18.4 Anℓ= 1 System in a Magnetic Field*
We will derive the Hamiltonian terms added when an atom is put in a magnetic field in section 20.
For now, we can be satisfied with the classical explanation that the circulating current associated
with nonzero angular momentum generates amagnetic moment,as does a classical current loop.
This magnetic moment has the same interaction as in classical EM,
H=−~μ·B.~For theorbital angular momentumin a normal atom, the magnetic moment is
~μ=−e
2 mc~L.
For the electron mass, in normal atoms, the magnitude of~μis oneBohr magneton,
μB=e ̄h
2 mecIf we choose the direction ofBto be thezdirection, then themagnetic moment term in the
Hamiltonianbecomes
H=μBB
̄hLz=μBB
1 0 0
0 0 0
0 0 − 1
.
So the eigenstates of this magnetic interaction are the eigenstates ofLzand theenergy eigenvalues
are +μBB, 0, and−μBB.
- See Example 18.10.6:The energy eigenstates of anℓ= 1 system in a B-field.*
- See Example 18.10.8:Time development of a state in a B field.*
18.5 Splitting the Eigenstates with Stern-Gerlach
A beam of atoms can be split into the eigenstates ofLzwith aStern-Gerlach apparatus. A
magnetic moment is associated with angular momentum.
~μ=
−e
2 mc~L=μB~L
̄hThis magnetic moment interacts with an external field, adding a termto the Hamiltonian.
H=−~μ·B~If the magnetic field has a gradient in the z direction, there is a forceexerted (classically).
F=−
∂U
∂z=μz∂B
∂zA magnet with astrong gradient to the fieldis shown below.