184 5.4  NMR and Other Radio Frequency and Microwave Resonance Spectroscopies

Typical values of γ are equivalent to ~10⁷ T⁻¹ s⁻¹ but are often quoted as these values divided

by 2π and are given for a few atomic nuclei in Table 5.2. The bulk magnetization M of a

sample is the sum of all the atomic nuclear magnetic moments, which average out to zero in

the absence of an external magnetic field.

However, in the presence of an external magnetic field, there is a nonzero net magnet­

ization, and each atomic nuclear magnetic state will also have a different energy E due to

the coupling interaction between the B-​field and the magnetic moment (also known as the

Zeeman interaction), which is given by the dot product of the external magnetic field B with

the atomic nucleus magnetic moment:

(5.17)

E

B

B

B hm

m

z

z

z

= −⋅

= −

= −

^

µ

µ

γ

π

2

Therefore, the presence of an external magnetic field splits the energy into (2I +​ 1) discrete

energy levels (Zeeman levels), a process known as Zeeman splitting, with the lower energy

levels resulting from the alignment of atomic nuclear magnetic moment with the external

B-​field and higher energies with alignment against the B-​field. The transition energy between

each level is given by

(5.18)

∆E

B h

z

= −^γ

π

2

If a photon of electromagnetic energy hv matches ΔE, it can be absorbed to excite a nuclear

magnetic energy level transition from a lower to a higher state; similarly, a higher energy state

can drop to a lower level with consequent photon emission, with quantum selection rules

permitting Δm =​ ±1, which indicates 2I possible reversible transitions. An absorbed photon

of frequency ν can thus result in a resonance between the different spin energy states. This

resonance frequency is also known as the Larmor frequency and is identical to the classically

calculated frequency of precession of an atomic nucleus magnetic moment around the axis

of the external B-​field vector.

The value of ν depends on γ and on B (in most research laboratories, B is in the range of

~1–​24 T, ~10⁶ times the strength of Earth’s magnetic field), but is typically ~10⁸ Hz, and it is

common to compare the resonance frequencies of different atomic nuclei under standard ref­

erence conditions in relation to a B-​field, which would generate a resonance frequency of 400

MHz for ¹H (B ~ 9.4 T), some examples of which are shown in Table 5.1. For magnetic atomic

nuclei, these are radio frequencies. For example, the resonance frequency of ¹³C is very close

to that of a common FM transmission frequency of ~94 MHz for New York Public Radio.

A typical value of ΔE, for example, for ¹H in a “400 MHz NMR machine” (i.e., B ~ 9.4 T) is ~3

× 10⁻²⁵ J. Experiments in such machines are often performed at ~4 K, and so kBT/​ΔE ~ 180,

hence, still a significant proportion of occupied lower energy states at thermal equilibrium.

The occupational probability pm of the mth state (see Worked Case Example 5.2) is given

by the normalized Boltzmann probability of

(5.19)

p

E

k T

E

k T

B hm

k T

m

m

B

all m

m

g

z

B

all

=

−





−





=





∑

exp

/

exp

/

exp

/

γ

π

2

m

z

B

B hm

k T

∑





exp

/

γ

π

2

The relative occupancy N of the different energy levels can be predicted from the Boltzmann

distribution:

(5.20)

N

N

E

k T

Bh

k T

m

m I

B

B

=

= +

=

−











⁼

−













1

1

2

exp

exp

∆

γ

π