Your search keyword '"Yossifon, Gilad"' showing total 45 results

1. Active microparticle propulsion pervasively powered by asymmetric AC field electrophoresis.

Author

Diwakar, Nidhi M., Yossifon, Gilad, Miloh, Touvia, and Velev, Orlin D.

Subjects

*INDUCED polarization, *PARTICLE motion, *JANUS particles, *ALTERNATING currents, *SYMMETRY breaking

Abstract

[Display omitted] Symmetry breaking in an electric field-driven active particle system can be induced by applying a spatially uniform, but temporally non-uniform, alternating current (AC) signal. Regardless of the type of particles exposed to sawtooth AC signals, the unevenly induced polarization of the ionic charge layer leads to a major electrohydrodynamic effect of active propulsion, termed Asymmetric Field Electrophoresis (AFEP). Suspensions containing latex microspheres of three sizes, as well as Janus and metal-coated particles were subjected to sawtooth AC signals of varying voltages, frequencies, and time asymmetries. Particle tracking via microscopy was used to analyze their motility as a function of the key parameters. The particles exhibit field-colinear active propulsion, and the temporal reversal of the AC signal results in a reversal of their direction of motion. The experimental velocity data as a function of field strength, frequency, and signal asymmetry are supported by models of asymmetric ionic concentration-polarization. The direction of particle migration exhibits a size-dependent crossover in the low frequency domain. This enables new approaches for simple and efficient on-chip sorting. Combining AFEP with other AC motility mechanisms, such as induced-charge electrophoresis, allows multiaxial control of particle motion and could enable development of novel AC field-driven active microsystems. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optoelectronic Trajectory Reconfiguration and Directed Self‐Assembly of Self‐Propelling Electrically Powered Active Particles.

Author

Das, Sankha Shuvra and Yossifon, Gilad

Subjects

*JANUS particles, *DIGITAL technology, *IMAGE analysis, *MICROMIRROR devices, *MICROROBOTS, *SPANNING trees

Abstract

Self‐propelling active particles are an exciting and interdisciplinary emerging area of research with projected biomedical and environmental applications. Due to their autonomous motion, control over these active particles that are free to travel along individual trajectories, is challenging. This work uses optically patterned electrodes on a photoconductive substrate using a digital micromirror device (DMD) to dynamically control the region of movement of self‐propelling particles (i.e., metallo‐dielectric Janus particles (JPs)). This extends previous studies where only a passive micromotor is optoelectronically manipulated with a translocating optical pattern that illuminates the particle. In contrast, the current system uses the optically patterned electrode merely to define the region within which the JPs moved autonomously. Interestingly, the JPs avoid crossing the optical region's edge, which enables constraint of the area of motion and to dynamically shape the JP trajectory. Using the DMD system to simultaneously manipulate several JPs enables to self‐assemble the JPs into stable active structures (JPs ring) with precise control over the number of participating JPs and passive particles. Since the optoelectronic system is amenable to closed‐loop operation using real‐time image analysis, it enables exploitation of these active particles as active microrobots that can be operated in a programmable and parallelized manner. [ABSTRACT FROM AUTHOR]

Published

2023

3. Perfusion in Organ-on-Chip Models and Its Applicability to the Replication of Spermatogenesis In Vitro.

Author

Shuchat, Sholom, Yossifon, Gilad, and Huleihel, Mahmoud

Subjects

*SPERMATOGENESIS, *BIOPRINTING, *SEMINIFEROUS tubules, *PERFUSION, *CELL communication, *FLUID flow

Abstract

Organ/organoid-on-a-chip (OoC) technologies aim to replicate aspects of the in vivo environment in vitro, at the scale of microns. Mimicking the spatial in vivo structure is important and can provide a deeper understanding of the cell–cell interactions and the mechanisms that lead to normal/abnormal function of a given organ. It is also important for disease models and drug/toxin testing. Incorporating active fluid flow in chip models enables many more possibilities. Active flow can provide physical cues, improve intercellular communication, and allow for the dynamic control of the environment, by enabling the efficient introduction of biological factors, drugs, or toxins. All of this is in addition to the fundamental role of flow in supplying nutrition and removing waste metabolites. This review presents an overview of the different types of fluid flow and how they are incorporated in various OoC models. The review then describes various methods and techniques of incorporating perfusion networks into OoC models, including self-assembly, bioprinting techniques, and utilizing sacrificial gels. The second part of the review focuses on the replication of spermatogenesis in vitro; the complex process whereby spermatogonial stem cells differentiate into mature sperm. A general overview is given of the various approaches that have been used. The few studies that incorporated microfluidics or vasculature are also described. Finally, a future perspective is given on elements from perfusion-based models that are currently used in models of other organs and can be applied to the field of in vitro spermatogenesis. For example, adopting tubular blood vessel models to mimic the morphology of the seminiferous tubules and incorporating vasculature in testis-on-a-chip models. Improving these models would improve our understanding of the process of spermatogenesis. It may also potentially provide novel therapeutic strategies for pre-pubertal cancer patients who need aggressive chemotherapy that can render them sterile, as well asfor a subset of non-obstructive azoospermic patients with maturation arrest, whose testes do not produce sperm but still contain some of the progenitor cells. [ABSTRACT FROM AUTHOR]

Published

2022

4. Suppression of photothermal convection of microparticles in two dimensional nanoplasmonic optical lattice.

Author

Yi-Chung Chen, Yossifon, Gilad, and Ya-Tang Yang

Subjects

*PHOTOTHERMAL effect, *OPTICAL lattices, *HEAT convection, *THERMAL expansion, *OPTICAL tweezers

Abstract

Photothermal convection has been a major obstacle for stable particle trapping in plasmonic optical tweezer at high optical power. Here, we demonstrate a strategy to suppress the plasmonic photothermal convection by using vanishingly small thermal expansion coefficient of water at low temperature. A simple square nanoplasmonic array is illuminated with a loosely Gaussian beam to produce a two dimensional optical lattice for trapping of micro particles. We observe stable particle trapping due to near-field optical gradient forces at elevated optical power at low temperature. In contrast, for the same optical power at room temperature, the particles are convected away from the center of the optical lattice without their accumulation. This technique will greatly increase usable optical power and enhance the trapping capability of plasmonic optical tweezer. [ABSTRACT FROM AUTHOR]

