1008 24 Magnetic Resonance Spectroscopy
Exercise 24.4
Find the frequency and wavelength of photons with energy equal to the energy difference in
Example 24.7.
Nuclear Magnetic Dipoles
Like the electron, the proton does not obey nonrelativistic mechanics. The proton’s
magnetic dipole operator is
̂μgp
e
2 mp
̂I (24.2-7)
wherêIis the spin angular momentum operator of the proton, andmpis the mass of
the proton. The factorgpis analogous to the anomalousgfactor of the electron, and is
called thenucleargfactorof the proton. Its value to six significant digits is 5.58569.
The proton has the same spin angular momentum properties as the electron, with a
spin quantum numberIequal to 1/2. The magnitude of the spin angular momentum
of a proton is
|I|h ̄
√
I(I+1)h ̄
√
1
2
(
1
2
+ 1
)
h ̄
√
3
4
(24.2-8)
Thezcomponent of the spin angular momentum is
IzMIh ̄±
1
2
h ̄ (24.2-9)
whereMIis the quantum number for thezcomponent ofI. The magnitude of the
magnetic dipoleμfor a proton is
|μ|μgp
e
2 mp
h ̄
√
1
2
(
1
2
+ 1
)
√
3
4
gpβN 2. 44324 × 10 −^26 JT−^1 (24.2-10)
and itszcomponent is
μz±
1
2
gpβN± 1. 41061 × 10 −^6 JT−^1 (24.2-11)
The constantβNis analogous to the Bohr magneton and is called thenuclear magneton:
βN
eh ̄
2 mp
5. 050787 × 10 −^27 JT−^1 (24.2-12)
In some tabulations (such as CODATA 63) the value given for the magnetic moment
of the proton is the magnitude of thezcomponent, equal to 1. 41061 × 10 −^26 JT−^1.
EXAMPLE24.8
Find the difference in the energies of the two spin states of a proton in a magnetic field of
0.500 T. Compare with the result of Example 24.7 for the electron.