it has to be assumed since it's not impossible for charge to exist along the axes/points of symmetry for the conductor
i.e., a single point charge in the center of a sphere, or a continuous line of charge along the cylindrical axis of symmetry for a cylindrical conductor
there's probably some semantics about what the right 'definition' is
the formal definition i'd probably fall back on is "a conductor is what you get if you start with a dielectric material and take $\epsilon\to \infty$."
@Obliv in reality it is very logical in electrostatics. The definition of conductor is a material where charge is free to move, at equilibrium (which is were electrostatics works) no charge should be moving and for that to happen you need $\vec{E} = 0$ inside the conductor or else the charge would be free to move
For the level of the discourse it is extremely clear that it is some kind of misuderstanding. It should be an insulator. But when you learn further and need to model what the electrons inside a metal is doing, then we would treat all the freed electrons in a statistical thermodynamics model, separate from all the ions. The first approximation is then to smear the ions out into a uniform charge density background. Later, when you learn crystalline physics, then you can upgrade to crystalline
is this an appropriate writing down of the Hamiltonian of an ideal scattering experiment?
i remark that I do not explicitly define what the Hamiltonian is between the asymptotic behavior and the bounds of the finite interaction interval $\mathcal{I}$
i don't understand how this quantity can be a distribution? at what point did we turn it into a distribution... it should just be an inner product i would have thought and so a complex number
i should clarify that the incoming and outgoing state at this point is assumed to be a particle in a length $L$ box for now, but i guess i see your point once we take the $L \to \infty$ limit
okay i guess that makes sense. if the incoming and outgoing waves are plane waves then surely the $S$-matrix is not a discretely indexed matrix (in the momentum basis)
okay so it is really an artifact of the idealized set up
and then when we move into a real picture maybe we integrate twice: once over $k$ and once over $k'$ to get our packets
Is there any modern physics book which is not just plug the numbers and get the answer( I have books like Arthur beiser and paul tipler but they just throw formulas and in example number that have to be plugged and get the answer)