Published

2016

5. Propulsion of Active Colloids by Self-Induced Field Gradients.

Author

Boymelgreen, Alicia, Yossifon, Gilad, and Miloh, Touvia

Subjects

*COLLOIDS, *JANUS particles, *DIELECTRIC properties, *ELECTRIC fields, *SURFACE forces, *DIELECTROPHORESIS, *ELECTROLYTES

Abstract

Previously, metallodielectric Janus particles have been shown to travel with their dielectric hemisphere forward under low frequency applied electric fields as a result of asymmetric induced-charge electroosmotic flow. Here, it is demonstrated that at high frequencies, well beyond the charge relaxation time of the electric double layer induced around the particle, rather than the velocity decaying to zero, the Janus particles reverse direction, traveling with their metallic hemisphere forward. It is proposed that such motion is the result of a surface force, arising from localized nonuniform electric field gradients, induced by the dual symmetry-breaking of an asymmetric particle adjacent to a wall, which act on the induced dipole of the particle to drive net motion even in a uniform AC field. Although the field is external, since the driving gradient is induced on the particle level, it may be considered an active colloid. We have thus termed this propulsion mechanism "self-dielectrophoresis", to distinguish from traditional dielectrophoresis where the driving nonuniform field is externally fixed and the particle direction is restricted. It is demonstrated theoretically and experimentally that the critical frequency at which the particle reverses direction can be characterized by a nondimensional parameter which is a function of electrolyte concentration and particle size. [ABSTRACT FROM AUTHOR]

Published

2016

6. Characterization of the near-field and convectional transport behavior of micro and nanoparticles in nanoscale plasmonic optical lattices.

Author

Tsang-Po Yang, Yossifon, Gilad, and Ya-Tang Yang

Subjects

*NANOPARTICLES, *NANOELECTROMECHANICAL systems, *PLASMONICS, *OPTICAL lattices, *GAUSSIAN beams

Abstract

Here, we report the characterization of the transport of micro- and nanospheres in a simple two-dimensional square nanoscale plasmonic optical lattice. The optical potential was created by exciting plasmon resonance by way of illuminating an array of gold nanodiscs with a loosely focused Gaussian beam. This optical potential produced both in-lattice particle transport behavior, which was due to near-field optical gradient forces, and high-velocity (~μm/s) out-of-lattice particle transport. As a comparison, the natural convection velocity field from a delocalized temperature profile produced by the photothermal heating of the nanoplasmonic array was computed in numerical simulations. This work elucidates the role of photothermal effects on micro- and nanoparticle transport in plasmonic optical lattices. [ABSTRACT FROM AUTHOR]

Published

2016

7. Time-dependent ion transport in heterogeneous permselective systems.

Author

Green, Yoav and Yossifon, Gilad

Subjects

*ION transport (Biology), *HETEROGENEOUS catalysis, *ION-permeable membranes, *NUMERICAL analysis, *CHRONOAMPEROMETRY, *LAPLACE transformation

Abstract

The current study extends previous analytical and numerical solutions of chronopotentiometric response of one-dimensional systems consisting of three layers to the more realistic two-dimensional (2D) heterogeneous ion-permselective medium. An analytical solution for the transient concentration-polarization problem, under the local electroneutrality approximation and assumption of ideal permselectivity, was obtained using the Laplace transform and separation of variables technique. Then the 2D electric potential was obtained numerically and was compared to the full Poisson-Nernst-Planck solution. It was then shown that the resultant voltage drop across the system varies between the initial Ohmic response and that of the steady state accounting for concentration polarization. Also, the field-focusing effect in a 2D system is shown to result in a faster depletion of ions at the permselective interface. [ABSTRACT FROM AUTHOR]

Published

2015

8. Particle dynamics and rapid trapping in electro-osmotic flow around a sharp microchannel corner.

Author

Zehavi, Matan and Yossifon, Gilad

Subjects

*PARTICLE analysis, *ELECTRO-osmosis, *MICROCHANNEL flow, *DIELECTRICS, *POLARIZATION (Electricity), *HYDRODYNAMICS

Abstract

We study here the curious particle dynamics resulting from electro-osmotic flow around a microchannel junction corner whose dielectric walls are weakly polarizable. The hydrodynamic velocity field is obtained via superposition of a linear irrotational term associated with the equilibrium zeta potentials of both the microchannel and particle surfaces and the nonlinear induced-charge electro-osmotic flow which originates from the interaction of the externally applied electric field on the charge cloud it induces at the solid-liquid interface. The particle dynamics are analyzed by considering dielectrophoretic forces via the addition of a mobility term to the flow field in the limit of Stokes drag law. The former, non-divergence free term is responsible for migration of particles towards the sharp microchannel junction corner, where they can potentially accumulate. Experimental observations of particle trapping for various applied electric fields and microparticle size are rationalized in terms of the growing relative importance of the dielectrophoretic force and induced-charge contributions to the global velocity field with increasing intensity of the externally applied electric field. [ABSTRACT FROM AUTHOR]

Published

2014

9. Influence of electric-double-layer structure on the transient response of nanochannels.

Author

Schiffbauer, Jarrod and Yossifon, Gilad

Subjects

*IMPEDANCE spectroscopy, *ELECTRIC double layer, *NAVIER-Stokes equations, *BOUNDARY value problems, *SOLID-liquid interfaces, *DEBYE length

Abstract

A fundamental Poisson-Nernst-Planck-Stokes model is presented for the impedance response of a long nanochannel under zero bias, capturing the effects of surface conduction and the coupling between transverse momentum and axial ion distribution in a manner reminiscent of Taylor dispersion. This is shown to result in a shift of the impedance frequency spectrum with bulk concentration similar to previous experimental observation [Schiffbauer, Liel, and Yossifon, Phys. Rev. E89,033017 (2014)]. It further predicts an additional downward shift in frequency with increasing viscosity. Finally, the introduction of a phenomenological model for the impedance response of a dynamic Stem layer in parallel with the diffuse layer transport model is shown to yield good agreement between theory and experiment. As a result, we are able to obtain an equivalent circuit model based on the fundamental model and proposed corrections. [ABSTRACT FROM AUTHOR]

Published

2014

10. Effects of three-dimensional geometric field focusing on concentration polarization in a heterogeneous permselective system.

