Author:
SIEROU ASIMINA,BRADY JOHN F.
Abstract
A new implementation of the conventional Stokesian Dynamics (SD) algorithm,
called accelerated Stokesian Dynamics (ASD), is presented. The equations governing
the motion of N particles suspended in a viscous fluid at low particle Reynolds
number are solved accurately and efficiently, including all hydrodynamic interactions,
but with a significantly lower computational cost of O(N ln N). The main differences
from the conventional SD method lie in the calculation of the many-body
long-range interactions, where the Ewald-summed wave-space contribution is calculated
as a Fourier transform sum and in the iterative inversion of the now sparse resistance
matrix. The new method is applied to problems in the rheology of both structured and
random suspensions, and accurate results are obtained with much larger numbers
of particles. With access to larger N, the high-frequency dynamic viscosities and
short-time self-diffusivities of random suspensions for volume fractions above the
freezing point are now studied. The ASD method opens up an entire new class of
suspension problems that can be investigated, including particles of non-spherical
shape and a distribution of sizes, and the method can readily be extended to other
low-Reynolds-number-flow problems.
Publisher
Cambridge University Press (CUP)
Subject
Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics
Cited by
402 articles.
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