I am following a course about gauge theories in QFT and I have some questions about the physical meaning of what we are doing.
This is what I understood:
When we write a Lagrangian $\mathcal{L}(\phi)$, we are looking for its symmetries. Its symmetries are the transformation we apply on the fields that let the Lagrangian unchanged.
It means we are acting with an operator $U$ on the field $\phi$ and we will have: $\mathcal{L}(\phi'=U \phi)=\mathcal{L}(\phi)$.
And the operators $U$ belongs to a group.
Symmetries are very important because according to Noether theorem we can find the current conserved by knowing the symmetries.
In gauge theories, we allow the transformation $U$ to act "differently" on each point of the space. Then we have $U(x)$ (x dependance of the group element).
Thus, in my class the teacher did the following:
He remarked that this quantity:
$$ \partial_{\mu} \phi $$ doesn't transform as:
$$ \partial_{\mu} \phi'=U(x) \partial_{\mu} \phi $$ (because of the $x$ dependance of $U$).
And then he said "we have a problem, let's introduce a covariant derivative $D_{\mu} \phi$ that will allow us to have:
$$D_{\mu} \phi'=U(x)D_{\mu} \phi $$
My questions are the following:
Why do we want to have this "good" law of transformation? I am not sure at all but this is what I understood and I would like to check.
- First question: please tell me if I am right in this following paragraph
I think it is because we want to write the Lagrangian as invariant under gauge transformation. To do it we don't start from scratch: we start from a term that we know should be in the Lagrangian: $\partial_\mu \phi^{\dagger} \partial^{\mu} \phi$. We see that this term is not gauge invariant, so we try to modify it by "changing" the derivatives: $\partial_\mu \rightarrow D_\mu$. We see that if we have $D_{\mu} \phi'=U(x)D_{\mu} \phi$ we will have the good law of transformation. And finally, after some calculation we find the "good" $D_\mu$ that respect $D_{\mu} \phi'=U(x)D_{\mu} \phi $.
So: Am I right in my explanation?
Also:
Why do we want a Lagrangian invariant under gauge transformations? Is there a reason behind it or it is just a postulate? I could understand that we want Lagrangian invariant under global transformation (if we assume the universe isotropic and homogenous it makes sense), but for me asking a local invariance is quite abstract. What is the motivation behind all this?
I know that if we have lagrangian invariant under all local symmetries then it will be invariant under global symmetries, but this "all" is "problematic" for me.
- Next question in the following two lines:
Why should the lagrangian be invariant under all local symmetries? It is a very strong assumption from my perspective.
I would like a physical answer rather than too mathematical one.
