I want to understand the Schrödinger, Heisenberg and interaction picture and have a few questions about them:
So in general you have a time-dependent Hamiltonian $H$, as for example the potential may depend on time. This should not depend on what picture you use, so this is somewhat counterintuitive, as people always say: Schrödinger picture does not include time-dependent operators.
I am not so sure about the Heisenberg picture actually. Clearly, it deals with operators that are time-dependent, but I am not so sure if this includes the Hamiltonian itself. Especially, since the Hamiltonian is determined by the system, I am not so sure whether this operator should satisfy $$\hat A_{\rm H}(t)=\hat U^{\dagger}(t)\,\hat A_{\rm S}(t)\,\hat U(t).$$ So, do we have $$\hat H_{\rm H}(t)=\hat U^{\dagger}(t)\,\hat H_{\rm S}(t)\,\hat U(t)$$ for the Hamiltonian too in the Heisenberg picture?
In the interaction picture with a Hamiltonian $H = H_{0,S} + H_{1,S}$ a state is given by $$| \psi_{I}(t) \rangle = e^{i H_{0, S} t / \hbar} | \psi_{S}(t) \rangle $$
and the operator by $$A_{I}(t) = e^{i H_{0,S} t / \hbar} A_{S}(t) e^{-i H_{0,S} t / \hbar}. $$
This somehow seems as if $H_{1,S}$ would never appear in the time-evolution of the system which would be counterintuitive. So where does $H_{1,S}$ affect the system and are there any restrictions on $H_{0,S}$ and $H_{1,S}$?