Author

Green, Yoav and Yossifon, Gilad

Subjects

*ION-permeable membranes, *ELECTRODIFFUSION, *PROBLEM solving, *POLARIZATION (Electricity), *CONVECTIVE flow

Abstract

The current study extends previous two-dimensional (2D) analysis of concentration polarization to account for three-dimensional effects in realistic heterogeneous ion-permselective systems, e.g., microchamber-nanoslot devices. An analytical solution of the electrodiffusive problem, decoupled from electroconvection along with the local electroneutrality approximation, was obtained using the separation of variables technique. It is able to account for the previously neglected effects of microchamber and nanoslot heights on concentration polarization in terms of concentration profiles, limiting current, and current-voltage curves. The resultant heterogeneity in the third dimension adds to that already existing in the 2D in plane problem to further increase geometric field-focusing effects. As a result the currents no longer scale linearly with the nanoslot area, but rather depend on its shape and relative size compared to that of the nonconducting region (i.e., level of heterogeneity). This is turn leads to pro-nounced current density intensification with increased system heterogeneity found to be in qualitative agreement with previously reported experiments in which both microchamber and nanoslot geometries were varied. [ABSTRACT FROM AUTHOR]

Published

2014

11. Spinning Janus doublets driven in uniform ac electric fields.

Author

Boymelgreen, Alicia, Yossifon, Gilad, Sinwook Park, and Miloh, Touvia

Subjects

*NANOPARTICLES, *JANUS particles, *NANOCOMPOSITE materials, *MICROSTRUCTURE, *ELECTROKINETICS

Abstract

We provide an experimental proof of concept for a robust, continuously rotating microstructure--consisting of two metallodielectric (gold-polystyrene) Janus particles rigidly attached to each other--which is driven in uniform ac fields by asymmetric induced-charge electro-osmosis. The pairs (doublets) are stabilized on the substrate surface which is parallel to the plane of view and normal to the direction of the applied electric field. We find that the radius of orbit and angular velocity of the pair are predominantly dependent on the relative orientations of the interfaces between the metallic and dielectric hemispheres and that the electrohydrodynamic particle-particle interactions are small. Additionally, we verify that both the angular and linear velocities of the pair are proportional to the square of the applied field which is consistent with the theory for nonlinear electrokinetics. A simple kinematic rigid body model is used to predict the paths and doublet velocities (angular and linear) based on their relative orientations with good agreement. [ABSTRACT FROM AUTHOR]

Published

2014

12. Dynamical trapping of colloids at the stagnation points of electro-osmotic vortices of the second kind.

Author

Green, Yoav and Yossifon, Gilad

Subjects

*ELECTRO-osmosis, *COLLOIDS, *DYNAMICAL systems, *STAGNATION point, *VORTEX motion, *HYDRODYNAMICS

Abstract

By applying a stepwise overlimiting voltage to a nanoslot system in equilibrium, it is possible to follow the time evolution of the electroconvective instability vortex array via the depletion dynamics or, alternatively, by following dielectrophoretically trapped particles at the stagnation points of each of the hydrodynamic vortex pairs. Particles are advected to the stagnation point by the hydrodynamics, where they are trapped by a short-range dielectrophoretic force. It is experimentally confirmed that the wavelength selection process occurs at the diffusive time scale and that the wavelength selection mechanism, started by the Rubinstein and Zaltzman electroconvective instability is eventually determined by the system lateral geometry and dictated by Dukhin's electro-osmosis of the second kind. The steady-state case was numerically studied by solving the fully coupled electroconvective problem, confirming that the vortex stagnation point is indeed of a converging type. The particle's planar (two-dimensional) equations of motion are solved after adding a dielectrophoretic force that accounts for quasi-three-dimensional effects. It is shown that this force can account for trapping at the nanoslot interface. [ABSTRACT FROM AUTHOR]

Published

2013

13. Role of electro-osmosis in the impedance response of microchannel-nanochannel interfaces.

Author

Schiffbauer, Jarrod and Yossifon, Gilad

Subjects

*ELECTRO-osmosis, *ELECTRIC impedance, *DIRECT currents, *POISSON distribution, *ELECTRODIFFUSION

Abstract

The influence of net fluid flow on the low-frequency ac response of a microchannel-nanochannel interface under dc bias is studied theoretically using a simple ID model based on the Poisson-Nernst-Planck-Stokes equations. The model describes cross-sectional averaged transport wherein the electro-osmotic flow is controlled by the magnitude of the dc bias and captures essential features of the problem related to the micro-nano interface, specifically geometric focusing effects and nanochannel control of the net fluid flow. This model predicts behavior which differs from that predicted by a purely electrodiffusive formulation. The high-frequency edge of the Warburg branch of the complex impedance plot has a slope which deviates from the π/4 Warburg value, decreasing with increasing bias, and there are corresponding changes in the overall phase as seen in the Bode plots. This can be attributed to a streaming contribution to the capacitive reactance of the device as well an increase in the conductance of the depleted region, both due to net fluid flow. The increase in conductance, corresponding to reduced interfacial depletion, also permits dc currents above the classical electrodiffusive limit. [ABSTRACT FROM AUTHOR]

Published

2012

14. Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux.

Author

Chang, Hsueh-Chia, Yossifon, Gilad, and Demekhin, Evgeny A.

Subjects

*HYDRODYNAMICS, *FLUID dynamics, *ELECTROKINETICS, *ELECTRODYNAMICS, *NANOFLUIDS, *IONIC structure

Abstract

When a direct current (DC) electric field is applied across an ion-selective nanoporous membrane or a nanochannel with an overlapping Debye layer, a surprising microvortex instability occurs on the side of the membrane//channel through which counterions enter. Despite its micro and nano length scales, this instability exhibits all the hallmarks of other classical hydrodynamic instabilities-a subharmonic cascade, a wide-band fluctuation spectrum, and a coherent structure dominated by spatiotemporal dynamics. Moreover, the resulting convection enhances the ion flux into the ion-selective medium and gives rise to an overlimiting-current bifurcation in the current-voltage relationship. This hydrodynamically driven nonequilibrium ion flux does not seem to have any equivalent in cell membrane ion channels. Yet, by introducing asymmetric entrances to provide different polarized regions and//or viscous arrest of the vortex instability, one can fabricate a hydrodynamic nanofluidic diode. With other modifications, hysteretic, excitable, and oscillatory ion flux dynamics could also be elicited-all with strong hydrodynamic features. [ABSTRACT FROM AUTHOR]

Published

2012

15. Dipolophoresis of dielectric spheroids under asymmetric fields.

Author

Frankel, Itzchak, Yossifon, Gilad, and Miloh, Touvia

Subjects

*CHEMICAL processes, *SPHEROIDAL state, *COLLOIDS, *ELECTROSTATICS, *HYDRODYNAMICS, *STRAINS & stresses (Mechanics), *MONOTONIC functions, *PERMITTIVITY

