Rotational diffusion: Difference between revisions

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'''Rotational diffusion''' is a process by which the equilibrium statistical distribution of the overall orientation of particles or molecules is maintained or restored. Rotational diffusion is the counterpart of translational diffusion, which maintains or restores the equilibrium statistical distribution of particles' position in space.
'''Rotational diffusion''' is a process by which the equilibrium statistical distribution of the overall orientation of particles or molecules is maintained or restored. Rotational diffusion is the counterpart of translational [[diffusion]], which maintains or restores the equilibrium statistical distribution of particles' position in space.


If a molecule has an orientation along a unit vector '''n''', and ''f(θ, φ, t)'' represents the probability density distribution for the orientation of '''n''' at time ''t'' (with the usual
If a molecule has an orientation along a unit vector '''n''', and ''f(θ, φ, t)'' represents the probability density distribution for the orientation of '''n''' at time ''t'' (with the usual
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==See also==
==See also==


*[[diffusion]]
*[[Diffusion]]
*[[rotational relaxation]]
*[[Rotational relaxation]]
*[http://en.wikipedia.org/wiki/Rotational_diffusion Rotational diffusion at wikipedia]
*[http://en.wikipedia.org/wiki/Rotational_diffusion Rotational diffusion at wikipedia]


[[Category: Non-equilibrium thermodynamics]]
[[Category: Non-equilibrium thermodynamics]]

Latest revision as of 14:42, 27 June 2008

Rotational diffusion is a process by which the equilibrium statistical distribution of the overall orientation of particles or molecules is maintained or restored. Rotational diffusion is the counterpart of translational diffusion, which maintains or restores the equilibrium statistical distribution of particles' position in space.

If a molecule has an orientation along a unit vector n, and f(θ, φ, t) represents the probability density distribution for the orientation of n at time t (with the usual meaning of the θ and φ angles in spherical coordinates). The rotational diffusion equation is:

with the rotational diffusion coefficient , which has units of inverse time.

This partial differential equation may be solved by expanding f(θ, φ, t) in spherical harmonics, for which the mathematical identity holds:

Thus, the solution of this partial differential equation may be written

where Clm are constants determined by the initial distribution. The most relevant result is the one for relaxation times:

See also[edit]