Nuclear Structure 407
The last correction term arises from the tendency of proton pairs and neutron pairs
to occur (Sec. 11.3). Even-even nuclei are the most stable and hence have higher bind-
ing energies than would otherwise be expected. Thus such nuclei as^42 He,^126 C, and^168 O
appear as peaks on the empirical curve of binding energy per nucleon. At the other
extreme, odd-odd nuclei have both unpaired protons and neutrons and have relatively
low binding energies. The pairing energyEpis positive for even-even nuclei, 0 for
odd-even and even-odd nuclei, and negative for odd-odd nuclei, and seems to vary
with Aas A^3 ^4. HencePairing energy Ep(, 0) (11.17)The final expression for the binding energy of a nucleus of atomic number Zand
mass number A, which was first obtained by C. F. von Weizsäcker in 1935, isEba 1 Aa 2 A^2 ^3 a 3 a 4 (, 0) (11.18)A set of coefficients that gives a good fit with the data is as follows:a 1 14.1 MeV a 2 13.0 MeV a 3 0.595 MeV
a 4 19.0 MeV a 5 33.5 MeVOther sets of coefficients have also been proposed. Equation (11.18) agrees better
with observed binding energies than does Eq. (11.13), which suggests that the
liquid-drop model, though a good approximation, is not the last word on the
subject.Example 11.6
The atomic mass of the zinc isotope^6430 Zn is 63.929 u. Compare its binding energy with the
prediction of Eq. (11.18).
Solution
The binding energy of^6430 Zn is, from Eq. (11.7),Eb[(30)(1.007825 u)(34)(1.008665 u)63.929 u](931.49 MeV/u)559.1 MeV
The semiempirical binding energy formula, using the coefficients in the text, givesEb(14.1 MeV)(64)(13.0 MeV)(64)^2 ^3 561.7 MeVThe plus sign is used for the last term because^6430 Zn is an even-even nucleus. The difference
between the observed and calculated binding energies is less than 0.5 percent.33.5 MeV
(64)^3 ^4(19.0 MeV)(16)
64(0.595 MeV)(30)(29)
(64)^1 ^3a 5
A^3 ^4(A 2 Z)^2
AZ(Z 1 )
A^1 ^3a 5
A^3 ^4Semiempirical
binding-energy
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