Potassium persulfate

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In hydrodynamics, the Perrin friction factors are multiplicative adjustments to the translational and rotational friction of a rigid spheroid, relative to the corresponding frictions in spheres of the same volume. These friction factors were first calculated by Jean-Baptiste Perrin.

These factors pertain to spheroids (i.e., to ellipsoids of revolution), which are characterized by the axial ratio p = (a/b), defined here as the axial semiaxis a (i.e., the semiaxis along the axis of revolution) divided by the equatorial semiaxis b. In prolate spheroids, the axial ratio p > 1 since the axial semiaxis is longer than the equatorial semiaxes. Conversely, in oblate spheroids, the axial ratio p < 1 since the axial semiaxis is shorter than the equatorial semiaxes. Finally, in spheres, the axial ratio p = 1, since all three semiaxes are equal in length.

The formulae presented below assume "stick" (not "slip") boundary conditions, i.e., it is assumed that the velocity of the fluid is zero at the surface of the spheroid.

Perrin S factor

For brevity in the equations below, we define the Perrin S factor. For prolate spheroids (i.e., cigar-shaped spheroids with two short axes and one long axis)

S=def2atanhξξ

where the parameter ξ is defined

ξ=def|p21|p

Similarly, for oblate spheroids (i.e., discus-shaped spheroids with two long axes and one short axis)

S=def2atanξξ

For spheres, S=2, as may be shown by taking the limit p1 for the prolate or oblate spheroids.

Translational friction factor

The frictional coefficient of an arbitrary spheroid of volume V equals

ftot=fspherefP

where fsphere is the translational friction coefficient of a sphere of equivalent volume (Stokes' law)

fsphere=6πηReff=6πη(3V4π)(1/3)

and fP is the Perrin translational friction factor

fP=def2p2/3S

The frictional coefficient is related to the diffusion constant D by the Einstein relation

D=kBTftot

Hence, ftot can be measured directly using analytical ultracentrifugation, or indirectly using various methods to determine the diffusion constant (e.g., NMR and dynamic light scattering).

Rotation friction factor

There are two rotational friction factors for a general spheroid, one for a rotation about the axial semiaxis (denoted Fax) and other for a rotation about one of the equatorial semiaxes (denoted Feq). Perrin showed that

Fax=def(43)ξ22(S/p2)
Feq=def(43)(1/p)2p22S[2(1/p)2]

for both prolate and oblate spheroids. For spheres, Fax=Feq=1, as may be seen by taking the limit p1.

These formulae may be numerically unstable when p1, since the numerator and denominator both go to zero into the p1 limit. In such cases, it may be better to expand in a series, e.g.,

1Fax=1.0+(45)(ξ21+ξ2)+(4657)(ξ21+ξ2)2+(468579)(ξ21+ξ2)3+

for oblate spheroids.

Time constants for rotational relaxation

The rotational friction factors are rarely observed directly. Rather, one measures the exponential rotational relaxation(s) in response to an orienting force (such as flow, applied electric field, etc.). The time constant for relaxation of the axial direction vector is

τax=(1kBT)Feq2

whereas that for the equatorial direction vectors is

τeq=(1kBT)FaxFeqFax+Feq

These time constants can differ significantly when the axial ratio ρ deviates significantly from 1, especially for prolate spheroids. Experimental methods for measuring these time constants include fluorescence anisotropy, NMR, flow birefringence and dielectric spectroscopy.

It may seem paradoxical that τax involves Feq. This arises because re-orientations of the axial direction vector occur through rotations about the perpendicular axes, i.e., about the equatorial axes. Similar reasoning pertains to τeq.

References

  • Cantor CR and Schimmel PR. (1980) Biophysical Chemistry. Part II. Techniques for the study of biological structure and function, W. H. Freeman, p. 561-562.
  • Koenig SH. (1975) "Brownian Motion of an Ellipsoid. A Correction to Perrin's Results." Biopolymers 14: 2421-2423.