Abstract

Non-spherical particles are common in colloidal science. Spheroidal shapes are particularly convenient for the analysis of the pertinent electrostatic and hydrodynamic problems and are thus widely used to model the manipulation of biological cells as well as deformed drops and bubbles. We study the rotary motion of a dielectric spheroidal micro-particle which is freely suspended in an unbounded electrolyte solution in the presence of a uniform applied electric field, assuming a thin Debye layer. For the common case of a uniform distribution of the native surface-charge density, the rotary motion of the particle is generated by the contributions of the induced-charge electro-osmotic (ICEO) slip and the dielectrophoresis associated with the distribution of the Maxwell stress, respectively. Series solutions are obtained by using spheroidal (prolate or oblate) coordinates. Explicit results are presented for the angular velocity of particles spanning the entire spectrum from rod-like to disk-like shapes. These results demonstrate the non-monotonic variation of the angular speed with the eccentricity of particle shape and the singularity of the multiple limits corresponding to conducting (ideally polarizable) particles of extreme eccentricity (e ≈ 1). The non-monotonic variation of the angular speed with the particle dielectric permittivity is related to the induced-charge contribution. We apply these results to describe the motion of particles subject to a uniform field rotating in the plane. For a sufficiently slow rotation rate, prolate particles eventually become 'locked' to the external field with their stationary relative orientation in the plane of rotation being determined by the particle eccentricity and dielectric constant. This effect may be of potential use in the manipulation of poly-disperse suspensions of dielectric non-spherical particles. Oblate spheroids invariably approach a uniform orientation with their symmetry axes directed normal to the external-field plane of rotation. [ABSTRACT FROM AUTHOR]

Published

2012

16. Nonlinear electrokinetic phenomena around nearly insulated sharp tips in microflows

Author

Eckstein, Yuval, Yossifon, Gilad, Seifert, Avraham, and Miloh, Touvia

Subjects

*MICROFLUIDICS, *ELECTROKINETICS, *VORTEX motion, *NONLINEAR statistical models, *PARTICLE image velocimetry, *FLOW visualization, *ZETA potential

Abstract

Abstract: This contribution seeks to provide for the first time a combined comprehensive theoretical prediction and quantitative experimental (microparticle imaging velocimetry –-PIV) measurements of the nonlinear electrokinetic flow around sharp tips in order to substantiate former theoretical and qualitative experimental flow visualization results [S.K. Thamida, H.C Chang, Phys. Fluids 14 (2002) 12; P. Takhistov, K. Duginova, H.C. Chang, J. Colloid Interface Sci. 263 (2003) 133; G. Yossifon, I. Frankel, T. Miloh, Phys. Fluids 18 (2006) 117108]. The study focuses on two microchannel designs: an L-shaped channel and two isolated tips in a straight channel, important in engineering for mixing and particle-trapping purposes. The new experimental results were explained in terms of an induced-charge electrokinetic mechanism alone, without the concentration polarization mechanism as suggested by earlier studies. The vortex generation phenomenon around corners was explained in terms of the varying ratio between the equilibrium and the induced-charge zeta-potentials, showing fair qualitative agreement between numerical and experimental results. Hence, a transition from an irrotational to nonlinear-dominated flow with a vortex pattern occurs beyond a certain electric-field threshold. In particular, for the L-shaped channel case, it is demonstrated that beyond a second field threshold an upstream vortex appears in addition to the downstream one. [Copyright &y& Elsevier]

Published

2009

17. Understanding electrokinetics at the nanoscale: A perspective.

Author

Hsueh-Chia Chang and Yossifon, Gilad

Subjects

*ELECTROKINETICS, *NANOELECTROMECHANICAL systems, *ELECTROMAGNETIC fields, *MICROFLUIDICS, *DETECTORS

Abstract

Electrokinetics promises to be the microfluidic technique of choice for portable diagnostic chips and for nanofluidic molecular detectors. However, despite two centuries of research, our understanding of ion transport and electro-osmotic flow in and near nanoporous membranes, whose pores are natural nanochannels, remains woefully inadequate. This short exposition reviews the various ion-flux and hydrodynamic anomalies and speculates on their potential applications, particularly in the area of molecular sensing. In the process, we revisit several old disciplines, with some unsolved open questions, and we hope to create a new one. [ABSTRACT FROM AUTHOR]

Published

2009

18. Universal low-frequency asymptotes of dynamic conic nanopore rectification: An ionic nanofluidic inductor.

Author

Yu Yan, Schiffbauer, Jarrod, Yossifon, Gilad, and Hsueh-Chia Chang

Subjects

*NANOPORES, *NANOFLUIDICS, *ELECTRIC inductors, *CAPACITORS, *ELECTRIC resistors, *DIODES

Abstract

We report the first nanofluidic inductor (L) to complement the known nanofluidic capacitors (C), resistors (R), and diodes for ion currents. Under negative bias, the nanopore behaves like a parallel RC circuit at low frequencies; however, under positive bias, the asymptotic dynamics is that of a serial RL circuit. This new ionic circuit element can lead to nanofluidic RLC or diode-inductor oscillator circuits and new intrapore biosensing/rapid sequencing strategies. A universal theory, with explicit estimates for the capacitance and inductance at opposite biases, is derived to collapse the rectified dynamics of all conic nanopores to facilitate design of this new nanofluidic circuit. [ABSTRACT FROM AUTHOR]

Published

2015

19. Micromotor-based localized electroporation and gene transfection of mammalian cells.

Author

Yue Wu, Afu Fu, and Yossifon, Gilad

Subjects

*GENE transfection, *ELECTROPORATION, *MOLECULAR biology, *JANUS particles, *CELL suspensions

