildomar
99
2
I know that the strong force is viewed as the exchange of virtual pions between two nucleons, with the mass and range of them confirmed by the energy-time uncertainty principle. But if the momentum of the pion is transferred from one nucleon to the other in the interaction, wouldn't that give an equivalent repulsive force between them instead of an attractive one?
 
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  • #3
Thanks; guess I didn't look far enough back in the past topics.
 
  • #4
Virtual pion exchange is just one of the contributions. It's the dominant effect, but there are other things going on. Nucleons can exchange gluons directly, as well as exchange other mesons. Pions happen to be the lightest of mesons and not restricted by confinement, so they end up being better mediators for nuclear forces, but not the only ones there.
 
  • #5
gluons don't exist in the nuclei level due to confinement, so that's why in fact (effectively) you get the puons.
The main quarks you can make your "effective particle" consist of, are up and down, because I think (from the deep inelastic scattering on protons) we already know that strange is not favorable at all...it's almost not existing in the sea particles...
 
  • #6
How can you draw any strong interaction without involving gluons?
 
  • #7
K^2 said:
Virtual pion exchange is just one of the contributions. It's the dominant effect, but there are other things going on. Nucleons can exchange gluons directly, as well as exchange other mesons. Pions happen to be the lightest of mesons and not restricted by confinement, so they end up being better mediators for nuclear forces, but not the only ones there.

From www.phy.ohiou.edu/~elster/lectures/fewblect_2.pdf‎:

Fortunately, at distances larger than the nucleon extension, which dominate nuclear physics phenomena, color confinement dictates that nucleons can only interact by exchanging colorless objects, i.e. just mesons. Only at smaller distances, at which the two nucleons overlap, genuinely new processes may occur involving explicit quark-gluon exchange. Due to the repulsive core on the NN interaction, however, both nucleons do not come very close to each other unless the scattering energy is very high. Thus, there is good reason to believe these processes not to dominate the NN interaction for energies relevant in nuclear physics.
 
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  • #8
That's precisely what I said. Pions dominate interaction because they are not confined. Other processes are non-dominant either due to confinement or higher masses of mediator particles. Where's the problem?
 
  • #9
K^2 said:
That's precisely what I said. Pions dominate interaction because they are not confined. Other processes are non-dominant either due to confinement or higher masses of mediator particles. Where's the problem?
Please don't take offense when someone agrees with you. :wink:
 

1. What is "momentum exchange"?

"Momentum exchange" refers to the transfer of momentum between two particles during a collision or interaction.

2. What are virtual pions?

Virtual pions are particles that are predicted to exist based on mathematical models, but have not been directly observed in experiments. They play an important role in the theory of quantum chromodynamics (QCD), which describes the strong interaction between particles.

3. How do virtual pions exchange momentum?

Virtual pions exchange momentum through the strong force, one of the four fundamental forces in nature. This force is carried by particles called gluons, and virtual pions interact with these gluons to transfer momentum.

4. What is the significance of momentum exchange of virtual pions?

The momentum exchange of virtual pions is important for understanding the dynamics of subatomic particles and the strong force. It also plays a crucial role in calculations and predictions of particle interactions in QCD.

5. Can virtual pions be observed in experiments?

No, virtual pions cannot be directly observed in experiments because they are not stable particles. However, their effects can be observed indirectly in the behavior of other particles during high-energy collisions.

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