Ichiro Ueno scite author profile

Thermocapillary-driven convection in a half-zone liquid bridge was investigated experimentally. The induced flows were categorized into several regimes mainly through the pattern of the suspended particle motion in the bridge and the surface temperature variation. Special attention was paid to the flow structures far beyond the critical condition. Chaotic and turbulent flows were realized in this configuration. They were distinguished from the periodic oscillatory flow by applying the pseudo-phase-space reconstruction from the time series of the surface temperature variation.

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Transition process leading to microbubble emission boiling on horizontal circular heated surface in subcooled pool

Ando

Horiuchi

Saiki

et al. 2016

International Journal of Heat and Mass Transfer

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Flow structure and dynamic particle accumulation in thermocapillary convection in a liquid bridge

Tanaka

Kawamura

Ueno

et al. 2006

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Thermocapillary convection is induced in a liquid bridge by a nonuniform surface tension distribution caused by an axial temperature difference. A toroidal vortex is formed by the thermocapillary force over the free surface. The induced flow is visualized by using fine particles as tracers. At a sufficiently high Marangoni number, three-dimensional standing and traveling oscillatory flows appear, and under certain flow conditions, the tracer particles form particle accumulation structures ͑PAS͒. In the present study, the conditions for the occurrence of PAS have been carefully investigated with focus on the spiral loop PAS ͑SL-PAS͒ that appears when the flow exhibits a traveling mode. The particles gather along a closed spiral loop that winds itself around the toroidal vortex. Observed from above, the spiral loop looks as if it is rotating azimuthally. The number of spirals corresponds with the azimuthal wave number of the traveling wave and each spiral consists of either single or double turns. The azimuthal traveling direction of the particles trapped on the SL-PAS is opposite to that of the SL-PAS pattern and of the hydrothermal wave under the presently focused conditions. By varying particle diameter and density within a certain range, it was revealed that the SL-PAS appears almost independently of the particle properties. The path line of each particle trapped in the SL-PAS is different from the shape of the SL-PAS itself. The Stokes number of a particle is examined and found to be much smaller than unity. Furthermore, a structure similar to the SL-PAS was also visualized by injecting colored dye. Thus, the shape of the SL-PAS is primarily determined not by the particle-particle interaction but by the flow field itself.

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Limit cycles for the motion of finite-size particles in axisymmetric thermocapillary flows in liquid bridges

Romanò

Kuhlmann

Ishimura

et al. 2017

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The motion of a small spherical particle of finite size in an axisymmetric thermocapillary liquid bridge is investigated numerically and experimentally. Due to the crowding of streamlines towards the free surface and the recirculating nature of the flow, advected particles visit the free surface repeatedly. The balance between centrifugal inertia and the strong short-range repulsive forces a particle experiences near the free surface leads to an attracting limit cycle for the particle motion. The existence of this limit cycle is established experimentally. It is shown that limit cycles obtained numerically by one-way-coupled simulations based on the Maxey–Riley equation and a particle–surface interaction model compare favorably with the experimental results if the thickness of the lubrication gap between the free surface and the surface of the particle is properly taken into account.

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Effect of ambient fluid flow upon onset of oscillatory thermocapillary convection in half-zone liquid bridge

Irikura

Arakawa

Ueno

et al. 2005

Microgravity sci. Technol.

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Ichiro Ueno

Oscillatory and chaotic thermocapillary convection in a half-zone liquid bridge

Transition process leading to microbubble emission boiling on horizontal circular heated surface in subcooled pool

Flow structure and dynamic particle accumulation in thermocapillary convection in a liquid bridge

Limit cycles for the motion of finite-size particles in axisymmetric thermocapillary flows in liquid bridges

Effect of ambient fluid flow upon onset of oscillatory thermocapillary convection in half-zone liquid bridge

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