28 Kinetic propertiesTherefore, combining equations (2.10) and (2.11),x = (20^ (2.4)Diffusion equation (2.5)The work done in moving a particle through a distance dx against a
frictional resistance to motion f(dx/dt) can be equated with the
resulting change in chemical potential given by the expressiondp = kT d In c
dx_
dtTherefore,dx _ kT dine _ kT dc
— --— - -—— (2.12)
dr / dx fc dx ^Since™_ nuvKVdm:,-:m, ™' , £\ /"* M,_Trrnmm dx
dt dt
then combining this expression with equation (2.8) givesc =D (2.13)
dr dx
Therefore, combining equations (2.12) and (2.13),For a system containing spherical particles, D = RT/6injaNA - i.e.
D oc l/ml/!, where m is the particle mass. For systems containing
asymmetric particles, D is correspondingly smaller (see Table 2.3).
Since D = k77/, the ratio D/D(} (where D is the experimental
diffusion coefficient and D 0 is the diffusion coefficient of a system
containing the equivalent unsolvated spheres) is equal to the