Your search keyword '"Yongxin Song"' showing total 3 results

1. Simultaneous diamagnetic and magnetic particle trapping in ferrofluid microflows via a single permanent magnet

Author

Xinyu Lu, John DuBose, Xiangchun Xuan, Yongxin Song, Yilong Zhou, Junsheng Wang, Dhileep Thanjavur Kumar, Akshay Kale, and Dongqing Li

Subjects

Fluid Flow and Transfer Processes, Ferrofluid, Microchannel, Chemistry, Biomedical Engineering, Analytical chemistry, Trapping, Magnetic particle inspection, Condensed Matter Physics, Molecular physics, Colloid and Surface Chemistry, Magnet, Diamagnetism, Particle, Magnetic nanoparticles, General Materials Science, Regular Articles

Abstract

Trapping and preconcentrating particles and cells for enhanced detection and analysis are often essential in many chemical and biological applications. Existing methods for diamagnetic particle trapping require the placement of one or multiple pairs of magnets nearby the particle flowing channel. The strong attractive or repulsive force between the magnets makes it difficult to align and place them close enough to the channel, which not only complicates the device fabrication but also restricts the particle trapping performance. This work demonstrates for the first time the use of a single permanent magnet to simultaneously trap diamagnetic and magnetic particles in ferrofluid flows through a T-shaped microchannel. The two types of particles are preconcentrated to distinct locations of the T-junction due to the induced negative and positive magnetophoretic motions, respectively. Moreover, they can be sequentially released from their respective trapping spots by simply increasing the ferrofluid flow rate. In addition, a three-dimensional numerical model is developed, which predicts with a reasonable agreement the trajectories of diamagnetic and magnetic particles as well as the buildup of ferrofluid nanoparticles.

Published

2015

2. Sheathless electrokinetic particle separation in a bifurcating microchannel.

Author

Di Li, Xinyu Lu, Yongxin Song, Junsheng Wang, Dongqing Li, and Xiangchun Xuan

Subjects

ELECTROKINETICS, MICROCHANNEL flow, BIFURCATION theory, SEPARATION (Technology), DIELECTROPHORESIS

Abstract

Particle separation has found practical applications in many areas from industry to academia. Current electrokinetic particle separation techniques primarily rely on dielectrophoresis, where the electric field gradients are generated by either active microelectrodes or inert micro-insulators. We develop herein a new type of electrokinetic method to continuously separate particles in a bifurcating microchannel. This sheath-free separation makes use of the inherent wall-induced electrical lift to focus particles towards the centerline of the main-branch and then deflect them to size-dependent flow paths in each side-branch. A theoretical model is also developed to understand such a size-based separation, which simulates the experimental observations with a good agreement. This electric fielddriven sheathless separation can potentially be operated in a parallel or cascade mode to increase the particle throughput or resolution. [ABSTRACT FROM AUTHOR]

Published

2016

3. Simultaneous diamagnetic and magnetic particle trapping in ferrofluid microflows via a single permanent magnet.

Author

Yilong Zhou, Kumar, Dhileep Thanjavur, Xinyu Lu, Kale, Akshay, DuBose, John, Yongxin Song, Junsheng Wang, Dongqing Li, and Xiangchun Xuan

Subjects

DIAMAGNETIC materials, MAGNETIC particles, MAGNETIC fluids, PERMANENT magnets, NUMERICAL analysis, NANOPARTICLES analysis

Abstract

Trapping and preconcentrating particles and cells for enhanced detection and analysis are often essential in many chemical and biological applications. Existing methods for diamagnetic particle trapping require the placement of one or multiple pairs of magnets nearby the particle flowing channel. The strong attractive or repulsive force between the magnets makes it difficult to align and place them close enough to the channel, which not only complicates the device fabrication but also restricts the particle trapping performance. This work demonstrates for the first time the use of a single permanent magnet to simultaneously trap diamagnetic and magnetic particles in ferrofluid flows through a T-shaped microchannel. The two types of particles are preconcentrated to distinct locations of the T-junction due to the induced negative and positive magnetophoretic motions, respectively. Moreover, they can be sequentially released from their respective trapping spots by simply increasing the ferrofluid flow rate. In addition, a three-dimensional numerical model is developed, which predicts with a reasonable agreement the trajectories of diamagnetic and magnetic particles as well as the buildup of ferrofluid nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2015