Appendix: Exercises... 417
Furthermore, determine the anisotropy ratio R=(D‖−D⊥)/(D‖+ 2 D⊥),
the average diffusion coefficientD ̄ =^13 D‖+^23 D⊥and the geometric meanD ̃=
D
1 / 3
‖ D
2 / 3
⊥ .Discuss the cases Q>^1 and Q<^1 for prolate and oblate particles.
The fluxjtransforms like the position vector, viz. jμ = A−μν^1 /^2 jνA. The spatial
gradient in real space is linked with the nabla operator in affine space according
to∇ν=A^1 νκ/^2 ∇Aκ.
From the diffusion law in the affine space,jλA=−DAλκ∇νAρ, whereDAλκis the
diffusion tensor in that space, follows
jμ=A−μλ^1 /^2 jλA=−A−μλ^1 /^2 DAλκ∇Aνρ=−A−μλ^1 /^2 DλκAA−κν^1 /^2 ∇νρ.
Comparison with the diffusion law in real space andDλκA=D 0 δλκimplies
Dμν=A
− 1 / 2
μλ D
A
λκA
− 1 / 2
κν =A
− 1
μνD^0.
For uniaxial particles with their symmetry axis parallel to the director, one has
A−μν^1 =Q−^2 /^3
[
δμν+(Q^2 − 1 )nμnν
]
,
cf. (5.58). HereQ=a/bis the axes ratio of an ellipsoid with the semi-axesaand
b=c. Thus the above mentioned resultD‖=Q^4 /^3 D 0 ,D⊥=Q−^2 /^3 D 0 is obtained.
This implies
R=(D‖−D⊥)/(D‖+ 2 D⊥)=(Q^2 − 1 )/(Q^2 + 2 ),
and
D ̄=^1
3
D‖+
2
3
D⊥=
1
3
Q−^2 /^3 (Q^2 + 2 )D 0 ,
for the ansotropy ratioRand for the average diffusion coefficientD ̄. The geometric
mean diffusion coefficientD ̃=D‖^1 /^3 D⊥^2 /^3 =D 0 is independent of the axes ratioQ.
As expected intuitively, prolate particles withQ>1 diffuse faster in the direction
parallel ton, sinceD‖>D⊥, in this case. For prolate particles, pertaining toQ<1,
one hasD‖<D⊥. There the diffusion alongnis slower compared with the diffusion
in a direction perpendicular ton. The anisotropy ratioRis positive for prolate and
negative for oblate particles.