2018
DOI: 10.1103/physrevapplied.10.044005
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Thermophoretic Manipulation of Micro- and Nanoparticle Flow through a Sudden Contraction in a Microchannel with Near-Infrared Laser Irradiation

Abstract: A temperature gradient in a continuous fluid induces the motion of dispersed micro-and nanoparticles even when the fluid is motionless. This phenomenon is known as thermophoresis, and it is expected to be the basis for techniques to control particle motion. In this study, we use the thermophoresis of microand nanoparticles in a microchannel filled with an aqueous solution to control the particle motion near the inlet of a sudden contraction, which is a narrower channel connecting two wider channels. Microfluid… Show more

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Cited by 29 publications
(36 citation statements)
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References 94 publications
(141 reference statements)
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“…1c,d), achieving 'optical-thermophoretic tweezing' . Although similar phenomena have been reported by other research groups [46][47][48][49][50][51][52] , in many cases the substrates of their devices needed to be pre-treated by a thin layer of high optical absorber, and in no cases have biological cells been used. Our method of using SWNTs clusters instead of an absorbing substrate is important as it will allow cells to be concentrated within standard glass/plastic-ware such as slides, well plates and Petri dishes without modification, which significantly reduces the device fabrication time and cost and so is truly suitable for single-use applications.…”
Section: Microparticle Manipulation Using Laser-induced Thermophoresisupporting
confidence: 77%
“…1c,d), achieving 'optical-thermophoretic tweezing' . Although similar phenomena have been reported by other research groups [46][47][48][49][50][51][52] , in many cases the substrates of their devices needed to be pre-treated by a thin layer of high optical absorber, and in no cases have biological cells been used. Our method of using SWNTs clusters instead of an absorbing substrate is important as it will allow cells to be concentrated within standard glass/plastic-ware such as slides, well plates and Petri dishes without modification, which significantly reduces the device fabrication time and cost and so is truly suitable for single-use applications.…”
Section: Microparticle Manipulation Using Laser-induced Thermophoresisupporting
confidence: 77%
“…Thermophoresis is a rather weak effect, that is, it can be hindered by the fast flow of continuous phase. Therefore, to observe the effect of thermophoresis effectively, we should induce a creeping flow of O(1)O(10) μm0.166667em·0.166667ems1 in the microfluidic channel [53,54]. However, in general, the creeping flow is difficult to control since a finer pressure control resolution is required.…”
Section: Resultsmentioning
confidence: 99%
“…Then, the reservoir for the inlet is lifted by ΔH, as shown in Figure 1b, to induce the fluid flow of a sample solution with a required flow rate. As discussed in [54], the generated pressure difference ΔP in Figure 1 is estimated as ΔP=ρgΔH, where ρ is the mass density of the sample solution and g=9.8 m0.166667em·0.166667ems2 is the acceleration of gravity. In this research, an aqueous solution is used and thus ρ=1.0×103 kg0.166667em·0.166667emm3.…”
Section: Experimental Methodsmentioning
confidence: 99%
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“…Application examples. Several researchers have already utilized the fluorescence intensity method with various dyes (RhB [ 43 , 45 , 59 ], BCECF [ 27 , 70 , 93 ], Ruthenium [ 94 , 95 ]) to observe the temperature field in a thermophoresis experiment. To our best knowledge, despite the experimental robustness, fluorescence lifetime imaging measurements have not been used in thermophoretic studies.…”
Section: Temperature Measurementsmentioning
confidence: 99%