How and why do quantum fields interact with each other?

In summary, quantum fields interact by exchanging particles (e.g. photons or W and Z bosons). This is an interaction within a different type, and it is only possible if the resulting interaction can be detected.
  • #1
Daniel Bolstad
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Why is it that quantum fields interact? How do they do this? Does every exitation of any field affect all other fields?

I'd appreciate an explanation that uses as little math as possible, I don't have a science background.
 
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  • #2
Daniel Bolstad said:
Why is it that quantum fields interact? How do they do this? Does every exitation of any field affect all other fields?

I'd appreciate an explanation that uses as little math as possible, I don't have a science background.

Then maybe you need to first explain to us what you mean when you ask "quantum fields interact". You seem to be using familiar terms, but it doesn't seem to feel as if you are aware what they are.

For example, what makes you think that "every exitation of any field affect all other fields"? Where did you get this, and where did this come from? Do you have an example of this to support your claim? The "weak interaction" doesn't interact with the EM interaction. If it does, then neutrinos won't be this difficult to detect and interact. This is what I mean by you are using familiar terms, but I don't think you know what they are.

So don't ask us why the color of the unicorn's horn is pink. Let's first establish that there IS a unicorn, i.e. establish that you actually know what "quantum field theory" is to start with. Can you do that?

Zz.
 
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  • #3
I'm afraid the OP has asked for explanations of things way above his head, so we can't formulate any answer that he could understand.
 
  • #4
If fields wouldn't interact, they would not be observable. The problem is that nobody knows how to exactly treat interacting fields. So we have to use clumsy perturbation theory starting from free fields crossing our fingers that it may describe something remotely similar to reality.
 
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  • #5
DrDu said:
If fields wouldn't interact, they would not be observable. The problem is that nobody knows how to exactly treat interacting fields. So we have to use clumsy perturbation theory starting from free fields crossing our fingers that it may describe something remotely similar to reality.

That is not the issue here. In many cases, we detect neutrinos not because its field "interact" with other fields, but because it has a small cross-section in scattering off atoms and electrons, and those electrons create the cherenkov radiation. That's how we detect them, but this is not "weak interaction interacting with EM interaction". And we know that leptons certainly do not participate in the strong interaction.

The OP just need to really explain a lot more here, especially on where he/she got such ideas, because I have a strong feeling that the context is missing.

Zz.
 
  • #6
ZapperZ said:
In many cases, we detect neutrinos not because its field "interact" with other fields, but because it has a small cross-section in scattering off atoms and electrons[...]
Doesn't scattering off the electrons qualify as an interaction?
 
  • #7
DrDu said:
Doesn't scattering off the electrons qualify as an interaction?

Yes, but this is via the exchange of W or Z boson, not W/Z with photons. It is not interaction within the same type. It is the interaction with another "specie" that is the issue here.

Zz.
 
  • #8
Well, if you have a question that doesn't allow me to give an answer, I just don't respond ;-)). QFT is not communicable without math!
 
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  • #9
ZapperZ said:
Yes, but this is via the exchange of W or Z boson, not W/Z with photons. It is not interaction within the same type. It is the interaction with another "specie" that is the issue here.

Zz.
Of course, but if the neutrino would not interact weakly with the electrons and the electrons with the em field, i.e. if one field would totally decouple from the rest, we would not have any means to observe it. So we are forced to consider interacting fields.
 
  • #10
DrDu said:
Of course, but if the neutrino would not interact weakly with the electrons and the electrons with the em field, i.e. if one field would totally decouple from the rest, we would not have any means to observe it. So we are forced to consider interacting fields.

But the 2nd part is "optional". We just happen to get a particle that couples to the EM field. It doesn't have to be that way all the time, which may explain why we don't detect neutrinos efficiently, despite its abundance (i.e. we are oblivious its many other interactions). And once the electron is out, it is like any other electron.

So yes, in my view, they are decoupled, and only if the resulting interaction can produced detectable (EM) interaction can we observe it.

Zz.
 

Related to How and why do quantum fields interact with each other?

1. How do quantum fields interact with each other?

Quantum fields interact with each other through the exchange of particles called "force carriers." These force carriers carry the fundamental forces of nature, such as electromagnetism and the strong and weak nuclear forces.

2. Why do quantum fields interact with each other?

Quantum fields interact with each other because of the fundamental laws of quantum mechanics, which govern the behavior of particles and fields at the subatomic level. These laws dictate that particles and fields cannot exist independently and must constantly interact with each other.

3. What are the consequences of quantum fields interacting with each other?

The consequences of quantum fields interacting with each other include the manifestation of fundamental forces, the creation of virtual particles, and the formation of particles and matter. These interactions also play a crucial role in the behavior of matter and energy in the universe.

4. How does the interaction of quantum fields affect our everyday lives?

The interaction of quantum fields is responsible for the physical properties and behavior of matter and energy in our everyday lives. For example, the interaction of electromagnetic fields allows for the functioning of electronic devices, while the strong and weak nuclear forces govern the structure and behavior of atoms and molecules.

5. Are there still unanswered questions about the interaction of quantum fields?

Yes, there are many unanswered questions about the interaction of quantum fields, including how to reconcile quantum mechanics with Einstein's theory of general relativity, how to unify the fundamental forces into a single theory, and how to explain the origin of mass and the hierarchy of particle masses.

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