Abstract

Herein, we studied localized electroporation and gene transfection of mammalian cells using a metallodielectric hybrid micromotor that is magnetically and electrically powered. Much like nanochannel-based, local electroporation of single cells, the presented micromotor was expected to increase reversible electroporation yield, relative to standard electroporation, as only a small portion of the cell's membrane (in contact with the micromotor) is affected. In contrast to methods in which the entire membrane of all cells within the sample are electroporated, the presented micromotor can perform, via magnetic steering, localized, spatially precise electroporation of the target cells that it traps and transports. In order to minimize nonselective electrical lysis of all cells within the chamber, resulting from extended exposure to an electrical field, magnetic propulsion was used to approach the immediate vicinity of the targeted cell, after which short-duration, electric-driven propulsion was activated to enable contact with the cell, followed by electroporation. In addition to local injection of fluorescent dye molecules, we demonstrated that the micromotor can enhance the introduction of plasmids into the suspension cells because of the dielectrophoretic accumulation of the plasmids in between the Janus particle and the attached cell prior to the electroporation step. Here, we chose a different strategy involving the simultaneous operation of many micromotors that are self-propelling, without external steering, and pair with cells in an autonomic manner. The locally electroporated suspension cells that are considered to be very difficult to transfect were shown to express the transfected gene, which is of significant importance for molecular biology research. [ABSTRACT FROM AUTHOR]

Published

2021

20. Enhanced cargo loading of electrically powered metallo-dielectric pollen bearing multiple dielectrophoretic traps.

Author

Park, Sinwook, Finkelman, Lior, and Yossifon, Gilad

Subjects

*FREIGHT & freightage, *TARGETED drug delivery, *POLLEN, *JANUS particles, *DRUG delivery systems

Abstract

An electrically powered half-coated (Janus) metallo-dielectric sunflower pollen with multiple sharp spikes, acting as an efficient bio-hybrid active carrier for label-free and selective cargo loading and transport for targeted drug delivery. The use of active particles for cargo transport offers unique potential for applications ranging from targeted drug delivery to lab-on-a-particle systems. Previously, deployment of metallo-dielectric Janus spherical particles (JPs) as mobile microelectrodes for transport and dielectrophoretic manipulation of cargo has been shown to be singularly controlled via an applied electric field. Herein, we extended this to a metallo-dielectric pollen featuring multiple dielectrophoretic traps associated with its many spikes, and characterized its loading capacities for various cargo sizes and frequencies. When compared to spherical JPs, the active pollen exhibited a significantly enhanced cargo loading capacity due to its multiple dielectrophoretic traps. These findings open new opportunities for application of bio-hybrid particles with diverse and irregular shapes, such as pollen, as efficient cargo carriers, local electroporation and targeted drug delivery. [ABSTRACT FROM AUTHOR]

Published

2021

21. Active particles as mobile microelectrodes for selective bacteria electroporation and transport.

Author

Yue Wu, Afu Fu, and Yossifon, Gilad

Subjects

*ELECTROPORATION, *MICROELECTRODES, *ELECTRIC double layer, *DEBYE-Huckel theory, *RELATIVE motion

Abstract

The article presents a study on active particles as mobile microelectrodes for selective bacteria electroporation and transport. Topics discussed include self-propelling micromotors are emerging as a promising micro- and nanoscale tool for single-cell analysis necessary to manipulate matter via dielectrophoresis can be induced at the surface of a polarizable active metallodielectric Janus particle; and important and novel experimental tool for single-cell analysis and targeted delivery.

Published

2020

22. Induced-charge electrokinetics, bipolar current, and concentration polarization in a microchannel-Nafion-membrane system.

Author

Sinwook Park and Yossifon, Gilad

Subjects

*ELECTROKINETICS, *BIPOLAR transistor circuits, *POLARIZATION (Electricity), *NAFION, *ARTIFICIAL membranes, *ELECTRODES

Abstract

The presence of a floating electrode array located within the depletion layer formed due to concentration polarization across a microchannel-membrane interface device may produce not only induced-charge electro-osmosis (ICEO) but also bipolar current resulting from the induced Faradaic reaction. It has been shown that there exists an optimal thickness of a thin dielectric coating that is sufficient to suppress bipolar currents but still enables ICEO vortices that stir the depletion layer, thereby affecting the system's current-voltage response. In addition, the use of alternating-current electro-osmosis by activating electrodes results in further enhancement of the fluid stirring and opens new routes for on-demand spatiotemporal control of the depletion layer length. [ABSTRACT FROM AUTHOR]

Published

2016

23. Erratum: Dynamical trapping of colloids at the stagnation points of electro-osmotic vortices of the second kind [Phys. Rev. E 87,033005 (2013)].

Author

Green, Yoav and Yossifon, Gilad

Subjects

*COLLOIDS, *STAGNATION point

Abstract

A correction to the article "Dynamical trapping of colloids at the stagnation points of electro-osmotic vortices of the second kind" that was published in a 2013 issue is presented.

Published

2013

24. A Magnetically and Electrically Powered Hybrid Micromotor in Conductive Solutions: Synergistic Propulsion Effects and Label-Free Cargo Transport and Sensing.

Author

Wu, Yue, Yakov, Sivan, Fu, Afu, and Yossifon, Gilad

Subjects

*HYBRID power, *LIPOSOMES, *FREIGHT & freightage, *HOPPING conduction

Abstract

Electrically powered micro- and nanomotors are promising tools for in vitro single-cell analysis. In particular, single cells can be trapped, transported, and electroporated by a Janus particle (JP) using an externally applied electric field. However, while dielectrophoretic (DEP)-based cargo manipulation can be achieved at high-solution conductivity, electrical propulsion of these micromotors becomes ineffective at solution conductivities exceeding "0.3 mS cm-1. Here, JP cargo manipulation and transport capabilities to conductive near-physiological (<6 mS cm-1) solutions are extended successfully by combining magnetic field-based micromotor propulsion and navigation with DEP-based manipulation of various synthetic and biological cargos. Combination of a rotating magnetic field and electric field results in enhanced micromotor mobility and steering control through tuning of the electric field frequency. In addition, the micromotor's ability of identifying apoptotic cell among viable and necrotic cells based on their dielectrophoretic difference is demonstrated, thus, enabling to analyze the apoptotic status in the single-cell samples for drug discovery, cell therapeutics, and immunotherapy. The ability to trap and transport live cells towards regions containing doxorubicin-loaded liposomes is also demonstrated. This hybrid micromotor approach for label-free trapping, transporting, and sensing of selected cells within conductive solutions opens new opportunities in drug delivery and single-cell analysis, where close-to-physiological media conditions are necessary. [ABSTRACT FROM AUTHOR]

Published

2023

25. Micromotor-mediated label-free cargo manipulation.

Author

Wu, Yue, Boymelgreen, Alicia, and Yossifon, Gilad

Subjects

*FREIGHT & freightage, *SMART structures, *ENVIRONMENTAL remediation, *MICROMOTORS

