Micromixing using a conductive liquid-based focused surface acoustic wave (CL-FSAW)

•Using the concentrated acoustic force of a conductive liquid-based focused surface acoustic wave (CL-FSAW) device, rapid and efficient mixing can be achieved.•In the CL-FSAW mixer, high efficiency mixing performance can be achieved (efficiency ∼97%) at a flow rate of Q≤80μLmin−1 with an applied vol...

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Veröffentlicht in:	Sensors and actuators. B, Chemical Chemical, 2018-04, Vol.258, p.991-997
Hauptverfasser:	Nam, Jeonghun, Jang, Woong Sik, Lim, Chae Seung
Format:	Artikel
Sprache:	eng
Schlagworte:	Conductive liquid Deionization Electric potential Flow velocity Fluid dynamics Fluid flow Fluorescence Focused surface acoustic wave Microchannels Microfluidics Micromixing Nanoparticles Power consumption Reynolds number Sensors Surface acoustic waves
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creator	Nam, Jeonghun Jang, Woong Sik Lim, Chae Seung
description	•Using the concentrated acoustic force of a conductive liquid-based focused surface acoustic wave (CL-FSAW) device, rapid and efficient mixing can be achieved.•In the CL-FSAW mixer, high efficiency mixing performance can be achieved (efficiency ∼97%) at a flow rate of Q≤80μLmin−1 with an applied voltage of 21V.•For further application, CL-FSAW mixer device was applied to continuous synthesis of monodispersed silver nanoparticles at Q=100μLmin−1 and V=21V. Acoustic manipulation of fluids and particles has gained much attention in microfluidics, owing to its advantages of non-invasive manipulation and low power consumption. Microchannel mixing has been limited to diffusion-based mixing, because of low Reynolds number that has a low mixing efficiency. In this study, we firstly introduce a conductive liquid-based focused surface acoustic wave (CL-FSAW) device for mixing. Using the concentrated acoustic force of CL-FSAW, rapid and efficient mixing of deionized water and fluorescent particle suspension was demonstrated in a microfluidic channel. Effects of the applied voltage and the flow rate on the mixing efficiencies were investigated. As the flow rate decreased or the applied voltage increased, the mixing efficiency increased. At 21V, mixing efficiencies were higher than 90% at a flow rate lower than 120μLmin−1. In addition, our device was applied to silver nanoparticle synthesis at the optimal mixing condition (100μLmin−1 and 21V).
doi_str_mv	10.1016/j.snb.2017.11.188
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Acoustic manipulation of fluids and particles has gained much attention in microfluidics, owing to its advantages of non-invasive manipulation and low power consumption. Microchannel mixing has been limited to diffusion-based mixing, because of low Reynolds number that has a low mixing efficiency. In this study, we firstly introduce a conductive liquid-based focused surface acoustic wave (CL-FSAW) device for mixing. Using the concentrated acoustic force of CL-FSAW, rapid and efficient mixing of deionized water and fluorescent particle suspension was demonstrated in a microfluidic channel. Effects of the applied voltage and the flow rate on the mixing efficiencies were investigated. As the flow rate decreased or the applied voltage increased, the mixing efficiency increased. At 21V, mixing efficiencies were higher than 90% at a flow rate lower than 120μLmin−1. 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B, Chemical</title><description>•Using the concentrated acoustic force of a conductive liquid-based focused surface acoustic wave (CL-FSAW) device, rapid and efficient mixing can be achieved.•In the CL-FSAW mixer, high efficiency mixing performance can be achieved (efficiency ∼97%) at a flow rate of Q≤80μLmin−1 with an applied voltage of 21V.•For further application, CL-FSAW mixer device was applied to continuous synthesis of monodispersed silver nanoparticles at Q=100μLmin−1 and V=21V. Acoustic manipulation of fluids and particles has gained much attention in microfluidics, owing to its advantages of non-invasive manipulation and low power consumption. Microchannel mixing has been limited to diffusion-based mixing, because of low Reynolds number that has a low mixing efficiency. In this study, we firstly introduce a conductive liquid-based focused surface acoustic wave (CL-FSAW) device for mixing. Using the concentrated acoustic force of CL-FSAW, rapid and efficient mixing of deionized water and fluorescent particle suspension was demonstrated in a microfluidic channel. Effects of the applied voltage and the flow rate on the mixing efficiencies were investigated. As the flow rate decreased or the applied voltage increased, the mixing efficiency increased. At 21V, mixing efficiencies were higher than 90% at a flow rate lower than 120μLmin−1. 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B, Chemical</jtitle><date>2018-04-01</date><risdate>2018</risdate><volume>258</volume><spage>991</spage><epage>997</epage><pages>991-997</pages><issn>0925-4005</issn><eissn>1873-3077</eissn><abstract>•Using the concentrated acoustic force of a conductive liquid-based focused surface acoustic wave (CL-FSAW) device, rapid and efficient mixing can be achieved.•In the CL-FSAW mixer, high efficiency mixing performance can be achieved (efficiency ∼97%) at a flow rate of Q≤80μLmin−1 with an applied voltage of 21V.•For further application, CL-FSAW mixer device was applied to continuous synthesis of monodispersed silver nanoparticles at Q=100μLmin−1 and V=21V. Acoustic manipulation of fluids and particles has gained much attention in microfluidics, owing to its advantages of non-invasive manipulation and low power consumption. Microchannel mixing has been limited to diffusion-based mixing, because of low Reynolds number that has a low mixing efficiency. 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subjects	Conductive liquid Deionization Electric potential Flow velocity Fluid dynamics Fluid flow Fluorescence Focused surface acoustic wave Microchannels Microfluidics Micromixing Nanoparticles Power consumption Reynolds number Sensors Surface acoustic waves
title	Micromixing using a conductive liquid-based focused surface acoustic wave (CL-FSAW)
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