Your search keyword '"Gui-ren Wang"' showing total 4 results

1. Mechanisms of rectangular groove-induced multiple-microdroplet coalescences

Author

Zhaomiao Liu, Gui-Ren Wang, Feng Shen, and Yi Li

Subjects

Coalescence (physics), Microchannel, Materials science, Continuous phase modulation, business.industry, Capillary action, Mechanical Engineering, 010401 analytical chemistry, Microfluidics, Computational Mechanics, 02 engineering and technology, Trapping, Mechanics, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Velocity vector, Physics::Fluid Dynamics, Optics, Droplet-based microfluidics, 0210 nano-technology, business

Abstract

The mechanism of microdroplet coalescence is a fundamental issue for droplet-based microfluidics. We developed an asymmetric expansion (a rectangular groove) along one side of a microchannel to achieve multiple-microdroplet trapping, collision, and coalescence. Compared with reported symmetric expansions, this asymmetric groove could easily trap microdroplets and control two or three microdroplet coalescences precisely without a requirement for temporal and spatial synchronization. To reveal the mechanisms of multiple-droplet coalescences in a groove, we observed five different coalescence patterns under different flow conditions. Moreover, we characterized the flow behavior quantitatively by simulating the velocity vector fields in both the microdroplets and continuous phase, finding good agreement with experiments. Finally, a map of coalescence forms with different capillary numbers ( $$0.001< {Ca}

Published

2017

2. Advances in Micro-Droplets Coalescence Using Microfluidics

Author

Gui-Ren Wang, Feng Shen, Yi Li, Zhaomiao Liu, and Cao Rentuo

Subjects

Physics::Fluid Dynamics, Fusion, Microchannel, Chemistry, Drop (liquid), Electric field, Surface acoustic wave, Microfluidics, Fluid dynamics, Nanotechnology, Analytical Chemistry, Magnetic field

Abstract

Recently, with the development of lab-on-a-chip researches, the use of microfluidics to precisely control the droplet behaviors in microchannel has received more and more research attention. This article firstly introduces the basic theory and mechanism of the droplets coalescence. Then, it carefully reviews the passive methods of droplets coalescence used in current researches by changing microchannel geometry and adding surfactants. The active methods to trigger droplet fusion such as applied electric field, magnetic fields, temperature gradients, surface acoustic wave and focused lasers are also introduced briefly. We also introduce the fluid dynamics of the droplets coalescence and forecast its progress at last to provide useful guidance for microfluidic devices design and wide use of the drop-based microfluidics.

Published

2015

3. Reversal current observed in micro- and submicro-channel flow under non-continuous DC electric field.

Author

Yi-fei Duan, Hong-wei Ma, Ze-yang Gao, Kai-ge Wang, Wei Zhao, Dan Sun, Gui-ren Wang, Jun-jie Li, Jin-tao Bai, and Chang-zhi Gu

Subjects

BIOCHIPS, BIOSENSORS, BIOMOLECULES, SINGLE molecules, ELECTRODES

Abstract

In practical applications of biochips and bio-sensors, electrokinetic mechanisms are commonly employed to manipulate and analyze the characteristics of single bio-molecules. To accurately and flexibly control the movement of single molecule within micro-/submicro-fluidic channels, the characteristics of current signals at the initial stage of the flow are systematically studied based on a three-electrode system. The current response of micro-/submicro-fluidic channels filled with different electrolyte solutions in non-continuous external electric field are investigated. It is found, there always exists a current reversal phenomenon, which is an inherent property of the current signals in micro/submicro-fluidics Each solution has an individual critical voltage under which the steady current value is equal to zero The interaction between the steady current and external applied voltage follows an exponential function. All these results can be attributed to the overpotentials of the electric double layer on the electrodes. These results are helpful for the design and fabrication of functional micro/nano-scale fluidic sensors and biochips. [ABSTRACT FROM AUTHOR]

Published

2017

4. Direct observation of λ-DNA molecule reversal movement within microfluidic channels under electric field with single molecule imaging technique.

Author

Fengyun Yang, Kaige Wang, Dan Sun, Wei Zhao, Hai-qing Wang, Xin He, Gui-ren Wang, and Jin-tao Bai

Subjects

SINGLE molecule research, MICROFLUIDICS, ELECTRIC field effects, DNA analysis, BIOMEDICAL engineering

Abstract

The electrodynamic characteristics of single DNA molecules moving within micro-/nano-fluidic channels are important in the design of biomedical chips and bimolecular sensors. In this study, the dynamic properties of λ-DNA molecules transferring along the microchannels driven by the external electrickinetic force were systemically investigated with the single molecule fluorescence imaging technique. The experimental results indicated that the velocity of DNA molecules was strictly dependent on the value of the applied electric field and the diameter of the channel. The larger the external electric field, the larger the velocity, and the more significant deformation of DNA molecules. More meaningfully, it was found that the moving directions of DNA molecules had two completely different directions: (i) along the direction of the external electric field, when the electric field intensity was smaller than a certain threshold value; (ii) opposite to the direction of the external electric field, when the electric field intensity was greater than the threshold electric field intensity. The reversal movement of DNA molecules was mainly determined by the competition between the electrophoresis force and the influence of electro-osmosis flow. These new findings will theoretically guide the practical application of fluidic channel sensors and lab-on-chips for precisely manipulating single DNA molecules. [ABSTRACT FROM AUTHOR]

Published

2016