Abstract

Efficient and flexible cargo manipulation at the micro/nanoscale is key to the realization of an array of applications ranging from drug delivery, directed self-assembly, and environmental remediation to self-repair. In this review, we highlight recent advances in the label-free manipulation of cargo by microscale carriers, commonly referred to as "micromotors" Label-free manipulation eliminates the need for tagging of cargo, enabling on-demand dynamic selectivity. Primary mechanisms include electrical, optical, hydrodynamical, and mechanical forcing. For the carrier, both self-propelling active particles moving in a uniform field and smart passive structures moving in a field gradient are considered with the caveat that cargo manipulation is "micromotor-mediated," i.e., cargo is not manipulated directly by the applied fields but only through its interaction with the carrier. We compare the manipulation techniques in terms of selectivity, cargo size, material, and suspending medium. We conclude by summarizing the existing challenges and future prospects. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

26. Asymmetry-induced electric current rectification in permselective systems.

Author

Green, Yoav, Edri, Yaron, and Yossifon, Gilad

Subjects

*ELECTRIC fields, *ELECTRIC current rectifiers, *ION-permeable membranes, *ELECTRIC potential, *CURRENT-voltage characteristics

Abstract

For a symmetric ion permselective system, in terms of geometry and bulk concentrations, the system response is also symmetric under opposite electric field polarity. In this work we derive an analytical solution for the concentration distribution, electric potential, and current-voltage response for a four-layered system comprised of two microchambers connected by two permselective regions of varying properties. It is shown that any additional asymmetry in the system, in terms of the geometry, bulk concentration, or surface charge property of the permselective regions, results in current rectification. Our work is divided into two parts: when both permselective regions have the same surface charge sign and the case of opposite signs. For the same sign case we are able to show that the system behaves as a dialytic battery while accounting for field-focusing effects. For the case of opposite signs (i.e., bipolar membrane), our system exhibits the behavior of a bipolar diode where the magnitude of the rectification can be of order 102-103. [ABSTRACT FROM AUTHOR]

Published

2015

27. Extended space charge near nonideally selective membranes and nanochannels.

Author

Schiffbauer, Jarrod, Leibowitz, Neta, and Yossifon, Gilad

Subjects

*INTERFACE circuits, *SPACE charge, *ELECTRODIFFUSION, *ELECTROLYTES, *MICROCHANNEL flow, *CURRENT-voltage curves, *ELECTRIC resistance

Abstract

We demonstrate the role of selectivity variation in the structure of the nonequilibrium extended space charge using one-dimensional analytic and two-dimensional numerical Poisson-Nernst-Planck models for the electro-diffusive transport of a symmetric electrolyte. This provides a deeper understanding of the underlying mechanism behind a previously observed maximum in the resistance-voltage curve for a shallow micro-nanochannel interface device [Schiffbauer, Liel, Leibowitz, Park, and Yossifon, arXiv:1409.4548, Phys. Rev. E (to be published)]. The current study helps to establish a connection between parameters such as the geometry and nanochannel surface charge and the control of selectivity and resistance in the overlimiting current regime. [ABSTRACT FROM AUTHOR]

Published

2015

28. The influence of flow intensity and field frequency on continuous-flow dielectrophoretic trapping.

Author

Ben-Bassat, Dana, Boymelgreen, Alicia, and Yossifon, Gilad

Subjects

*DIELECTROPHORESIS, *MICROFLUIDICS, *NUMERICAL analysis, *ELECTRO-osmosis, *EQUATIONS of motion

Abstract

We examine the combined influence of the intensity of pressure driven background flow and the frequency of the applied field on the continuous-flow dielectrophoretic trapping behavior of micro-particles within a micro-channel. Using an embedded interdigitated electrode array, we find that the measured trapping percentage over a continuous frequency range exhibits several curious effects which are strongly dependent on the flow intensity, including an apparent shift of the cross-over frequency and low-frequency dispersion. A numerical and theoretical model accounting for the combined effects of pressure-driven flow, dielectrophoresis and alternating-current electro-osmosis on the equation of motion for the particle is used to qualitatively describe the main experimental results. [ABSTRACT FROM AUTHOR]

Published

2015

29. Bridging the gap between an isolated nanochannel and a communicating multipore heterogeneous membrane.

Author

Green, Yoav, Park, Sinwook, and Yossifon, Gilad

Subjects

*ARTIFICIAL membranes, *DIFFUSION, *SPACE charge, *ELECTRODIFFUSION, *TELECOMMUNICATION

Abstract

To bridge the gap between single and isolated pore systems to multipore systems, such as membranes and electrodes, we studied an array of nanochannels with varying interchannel spacing that controlled the degree of channel communication. Instead of treating them as individual channels connected in parallel or an assembly like a homogeneous membrane, this study resolves the pore-pore interaction. We found that increased channel isolation leads to current intensification, whereas at high voltages electroconvective effects control the degree of communication via suppression of the diffusion layer growth. [ABSTRACT FROM AUTHOR]

Published

2015

30. Effect of geometry on concentration polarization in realistic heterogeneous permselective systems.

Author

Green, Yoav, Shloush, Shahar, and Yossifon, Gilad

Subjects

*INHOMOGENEOUS materials, *ION-permeable membranes, *COMPUTER simulation, *RECTIFICATION (Electricity), *ELECTRIC admittance, *POLARIZATION (Electricity)

Abstract

This study extends previous analytical solutions of concentration polarization occurring solely in the depleted region, to the more realistic geometry consisting of a three-dimensional (3D) heterogeneous ion-permselective medium connecting two opposite microchambers (i.e., a three-layer system). Under the local electroneutrality approximation, the separation of variable methods is used to derive an analytical solution of the electrodiffusive problem for the two opposing asymmetric microchambers. The assumption of an ideal permselective medium allows for the analytic calculation of the 3D concentration and electric potential distributions as well as a current-voltage relation. It is shown that any asymmetry in the microchamber geometries will result in current rectification. Moreover, it is demonstrated that for non-negligible microchamber resistances, the conductance does not exhibit the expected saturation at low concentrations but instead shows a continuous decrease. The results are intended to facilitate a more direct comparison between theory and experiments, as now the voltage drop is across a realistic 3D and three-layer system. [ABSTRACT FROM AUTHOR]

Published

2014

31. Individually addressable multi-chamber electroporation platform with dielectrophoresis and alternating-current-electro-osmosis assisted cell positioning.

