Your search keyword '"Yongxin Song"' showing total 6 results

1. Surfactant effects on microfluidic extensional flow of water and polymer solutions

Author

Michael Dacus, Mahmud Kamal Raihan, Micah Baghdady, Chase Gabbard, Sen Wu, Joshua B. Bostwick, Yongxin Song, and Xiangchun Xuan

Subjects

Fluid Flow and Transfer Processes, Mechanics of Materials, Mechanical Engineering, Computational Mechanics, Condensed Matter Physics

Abstract

Surfactants are often added to particle suspensions in the flow of Newtonian or non-Newtonian fluids for the purpose of reducing particle-particle aggregation and particle-wall adhesion. However, the impact on the flow behavior of such surfactant additions is often overlooked. We experimentally investigate the effect of the addition of a frequently used neutral surfactant, Tween 20, at the concentration pertaining to microfluidic applications on the entry flow of water and three common polymer solutions through a planar cavity microchannel. We find that the addition of Tween 20 has no significant influence on the shear viscosity or extensional flow of Newtonian water and Boger polyethylene oxide solution. However, such a surfactant addition reduces both the shear viscosity and shear-thinning behavior of xanthan gum and polyacrylamide solutions that each exhibit a strong shear-thinning effect. It also stabilizes the cavity flow and delays the onset of flow instability in both cases. The findings of this work can directly benefit microfluidic applications of particle and cell manipulation in Newtonian and non-Newtonian fluids.

Published

2022

2. Surface-conduction enhanced dielectrophoretic-like particle migration in electric-field driven fluid flow through a straight rectangular microchannel

Author

Xiangchun Xuan, Zhijian Liu, Yongxin Song, Xinxiang Pan, Dongqing Li, and Di Li

Subjects

Fluid Flow and Transfer Processes, Physics, Microchannel, Mechanical Engineering, Computational Mechanics, Nanotechnology, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Electrophoresis, Surface conductivity, Electrokinetic phenomena, Mechanics of Materials, Dukhin number, 0103 physical sciences, Particle, Electrohydrodynamics, Two-phase flow, 0210 nano-technology

Abstract

An electric field has been extensively used to manipulate fluids and particles via electrokinetic flow in microchannels and nanochannels for various lab-on-a-chip applications. Recent studies have demonstrated the action of a dielectrophoretic-like lift force on near-wall particles in an electrokinetic flow due to the particles’ modifications of the field-line structure adjacent to a planar wall. This work presents a fundamental investigation of the lateral migration of dielectric particles in the electrokinetic flow of buffer solutions of varying molar concentrations through a straight rectangular microchannel. We find that the particle migration-induced electrokinetic centerline focusing is significantly enhanced with the decrease of the buffer concentration. This observed phenomenon may be attributed to the increased surface conduction effect in a lower-concentration buffer that yields a larger Dukhin number, Du. It seems qualitatively consistent with a recent theoretical study that predicts a greater ...

Published

2017

3. Induced charge effects on electrokinetic entry flow

Author

Rama Aravind Prabhakaran, Junsheng Wang, Yongxin Song, Yilong Zhou, Chun Yang, Guoqing Hu, Xiangchun Xuan, Cunlu Zhao, and School of Mechanical and Aerospace Engineering

Subjects

Fluid Flow and Transfer Processes, Physics, Electric fields, Microchannel, Mechanical Engineering, 010401 analytical chemistry, Microfluidics, Flow (psychology), Computational Mechanics, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Electrokinetic phenomena, Electrophoresis, Mechanics of Materials, Fluid dynamics, Electrohydrodynamics, 0210 nano-technology, Joule heating, Microscale flows

Abstract

Electrokinetic flow, due to a nearly plug-like velocity profile, is the preferred mode for transport of fluids (by electroosmosis) and species (by electrophoresis if charged) in microfluidic devices. Thus far there have been numerous studies on electrokinetic flow within a variety of microchannel structures. However, the fluid and species behaviors at the interface of the inlet reservoir (i.e., the well that supplies the fluid and species) and microchannel are still largely unexplored. This work presents a fundamental investigation of the induced charge effects on electrokinetic entry flow due to the polarization of dielectric corners at the inlet reservoir-microchannel junction. We use small tracing particles suspended in a low ionic concentration fluid to visualize the electrokinetic flow pattern in the absence of Joule heating effects. Particles are found to get trapped and concentrated inside a pair of counter-rotating fluid circulations near the corners of the channel entrance. We also develop a depth-averaged numerical model to understand the induced charge on the corner surfaces and simulate the resultant induced charge electroosmosis (ICEO) in the horizontal plane of the microchannel. The particle streaklines predicted from this model are compared with the experimental images of tracing particles, which shows a significantly better agreement than those from a regular two-dimensional model. This study indicates the strong influences of the top/bottom walls on ICEO in shallow microchannels, which have been neglected in previous two-dimensional models. Published version

Published

2017

4. Surface-conduction enhanced dielectrophoretic-like particle migration in electric-field driven fluid flow through a straight rectangular microchannel.

