8.3 Solutions 453
8.15 (a) The electrical quadrupole moment is the expectation value of the operator
Qij=∑zk= 1ek(3xixj−δijr^2 )k (1)whereδijis the kronecker delta.
TheQzz– component,Qzz=∑zk= 1ek(3z^2 k−rk^2 )(2)is zero for a spherically charge distribution. This feature also becomes obvi-
ous from the formulaQ=2
5
ze(a^2 −b^2 ) for a homogenous ellipsoid of semi axesa,b
(Problem 8.54).For a spherea=band thereforeQ=0.
(b) The quadrupole moment which is a tensor has the property that it is sym-
metric, that isQij=Qjiand that its trace (the sum of the diagonal ele-
ments),Qxx+Qyy+Qzz =0. Using these two proiperties,Qijcan be
expressed in terms of the spin vectorIwhich specifies the quantized state
of the nucleus.Qij=C(
IiIj+IjIi−2
3
I^2 δij)
(3)
whereCis a constant. SubstitutingI^2 =I(I+1) in (3)Q=
2
3
CI(2I−1) (4)
which is zero forI=0orI= 1 / 28.16 From the results of Problem 8.15
Q=^25(
a^2 −b^2)
Z
We can writeQ=
4
5
Z
(
a+b
2)
(a−b)CallingR=(
a+b
2)
andΔR=a−b, we getQ=4
5
ZRΔR
Q= 4 .2 barn= 4. 2 × 10 −^24 cm^2 =420 fm^2=2
5
×71(a^2 −b^2 )