Author

Sinwook Park, Bassat, Dana Ben, and Yossifon, Gilad

Subjects

*ELECTROPORATION, *DIELECTROPHORESIS, *ALTERNATING currents, *ELECTRO-osmosis, *FLUORESCENT proteins, *UMBILICAL veins, *ENDOTHELIAL cells

Abstract

A multi-functional microfluidic platform was fabricated to demonstrate the feasibility of on-chip electroporation integrated with dielectrophoresis (DEP) and alternating-current-electro-osmosis (ACEO) assisted cell/particle manipulation. A spatial gradient of electroporation parameters was generated within a microchamber array and validated using normal human dermal fibroblast (NHDF) cells and red fluorescent protein-expressing human umbilical vein endothelial cells (RFP-HUVECs) with various fluorescent indicators. The edge of the bottom electrode, coinciding with the microchamber entrance, may act as an on-demand gate, functioning under either positive or negative DEP. In addition, at sufficiently low activation frequencies, ACEO vortices can complement the DEP to contribute to a rapid trapping/alignment of particles. As such, results clearly indicate that the microfluidic platform has the potential to achieve high-throughput screening for electroporation with spatial control and uniformity, assisted by DEP and ACEO manipulation/trapping of particles/cells into individual microchambers. [ABSTRACT FROM AUTHOR]

Published

2014

32. Concentration dependence of nanochannel impedance and the determination of surface charge.

Author

Schiffbauer, Jarrod, Liel, Uri, and Yossifon, Gilad

Subjects

*SURFACE charges, *ELECTROLYTES, *BULK solids, *CHARGE density waves, *ELECTRIC admittance, *DIRECT currents

Abstract

In this paper, we demonstrate the variation of nanochannel impedance with bulk (reservoir) electrolyte concentration. The impedance of a nanochannel is shown to correspond to a characteristic deformed semicircular arc. The degree of deformation decreases with increasing concentration, and at a sufficiently low concentration the complex impedance saturates, becoming essentially independent of the reservoir concentration. This behavior is indicative of a surface-conduction dominant regime. Here we demonstrate that this effect extends beyond dc conductance and affects the ac response of the system as well, including both phase relationship and magnitude. The nanochannel resistance, obtained from low-voltage ac measurements, is then used to extract the nanochannel surface charge density. This is found to increase in magnitude with increasing electrolyte concentration. [ABSTRACT FROM AUTHOR]

Published

2014

33. Electrical Impedance Spectroscopy of Microchannel-Nanochannel Interface Devices.

Author

Schiffbauer, Jarrod, Park, Sinwook, and Yossifon, Gilad

Subjects

*IMPEDANCE spectroscopy, *ELECTROKINETICS, *PHOTOLITHOGRAPHY, *MICROCHANNEL flow, *FLUIDIC devices

Abstract

We report experimental verification of the depression of the slope in the Warburg branch of the electrochemical impedance spectrum using a fabricated microchannel-nanochannel device. This was previously theoretically predicted to occur with increasing dc bias voltage as a result of nanochannel electro-osmotic flow and provides an example of the influence of net fluid flow on electrokinetic transport. The dominant influence of nanochannel polarization in the kHz range of the impedance response is also demonstrated experimentally. This latter effect may be significant in both fundamental electrokinetics of micronanochannel devices as well as in practical molecular sensing applications. [ABSTRACT FROM AUTHOR]

Published

2013

34. Digital microfluidics-like manipulation of electrokinetically preconcentrated bioparticle plugs in continuous-flow.

Author

Park, Sinwook, Sabbagh, Barak, Abu-Rjal, Ramadan, and Yossifon, Gilad

Subjects

*MICROFLUIDICS, *ELECTROKINETICS, *INLETS, *ELECTRODES

Abstract

Herein, we demonstrate digital microfluidics-like manipulations of preconcentrated biomolecule plugs within a continuous flow that is different from the commonly known digital microfluidics involving discrete (i.e. droplets) media. This is realized using one- and two-dimensional arrays of individually addressable ion-permselective membranes with interconnecting microfluidic channels. The location of powered electrodes, dictates which of the membranes are active and generates either enrichment/depletion diffusion layers, which, in turn, control the location of the preconcentrated plug. An array of such powered membranes enables formation of multiple preconcentrated plugs of the same biosample as well as of preconcentrated plugs of multiple biosample types introduced via different inlets in a selective manner. Moreover, digital-microfluidics operations such as up-down and left–right translation, merging, and splitting, can be realized, but on preconcentrated biomolecule plugs instead of on discrete droplets. This technology, based on nanoscale electrokinetics of ion transport through permselective medium, opens future opportunities for smart and programmable digital-like manipulations of preconcentrated biological particle plugs for various on-chip biological applications. [ABSTRACT FROM AUTHOR]

Published

2022

35. Ion current rectification in funnel-shaped nanochannels: Hysteresis and inversion effects.

Author

Rosentsvit, Leon, Wei Wang, Schiffbauer, Jarrod, Hsueh-Chia Chang, and Yossifon, Gilad

Subjects

*HYSTERESIS, *THRESHOLD voltage, *ELECTRIC currents, *NANOPORES, *POLARIZATION (Electricity)

Abstract

Ion current rectification inversion is observed in a funnel-shaped nanochannel above a threshold voltage roughly corresponding to the under-limiting to over-limiting current transition. Previous experimental studies have examined rectification at either low-voltages (under-limiting current region) for conical nanopores/funnel-shaped nanochannels or at high-voltages (over-limiting region) for straight nanochannels with asymmetric entrances or asymmetric interfacing microchannels. The observed rectification inversion occurs because the system resistance is shifted, beyond a threshold voltage, from being controlled by intra-channel ion concentration-polarization to that controlled by external concentration-polarization. Additionally, strong hysteresis effects, due to residual concentration-polarization, manifest themselves through the dependence of the transient current rectification on voltage scan rate. [ABSTRACT FROM AUTHOR]

Published

2015

36. Supercolloidal Spinners: Complex Active Particles for Electrically Powered and Switchable Rotation.

Author

Shields, IV, Charles Wyatt, Han, Koohee, Ma, Fuduo, Miloh, Touvia, Yossifon, Gilad, and Velev, Orlin D.

