Thermophoretic motion of slightly deformed aerosol spheres

“…43 The asymptotic formula for the thermophoretic velocity of a spheroidal particle correct to the second order in the small parameter characterizing the deformation, =1−͑a / b͒, was obtained in a closed form. The values of the normalized thermophoretic mobility U / U 0 of a prolate spheroid ͑with Ͻ0͒ perpendicular to its axis of revolution calculated from this approximate formula are also listed in Table II for comparison.…”

“…4͑b͔͒. Because the effects of the four parameters k ‫ء‬ , C t ‫ء‬ , C m ‫ء‬ , and a / b on the thermophoretic velocity of a spheroid interact one another in a quite complicated manner, 43 it would be difficult to provide detailed physical analysis for the above observations from Figs. 2-4.…”

“…Recently, the thermophoresis of a slightly deformed sphere with the effects of temperature jump, thermal slip, and frictional slip at its surfaces was investigated, and an explicit expression for the thermophoretic velocity was obtained to the second order in the small parameter characterizing the deformation. 42,43 The thermophoretic motions of a general axisymmetric particle 44 and a prolate or oblate spheroid 45 with the effects of temperature jump, thermal slip, and frictional slip along their axes of revolution were also examined analytically and numerically to some extent by using the methods of internal singularity distributions, separation or semiseparation of variables in spheroidal coordinates, and boundary collocations. However, the problem of thermophoresis of a general particle of revolution with the jump/slip conditions at its surface in an arbitrary direction has not been analytically or numerically solved yet, mainly due to the fact that, if the temperature jump and/or frictional slip is included, a separable solution of the temperature and/or fluid velocity fields is not feasible for most orthogonal curvilinear coordinate systems, such as the prolate and oblate spheroidal ones.…”

“…15,40 For the cases of a spheroid in general conditions whose shape deviates slightly from that of a sphere, our results also agree quite well with the approximate analytical solution in the literature. 43 Because the governing equations and boundary conditions concerning the general problem of thermophoretic motion of a particle of revolution with fore-and-aft symmetry caused by a prescribed moderate temperature gradient in an arbitrary direction are linear, its solution can be obtained as a superposition of the solutions for its two subproblems: motion along the axis of revolution of the particle, which was previously examined, 44,45 and motion normal to the axis, which is treated in this work.…”

Thermophoresis of axially and fore-and-aft symmetric aerosol particles

“…43 The asymptotic formula for the thermophoretic velocity of a spheroidal particle correct to the second order in the small parameter characterizing the deformation, =1−͑a / b͒, was obtained in a closed form. The values of the normalized thermophoretic mobility U / U 0 of a prolate spheroid ͑with Ͻ0͒ perpendicular to its axis of revolution calculated from this approximate formula are also listed in Table II for comparison.…”

“…4͑b͔͒. Because the effects of the four parameters k ‫ء‬ , C t ‫ء‬ , C m ‫ء‬ , and a / b on the thermophoretic velocity of a spheroid interact one another in a quite complicated manner, 43 it would be difficult to provide detailed physical analysis for the above observations from Figs. 2-4.…”

“…Recently, the thermophoresis of a slightly deformed sphere with the effects of temperature jump, thermal slip, and frictional slip at its surfaces was investigated, and an explicit expression for the thermophoretic velocity was obtained to the second order in the small parameter characterizing the deformation. 42,43 The thermophoretic motions of a general axisymmetric particle 44 and a prolate or oblate spheroid 45 with the effects of temperature jump, thermal slip, and frictional slip along their axes of revolution were also examined analytically and numerically to some extent by using the methods of internal singularity distributions, separation or semiseparation of variables in spheroidal coordinates, and boundary collocations. However, the problem of thermophoresis of a general particle of revolution with the jump/slip conditions at its surface in an arbitrary direction has not been analytically or numerically solved yet, mainly due to the fact that, if the temperature jump and/or frictional slip is included, a separable solution of the temperature and/or fluid velocity fields is not feasible for most orthogonal curvilinear coordinate systems, such as the prolate and oblate spheroidal ones.…”

“…15,40 For the cases of a spheroid in general conditions whose shape deviates slightly from that of a sphere, our results also agree quite well with the approximate analytical solution in the literature. 43 Because the governing equations and boundary conditions concerning the general problem of thermophoretic motion of a particle of revolution with fore-and-aft symmetry caused by a prescribed moderate temperature gradient in an arbitrary direction are linear, its solution can be obtained as a superposition of the solutions for its two subproblems: motion along the axis of revolution of the particle, which was previously examined, 44,45 and motion normal to the axis, which is treated in this work.…”

Thermophoresis of axially and fore-and-aft symmetric aerosol particles

“…This analysis has been generalized to the motion of a spheroid with an arbitrary orientation relative to the imposed thermal gradient (Keh and Ou, 2004). Recently, the thermophoresis of an isolated particle which departs slightly in shape from a sphere with the effects of temperature jump, thermal slip and frictional slip was examined, and an explicit expression for the thermophoretic velocity was obtained to the second order in the small parameter characterizing the deformation (Chang and Keh, 2010). However, the boundary effect on thermophoresis of particles of a nonspherical shape has not been investigated yet.…”

Boundary effects on thermophoresis of aerosol cylinders

Analytical study on accelerating falling of non-spherical particle in viscous fluid