Experimental exploration on stable expansion phenomenon of sheath flow in viscous microfluidics

Microfluidic technologies have been developed for decades, especially in bio-chemical research and applications. Among them, sheath flow is one of the most well-known techniques used for focusing microparticles into extremely narrow widths. With varying Reynolds numbers, sheath flow displays different behaviors, including diffusion, stable thread, and turbulence. In this study, a previously unknown phenomenon, namely, stable expansion, is originally reported in a 200 × 70 μm microchannel with a Reynolds number ranging from ∼10 to ∼110. This stable expansion of focusing width differs from all the reported phenomena in the literature and is experimentally explored in this study. First, the phenomenon is introduced, identified, and comprehensively described using different experimental samples and methods. Subsequently, an image processing algorithm of post-analysis is proposed and calibrated by the theoretical results of stable thread. Based on the calibrated standard protocol, the effects of flow rates and a hysteresis phenomenon due to variation in the flow rate are revealed and studied. In addition, the effects of fluid viscosity are investigated by introducing a mixture of deionized (DI) water and glycerin. It is found that, in this 200 × 70  μm2 (weight × height) microchannel made of PDMS, the stable expansion phenomenon will occur when the Reynolds number exceeds 10, and the expanded width will increase with total flow rate. Moreover, it is found that the expanded width in a flow rate reducing route is displayed to be wider than that in an increasing route. On the other hand, a high viscosity contrast (>40) between the middle sample and sheath flows can eliminate the focusing width expansion. The results indicate that this originally revealed phenomenon is experimentally repeatable and worth further studying to help researchers better understand the mechanism of microfluidics.

[1]  Shenmin Zhang Mixed convective heat transfer of medium-Prandtl-number fluids in horizontal circular tubes , 2022, International Journal of Heat and Mass Transfer.

[2]  J. Lai,et al.  Transition to chaos in a two-sided collapsible channel flow , 2021, Journal of Fluid Mechanics.

[3]  T. Huang,et al.  Microfluidic Isolation and Enrichment of Nanoparticles. , 2020, ACS nano.

[4]  M. Hoorfar,et al.  Sheath‐assisted focusing of microparticles on lab‐on‐a‐chip platforms , 2020, Electrophoresis.

[5]  Yeu‐Chun Kim,et al.  On-chip electroporation system of Polyimide film with sheath flow design for efficient delivery of molecules into microalgae , 2020 .

[6]  Wenfeng Liang,et al.  Optoelectrokinetics-based microfluidic platform for bioapplications: A review of recent advances. , 2019, Biomicrofluidics.

[7]  Ju Min Kim,et al.  Vortex generation by viscoelastic sheath flow in flow-focusing microchannel , 2019, Korean Journal of Chemical Engineering.

[8]  Jun‐Seok Oh,et al.  Effects of sheath gas flow on He atmospheric pressure plasma jet , 2019, Applied Physics Express.

[9]  Seung-Ki Lee,et al.  Separation of particles with bacterial size range using the control of sheath flow ratio in spiral microfluidic channel , 2019, Sensors and Actuators A: Physical.

[10]  Jiashu Sun,et al.  Lipid Nanovesicles by Microfluidics: Manipulation, Synthesis, and Drug Delivery , 2018, Advanced materials.

[11]  Zachary D. Schultz,et al.  Online Liquid Chromatography-Sheath-Flow Surface Enhanced Raman Detection of Phosphorylated Carbohydrates. , 2018, Analytical chemistry.

[12]  Q. Fang,et al.  A robust and extendable sheath flow interface with minimal dead volume for coupling CE with ESI-MS. , 2018, Talanta.

[13]  Lobat Tayebi,et al.  Microfluidic Manipulation of Core/Shell Nanoparticles for Oral Delivery of Chemotherapeutics: A New Treatment Approach for Colorectal Cancer , 2016, Advanced materials.

[14]  Gangrou Peng,et al.  Investigation of particle lateral migration in sample‐sheath flow of viscoelastic fluid and Newtonian fluid , 2016, Electrophoresis.

[15]  Uwe Schnakenberg,et al.  Simultaneous optical and impedance analysis of single cells: A comparison of two microfluidic sensors with sheath flow focusing , 2015 .

[16]  T. Cubaud,et al.  Regimes of miscible fluid thread formation in microfluidic focusing sections , 2014 .

[17]  Leslie Y Yeo,et al.  Microfluidic devices for bioapplications. , 2011, Small.

[18]  Sungyoung Choi,et al.  Three-dimensional hydrodynamic focusing with a single sheath flow in a single-layer microfluidic device. , 2009, Lab on a chip.

[19]  Lisa R. Hilliard,et al.  Multi-wavelength microflow cytometer using groove-generated sheath flow. , 2009, Lab on a chip.

[20]  Kurt Dirk Bettenhausen,et al.  A method for sheath flow forming, controlling, and detecting , 2007, International Symposium on Optomechatronic Technologies.

[21]  Roland Zengerle,et al.  Microfluidic platforms for lab-on-a-chip applications. , 2007, Lab on a chip.

[22]  Gwo-Bin Lee,et al.  Micromachined flow cytometers with embedded etched optic fibers for optical detection , 2003 .

[23]  M. Johnston,et al.  Sheath Flow Focusing in Supersonic Jet Spectroscopy , 1987 .