0path 1path 2B fieldr rConsider two different paths from~r 0 to~r.
f 1 (~r)−f 2 (~r) =∮
d~r·A~=∫
dS~·∇×~ A~=∫
dS~·B~= ΦThe difference between the two calculations of f is the flux.
Nowfis not a physical observable so thef 1 −f 2 does not have to be zero, but,ψdoes have to be
single valued.
ψ 1 = ψ 2
⇒ e−i
̄hcef^1
=e−i
̄hcef^2
⇒e
̄hc
(f 1 −f 2 ) = 2nπ⇒ Φ =f 1 −f 2 =2 nπ ̄hc
eThe flux is quantized.
Magnetic flux is observed to be quantized in a region enclosed by a superconductor. however, the
fundamental charge seen is 2e.
20.6 Homework Problems
- Show that the HamiltonianH= 21 μ[~p+ecA~(~r,t)]^2 −eφ(~r,t) yields the Lorentz force law for an
electron. Note that the fields must be evaluated at the position of the electron. This means
that the total time derivative ofA~must also account for the motion of the electron. - Calculate the wavelengths of the three Zeeman lines in the 3d→ 2 ptransition in Hydrogen
atoms in a 10^4 gauss field. - Show that the probability flux for system described by the Hamiltonian
H=
1
2 μ[~p+e
c