Author

Zhijian Liu, Di Li, Yongxin Song, Xinxiang Pan, Dongqing Li, and Xiangchun Xuan

Subjects

ELECTRIC fields, ELECTROKINETICS, MICROCHANNEL flow, MICROFLUIDICS, LABS on a chip, DIELECTRICS

Abstract

An electric field has been extensively used to manipulate fluids and particles via electrokinetic flow in microchannels and nanochannels for various lab-on-a-chip applications. Recent studies have demonstrated the action of a dielectrophoretic-like lift force on near-wall particles in an electrokinetic flow due to the particles' modifications of the field-line structure adjacent to a planar wall. This work presents a fundamental investigation of the lateral migration of dielectric particles in the electrokinetic flow of buffer solutions of varying molar concentrations through a straight rectangular microchannel. We find that the particle migration-induced electrokinetic centerline focusing is significantly enhanced with the decrease of the buffer concentration. This observed phenomenon may be attributed to the increased surface conduction effect in a lower-concentration buffer that yields a larger Dukhin number, Du. It seems qualitatively consistent with a recent theoretical study that predicts a greater wall-induced electrical lift with the increasing value of the Dukhin number for Du ≥1. [ABSTRACT FROM AUTHOR]

Published

2017

5. Induced charge effects on electrokinetic entry flow.

Author

Prabhakaran, Rama Aravind, Yilong Zhou, Cunlu Zhao, Guoqing Hu, Yongxin Song, Junsheng Wang, Chun Yang, and Xiangchun Xuan

Subjects

ELECTROKINETICS, VELOCITY, ELECTROPHORESIS, MICROFLUIDIC devices, MICROCHANNEL flow, RESISTANCE heating

Abstract

Electrokinetic flow, due to a nearly plug-like velocity profile, is the preferred mode for transport of fluids (by electroosmosis) and species (by electrophoresis if charged) in microfluidic devices. Thus far there have been numerous studies on electrokinetic flow within a variety of microchannel structures. However, the fluid and species behaviors at the interface of the inlet reservoir (i.e., the well that supplies the fluid and species) and microchannel are still largely unexplored. This work presents a fundamental investigation of the induced charge effects on electrokinetic entry flow due to the polarization of dielectric corners at the inlet reservoir-microchannel junction.We use small tracing particles suspended in a low ionic concentration fluid to visualize the electrokinetic flow pattern in the absence of Joule heating effects. Particles are found to get trapped and concentrated inside a pair of counterrotating fluid circulations near the corners of the channel entrance.We also develop a depth-averaged numerical model to understand the induced charge on the corner surfaces and simulate the resultant induced charge electroosmosis (ICEO) in the horizontal plane of the microchannel. The particle streaklines predicted from this model are compared with the experimental images of tracing particles, which shows a significantly better agreement than those from a regular two-dimensional model. This study indicates the strong influences of the top/bottom walls on ICEO in shallow microchannels, which have been neglected in previous two-dimensional models. [ABSTRACT FROM AUTHOR]

Published

2017

6. Induced-charge electrokinetics in a conducting nanochannel with broken geometric symmetry: Towards a flexible control of ionic transport.

Author

Cunlu Zhao, Yongxin Song, and Chun Yang

Subjects

*NANOFLUIDIC devices, *ELECTROKINETICS, *MICROFLUIDICS, *ELECTRIC fields, *ELECTROLYTE solutions, *SYMMETRY (Physics), *IONS

Abstract

In the literature, conventional electrokinetics is widely used as a principle of operating nanofluidic devices. Different from the conventional electrokinetics involving nonpolarizable solid surfaces with fixed surface charge, induced-charge electrokinetic (ICEK) phenomena deal with polarizable surfaces with the ability of surface charge modulation through electric polarization under external electric fields. Because of several advantages, ICEK phenomena have drawn a great deal of attention in microfluidic community. Herein, we propose the first effort of extending the ICEK phenomena from microfluidics to nanofluidics. In particular, we report a numerical model for the ICEK phenomena in a tapered nanochannel with conducting (ideally polarizable) walls. It is shown that due to the broken geometric symmetry of the nanochannel, induced-charge electroosmotic flow inside the nanochannel exhibits a flow rectification such that electrolyte solution always flows from the narrow end of the nanochannel to the wide end for either a forward electric bias (electric field from the narrow to wide ends) or a reverse electric bias (electric field from the wide to narrow ends). In addition, we demonstrate that the ion selectivity of such tapered conducting nanochannel can be actively tuned to be cation-selective with a forward bias and anion-selective with a reverse bias. Promisingly, conducting nanochannels with broken geometric symmetry could be potentially used for constructing nanofluidic pumps with the unidirectional pumping capacity and ion selectors with the tuneable ionic selection. [ABSTRACT FROM AUTHOR]

Published

2015