Brownian motion ferrofluids

The appendices contain an account of those parts of the theory of Brownian motion and linear response theory which are essential for the reader in order to achieve an understanding of relaxational phenomena in magnetic domains and in ferrofluid particles. The analogy with dielectric relaxation is emphasized throughout these appendices. Appendix D contains the rigorous derivation of Brown s equation. 

We have mentioned that the question posed above was answered in part by Shliomis and Stepanov [9]. They showed that for uniaxial particles, for weak applied magnetic fields, and in the noninertial limit, the equations of motion of the ferrofluid particle incorporating both the internal and the Brownian relaxation processes decouple from each other. Thus the reciprocal of the greatest relaxation time is the sum of the reciprocals of the Neel and Brownian relaxation times of both processes considered independently that is, those of a frozen Neel and a frozen Brownian mechanism In this instance the joint probability of the orientations of the magnetic moment and the particle in the fluid (i.e., the crystallographic axes) is the product of the individual probability distributions of the orientations of the axes and the particle so that the underlying Fokker Planck equation for the joint probability distribution also... 

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