Physics Asked on November 19, 2021
When we apply parity on a field two times, we demand that we should get back the same field. This gives us, $P^{2} =1$, which implies, $ P psi = e^{i theta} psi$ . This extra phase factor is called intrinsic parity. Now, this is not just a phase factor. It is important because it’s value decided whether a spin 0 field is a scalar or Pseudo-scalar. But what exactly is intrinsic parity ? On what properties of field it depends?
You are viewing this the wrong way. If you apply parity operation to a scalar field (both real and complex field), you have: $$ Pphi (x) P^{-1} = n_Pphi (tilde{x}) tag{1} $$ where, $n_P$ is the intrinsic parity,
and the parity operator effects the coordinate transformation from $x$ to $tilde{x} = (t, -boldsymbol{x})$.
Now, if you apply the parity operation again, $$ P^2phi (x) P^{-2} = n_P Pphi (tilde{x}) P^{-1} = n_P^2 phi (x) $$ We should obtain the original field back. Thus, we see that $n_P^2 = 1$, which can only imply that $n_P = pm 1$.
We cannot determine intrinsic parity with free Lagrangian; for that, we need interactions. Suppose you have an interaction Lagrangian of the form, $$ L_{int} = - mu phi^3 - lambda phi^4 $$ Applying the parity transformation on the interaction Lagrangian, and subsequently using Eqn. (1) for each $phi$, we see that parity invariance would require that for the first term, $n_P^3 = 1$, and for the second term $n_P^4 = 1$. Both of these equations are satisfied simultaneously only if $n_P = 1$. Hence, for this case, $phi$ is a scalar field.
Answered by OmG on November 19, 2021
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