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Microparticle manipulation using laser-induced thermophoresis and thermal convection flow

Qian Yang, Steven L. Neale, J.H. Marsh

2020Scientific Reports36 citationsDOIOpen Access PDF

Abstract

Abstract We demonstrate manipulation of microbeads with diameters from 1.5 to 10 µm and Jurkat cells within a thin fluidic device using the combined effect of thermophoresis and thermal convection. The heat flow is induced by localized absorption of laser light by a cluster of single walled carbon nanotubes, with no requirement for a treated substrate. Characterization of the system shows the speed of particle motion increases with optical power absorption and is also affected by particle size and corresponding particle suspension height within the fluid. Further analysis shows that the thermophoretic mobility ( D T ) is thermophobic in sign and increases linearly with particle diameter, reaching a value of 8 µm 2 s −1 K −1 for a 10 µm polystyrene bead.

Topics & Concepts

ThermophoresisParticle (ecology)Materials sciencePolystyreneOpacityAbsorption (acoustics)ThermalConvectionLaserMicroparticleNanotechnologyMechanicsOpticsThermodynamicsNanoparticlePolymerComposite materialNanofluidPhysicsGeologyOceanographyField-Flow Fractionation TechniquesParticle Dynamics in Fluid FlowsAdvanced Thermodynamics and Statistical Mechanics
Microparticle manipulation using laser-induced thermophoresis and thermal convection flow | Litcius