Thermocapillary mobility of bubbles and electrophoretic motion of particles in a fluid

## Abstract The size and surface chemistry of micron scale particles are of fundamental importance in studies of biology and air particulate pollution. However, typical electrophoretic measurements of these and other sub‐micron scale particles (300 nm–1 μm) cannot resolve size information within he

## Sumrnary Linear equations have been derived for the motion of a fluid with suspended impurities. The nature of the impurities is characterised by a ¢ontinuous parameter which varies over a finite interval. It is proved that, under certain assumptions, the velocity fields can be described by a f

Linear equations have been derived which approximately describe the motion of a m i x t u r e consisting of N components. In eaeh point of the domain of flow N velocity vectors, one for each component, have been assumed. It is shown t h a t these velocity fields can be described by N potential funct

ARTICLE NO. CS975220 NOTE Electrophoretic Mobility of a Spherical Particle in a Spherical Cavity where Ç 2 is the Laplace operator, r the space charge density, e the permittivity of the liquid phase, N the number of ionic species, z j and The electrophoretic mobility U of a spherical particle in a n