Structure and dynamics of particle-accumulation in thermocapillary liquid bridges

• Published in: Fluid dynamics research Vol. 46; no. 4; pp. 1 - 22
• Main Authors: Kuhlmann, Hendrik C, Mukin, Roman V, Sano, Tomoaki, Ueno, Ichiro
• Format: Journal Article
• Language: English
• Published: IOP Publishing 01.08.2014
• Subjects: Computational fluid dynamics; core of particles; depletion zone; Dynamics; Estimates; Fluid flow; Incompressible flow; Inertia; Liquid bridges; Liquids; particle accumulation; pAS; thermocapillary liquid bridge
• ISSN: 0169-5983; 1873-7005
• DOI: 10.1088/0169-5983/46/4/041421

The accumulation of small mono-disperse heavy particles in thermocapillary liquid bridges is investigated experimentally and numerically. We consider particle accumulation near the center of the toroidal vortex, the so-called toroidal core of particles (COP), and the particle-depletion zone near the axis of the liquid bridge. Based on the acceleration and deceleration of the tangential flow along the thermocapillary free surface it is argued that the interaction of the particles with the free surface is of key importance for the fast particle accumulation within a few characteristic momentum diffusion times. The experimentally determined particle-accumulation times are compared with time-scale estimates for accumulation due to either particle free-surface interaction or due to inertia of particles which are heavier than the liquid. We show that the experimental accumulation times are compatible with the accumulation times predicted by the particle-free-surface interaction (PSI) while the time-scale estimates based on the inertia of the particles are too large to explain the fast de-mixing observed in experiments. The shape of the COP resembles certain KAM tori of the incompressible flow of a hydrothermal wave. Two scenarios are proposed to explain the structure and the dynamics of the COP depending on the existence or non-existence of suitable KAM structures. The shape of the experimental particle-depletion zone agrees well with the release surface which is defined by the particle-free-surface interaction process. The favorable comparison of the dynamics and structure of experimental and numerical accumulation patterns provides strong evidence for the existence and relevance of the PSI as the most rapid physical accumulation mechanism.