Analysis of Electrokinetic Mixing Using AC Electric Field and Patchwise Surface Heterogeneities

Luo, Win‐Jet; Yarn, Kao-Feng; Hsu, Shou-Ping

doi:10.1143/jjap.46.1608

Cited by 11 publications

(5 citation statements)

References 23 publications

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“…This standard problem is then solved by a restarted, iterative Arnoldi method, which is essentially a sophisticated extension of the power iteration method, and which allows a number of eigenvalues,  , of largest magnitude to be calculated via ARPACK (Saad [19]). For the detailed algorithm of the linear stability analysis, one can refer to the studies of Yang and Luo [20], Luo et al [21] and Chen et al [13].…”

Section: Methodsmentioning

confidence: 99%

Aspect Ratio Effect on Multiple Flow Solutions in a Two-Sided Parallel Motion Lid-Driven Cavity

et al. 2014

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A continuation method, accompanied with a linear stability analysis, is employed to investigate the bifurcation diagram of the flow solutions, as well as the multiple flow states in a cavity with different aspect ratios for parallel motion of two facing lids. The Reynolds number proportional to the wall velocity is used as the continuation parameter, and the evolution of the bifurcation diagrams in cases with different aspect ratios is illustrated. The induced flow patterns are highly dependent upon both the aspect ratios and the moving velocity of the walls. Three different types of bifurcation diagrams and their corresponding flow states are classified according to the aspect ratios. One stable symmetric flow state and one stable asymmetric flow state are identified. The stable asymmetric flow state is obtained at a high aspect ratio and a low Reynolds number. Meanwhile, the regions of stable and unstable flows are distinguished according to the different aspect ratios.

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Section: Methodsmentioning

confidence: 99%

Aspect Ratio Effect on Multiple Flow Solutions in a Two-Sided Parallel Motion Lid-Driven Cavity

et al. 2014

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“…Temporal profiles of the switching process were obtained using a detection system similar to that presented by Alarie et al [4]. The details of the measurement principle are presented in the literature [5], and hence the operating process is described only briefly in the following: (1) the sample was introduced into the inlet channel via the application of an electrical potential to the sample inlet channel, [6][7] (2) the same electrical potential was applied to each of the focusing channels in order to generate sheath flows to focus the sample into a narrow stream, and (3) the outlet channels were electrically isolated or grounded, as appropriate, in order to drive the focused sample flow electrokinetically to the required outlet port. The present microfluidic chip was fabricated on glass substrates using standard photolithography and wet chemical etching techniques.…”

Section: Methodsmentioning

confidence: 99%

Electrokinetic Instability Induced Valveless Multi-Switching in a Microfluidic Chip

Chang

Hsieh

Yarn

et al. 2010

2010 Symposium on Photonics and Optoelectronics

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This work presents the experimental investigation with electrokinetic flow mixing for bio-analytical chip applications. By DC electrokinetic instability induced technique, we design a 5x5 microfluidic device which possesses microfluidic sample handling in flow multi-switching. The device not only control single sample flows into different outlets considered but also the multi-sample injection into specific outlet ports. Experimental results indicate that the sample flow could be electrokinetically pre-focusing to a narrow stream and then guided into a desired outlet port and successfully control devices of the voltage in the microfluidic chip.

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“…Fluid mixing schemes can be divided into either "active", where external forces drive fluid movement, like electric field perturbations [1,2] and mechanical agitation [3], or "passive", where the contact area and contact time of the species samples are increased through specially designed inserts, like a static mixer [4] and modified wall [5,6]. A static mixer is an efficient mixing device that incorporates continuously repeating elements in the pipeline and influences the fluid flow during the process, intensifying the mass and heat transfer [7].…”

Section: Introductionmentioning

confidence: 99%

Research for a Non-Standard Kenics Static Mixer with an Eccentricity Factor

et al. 2021

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The Kenics static mixer is one of the most widely studied static mixers, whose structure–function relationship has been studied by varying its aspect ratio and modifying the surface. However, the effect of the symmetric structure of the Kenics static mixer itself on twisting the fluid has been neglected. In order to study how the symmetrical structure of the Kenics static mixer impacts the fluid flow, we changed the center position of elements at twist angle 90° and introduced the eccentricity factor γ. We applied LHS-PLS to study this non-standard Kenics static mixer and obtained the statistical correlations of the aspect ratio, Reynolds number, and eccentricity factor on relative Nusselt number and relative friction factor. We analyzed the results by comparing the PLS model with the univariate analysis, and it was found that the underlying logic of the Kenics static mixer with an asymmetric structure became different. In addition, a non-standard Kenics static mixer with an asymmetric structure was investigated using vortex generation and dissipation through fluid flow simulation. The results demonstrated that the classical symmetric structure has a minor pressure drop, but the backward eccentric one has a higher thermal-hydraulic performance factor. It was found that the nature of the eccentric structure is that two elements with different aspect ratios are being combined at θ=90°, and this articulation leads to non-standard Kenics static mixers with different underlying logic, which finally result in the differences between the PLS model and the univariate analysis.

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Analysis of Electrokinetic Mixing Using AC Electric Field and Patchwise Surface Heterogeneities

Cited by 11 publications

References 23 publications

Aspect Ratio Effect on Multiple Flow Solutions in a Two-Sided Parallel Motion Lid-Driven Cavity

Aspect Ratio Effect on Multiple Flow Solutions in a Two-Sided Parallel Motion Lid-Driven Cavity

Electrokinetic Instability Induced Valveless Multi-Switching in a Microfluidic Chip

Research for a Non-Standard Kenics Static Mixer with an Eccentricity Factor

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