Effects of Fluid–Structure–Interaction and Surface Heterogeneity on the Electrophoresis of Microparticles

Mitra, Shirsendu; Mukherjee, Shreya; Ghosh, Abir; Bandyopadhyay, Dipankar

doi:10.1021/acs.iecr.8b06345

Cited by 6 publications

(3 citation statements)

References 94 publications

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“…], which has provided effective and steady support for research in fluid dynamics 50 and electrophoresis. 51 Density, size, and collision during diffusion were considered as variables to study the dominance of mass during the electrophoresis process. Correspondingly, we first considered particles with different sizes (46 nm, 60 nm, 100 nm, and 122 nm) and identical densities under the condition of collision.…”

Section: The Physical Mechanism Of the Dynamic Electrophoresis Processmentioning

confidence: 99%

Mass-determining role in the electrophoretic separation of colloidal plasmonic nanoparticle oligomers

et al. 2022

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Section: The Physical Mechanism Of the Dynamic Electrophoresis Processmentioning

confidence: 99%

Mass-determining role in the electrophoretic separation of colloidal plasmonic nanoparticle oligomers

et al. 2022

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“…Miniaturized objects often experience a notable reduction in the drag force as compared to their macroscopic counterparts when they undergo a motion inside a fluidic environment owing to the sharp decline in their total surface area. In such a scenario, various external stimuli such as the chemical potential gradient, − photonic excitation, , acoustic waves, surface tension gradient, , electric − or magnetic , fields, osmotic pressure imbalance, and chemo-magnetic , fields can fuel-up self-propulsion − after subduing the weak frictional influence originating from the surrounding fluidic environment. These stimuli-responsive behaviors are commonly termed as the chemotaxis, − phototaxis, Marangoni motion, , galvanotaxis, , or magnetotaxis , of micro- or nanoscale objects.…”

Section: Introductionmentioning

confidence: 99%

Nonequilibrium Dynamics of Transient Autoelectrophoresis and Effect of Surface Heterogeneity

Mitra

Basak

2023

J. Phys. Chem. B

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Nonuniform proton flux around a reactive Janus particle as a result of zone selective heterogeneous surface reaction leads to the formation of asymmetric electrical double layers (EDLs) which assists in generating a proximate electric field dipole around the Janus particle to initiate autoelectrophoretic migration. To estimate the force of the autoelectrophoretic motion of such Janus particles, a mathematical model is set up taking Poisson−Nernst−Plank (PNP) equations coupled with the Navier−Stokes (NS) equations with appropriate boundary conditions. To track the actual motion of these particles, we employ moving deforming mesh and fluid−structure interactions (fsi) of COMSOL Multiphysics while a finite element method is deployed for solving the set of modeled equations. At the outset, transient genesis of the electric field around the particle owing to the nonuniform proton flux has been explored. We further explore the detailed unsteady particle dynamics of the autoelectrophoretic motion with the help of fluid structure interaction physics. It has been observed that the concept of perfect ionic equilibrium in autoelectrophoretic motion is hard to achieve. The autoelectrophoretic particle undergoes continuous change in terms of the ionic concentration around it, speed of the particle, and the transient electric field gradient across the particle. The parametric variation of proton flux reveals that at a relatively lower proton flux a quasi-equilibrium state can be achieved, whereas for higher proton flux the phenomenon can be a pure nonequilibrium case. This parametric study has been done to support the transient dynamics. It has also been shown that the presence of chemical heterogeneity on the particle surface can alter the dynamics of the particle significantly, and the chemical heterogeneity can be used as a tool to control directionality and tuning speed of autoelectrophoretic motion.

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“…In recent times, the development of efficient microfluidic systems has become one of the key areas of research because of its widespread applications, which include electro-micro-total analysis systems (μ-TAS), micro-electromechanical systems (MEMS), lab-on-a-chip (LOC) devices, and many more. − These types of devices are extensively used for drug delivery, DNA analysis, detection of biohazardous agents, molecular separation, point-of-care diagnostic applications, etc. The efficient and rapid mixing of the two fluids is a challenging issue for such microlevel transport systems. − Generally, the mixing is divided into two categories, namely passive mixing and active mixing. , Passive mixing includes obstacles in the flow path, , adding waviness at the surfaces, , curved ribs, , grooves, , etc.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Electroosmotic Mixing in a Wavy Micromixer Using Surface Charge Heterogeneity

Mehta

Pati

2022

Ind. Eng. Chem. Res.

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We investigate the flow and mixing characteristics for an electroosmotic flow through a wavy micromixer using surface charge heterogeneity. The Laplace equation for the external electric field, Poisson–Boltzmann equation for potential distribution, and continuity and momentum equations for fluid flow and species transport equation have been solved by imposing the appropriate boundary conditions using a finite element method-based numerical solver. The results are presented by varying the phase lag of sinusoidal zeta potential between the two walls (Δϕ), Debye parameter (κ), geometrical wave number (n), dimensionless wall amplitude (α), and diffusive Peclet number (Pe). The results reveal that the phase lag has a strong confluence on the flow field and mixing performance together with other physicochemical parameters. The strength of primary flow as well as the size of the recirculation zones increases with Δϕ and κ, and additional recirculation zones are formed in the core of the mixer for Δϕ = 0. The value of mixing efficiency is close to 100% up to a critical value of Pe (Pe Cri), the value of which is greater for the nonuniformly charged surface potential with a nonzero phase lag. For thinner EDL (κ = 150), a fully mixed state based on 90% mixing is achieved up to higher values of Pe with a higher flow rate at Δϕ = π/2 and π. Also, for Δϕ = π/2, the mixing efficiency as well as the flow rate enhances with the amplitude of the channel walls for Pe Cri ≤ Pe ≤323.5. Moreover, for Δϕ = 0, the value of mixing efficiency increases with α for 786 ≤ Pe ≤1000 with a 9.17% decrement in the flow rate for the change in α from 0.05 to 0.25.

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Effects of Fluid–Structure–Interaction and Surface Heterogeneity on the Electrophoresis of Microparticles

Cited by 6 publications

References 94 publications

Mass-determining role in the electrophoretic separation of colloidal plasmonic nanoparticle oligomers

Mass-determining role in the electrophoretic separation of colloidal plasmonic nanoparticle oligomers

Nonequilibrium Dynamics of Transient Autoelectrophoresis and Effect of Surface Heterogeneity

Enhanced Electroosmotic Mixing in a Wavy Micromixer Using Surface Charge Heterogeneity

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