Subjects

*ELECTRIC fields, *SUPERCOLLIDERS, *PARTICLES, *ELECTRICAL energy, *ENERGY conversion

Abstract

Abstract: A class of supercolloidal particles that controllably spin about their central axis in AC electric fields is reported. The rational design of these “microspinners” enables their rotation in a switchable manner, which gives rise to several interesting and programmable behaviors. It is shown that due to their complex shape and discrete metallic patches on their surfaces, these microspinners convert electrical energy into active motion via the interplay of four mechanisms at different electric field frequency ranges. These mechanisms of rotation include (in order of increasing frequency): electrohydrodynamic flows, reversed electrohydrodynamic flows, induced charge electrophoresis, and self‐dielectrophoresis. As the primary mechanism powering their motion transitions from one phenomenon to the next, these microspinners display three directional spin inversions (i.e., from clockwise to anticlockwise, or vice versa). To understand the mechanisms involved, this experimental study is coupled with scaling analyses. Due to their frequency‐switchable rotation, these microspinners have potential for applications such as interlocking gears in colloidal micromachines. Moreover, the principles used to power their switchable motion can be extended to design other types of supercolloidal particles that harvest electrical energy for motion via multiple electrokinetic mechanisms. [ABSTRACT FROM AUTHOR]

Published

2018

37. Effect of advection on transient ion concentration-polarization phenomenon.

Author

Rosentsvit, Leon, Park, Sinwook, and Yossifon, Gilad

Subjects

*FLUORESCENT dyes, *IONS, *MICROCHANNEL flow

Abstract

Here, we studied the effect of advection on the transient ion concentration-polarization phenomenon in microchannel-membrane systems. Specifically, the temporal evolution of the depletion layer in a system that supports net flow rates with varying Péclet values was examined. Experiments complemented with simplified analytical one-dimensional semi-infinite modeling and numerical simulations demonstrated either suppression or enhancement of the depletion layer propagation against or with the direction of the net flow, respectively. Of particular interest was the third-species fluorescent dye ion concentration-polarization dynamics which was further explained using two-dimensional numerical simulations that accounted for the device complex geometry. [ABSTRACT FROM AUTHOR]

Published

2017

38. Myxozoan polar tubules display structural and functional variation.

Author

Ben-David, Jonathan, Atkinson, Stephen D., Pollak, Yulia, Yossifon, Gilad, Shavit, Uri, Bartholomew, Jerri L., and Lotan, Tamar

Subjects

*MYXOZOA, *INVERTEBRATES, *CNIDARIA, *MYXOSPOREA, *EURYSPORINA

Abstract

Background: Myxozoa is a speciose group of endoparasitic cnidarians that can cause severe ecological and economic effects. Although highly reduced compared to free-living cnidarians, myxozoans have retained the phylum-defining stinging organelles, known as cnidae or polar capsules, which are essential to initiating host infection. To explore the adaptations of myxozoan polar capsules, we compared the structure, firing process and content release mechanism of polar tubules in myxospores of three Myxobolus species including M. cerebralis, the causative agent of whirling disease. Results: We found novel functions and morphologies in myxozoan polar tubules. High-speed video analysis of the firing process of capsules from the three Myxobolus species showed that all polar tubules rapidly extended and then contracted, an elasticity phenomenon that is unknown in free-living cnidarians. Interestingly, the duration of the tubule release differed among the three species by more than two orders of magnitude, ranging from 0.35 to 10 s. By dye-labeling the polar capsules prior to firing, we discovered that two of the species could release their entire capsule content, a delivery process not previously known from myxozoans. Having the role of content delivery and not simply anchoring suggests that cytotoxic or proteolytic compounds may be present in the capsule. Moreover, while free-living cnidarians inject most of the toxic content through the distal tip of the tubule, our video and ultrastructure analyses of the myxozoan tubules revealed patterns of double spirals of nodules and pores along parts of the tubules, and showed that the distal tip of the tubules was sealed. This helical pattern and distribution of openings may minimize the tubule mechanical weakness and improve resistance to the stress impose by firing. The finding that myxozoan tubule characteristics are very different from those of free-living cnidarians is suggestive of their adaptation to parasitic life. Conclusions: These findings show that myxozoan polar tubules have more functions than previously assumed, and provide insight into their evolution from free-living ancestors. [ABSTRACT FROM AUTHOR]

Published

2016

39. Temperature and high pressure effects on choked flow in the microchannel.

Author

Parahovnik, Anatoly, Fraiman, Leonid, Rosinsky, Israel, and Yossifon, Gilad

Subjects

*CHOKED flow (Fluid dynamics), *TEMPERATURE effect, *COMPUTER simulation, *GAS flow, *MICROCHANNEL flow, *HIGH pressure (Technology)

Abstract

We studied the choked flow behavior of gas flow in a single microchannel at inlet pressures of up to 2.2 MPa. Fair agreement was obtained between the basic compressible flow theory, known as Fanno flow, numerical simulations, and experiments for the mass flow rate dependency on the inlet pressure. Investigation of the effect of varying the inlet temperature on the choked flow behavior revealed that the power law scaling of the maximum flow rate on the temperature varies with inlet pressure. This was suggested, using numerical simulations, to be a result of heat loss to the environment. [ABSTRACT FROM AUTHOR]

Published

2016

40. Investigation of the cooling enhancement of a single crystal diamond heat sink with embedded microfluidic channels.

Author

Fu, Jiao, Hoffman, Alon, Kuntumalla, Mohan Kumar, Wang, Hong-xing, Chen, Daming, Mosyak, Albert, and Yossifon, Gilad

Subjects

*DIAMOND crystals, *SINGLE crystals, *HEAT sinks, *HEAT convection, *MICROFLUIDIC devices, *HEAT flux, *FLUX flow, *HEAT transfer, *ELECTRICAL load

Abstract

Single crystal diamond (SCD) owns superior mechanical strength, chemical stability, and the highest thermal conductivity among the well-known materials. In this work, we investigated the cooling enhancement of a cold plate made of SCD with embedded microfluidic channels. In particular, we studied the enhanced heat spreading due to conduction followed by convective dissipation of a locally heated resistor mimicking a linear hot spot within electronic chips. Experiments were carried out with various heat fluxes (9–75 W/cm2) and volumetric flow rates (0.02–0.18 ml/min) under transient state. The results showed that cold plate made of a SCD layer with embedded microfluidic channels exhibited the highest cooling effect obtained for maximum applied power density and flow rate. This indicated that combined effect of conductive spreading and convective heat transfer exhibited a significant cooling enhancement. Simulation results further support the improvement of the cooling capability due to the addition of microfluidic channels and the use of SCD as the substrate of the heat sink. [Display omitted] • Single crystal diamond embedded with microchannels (SCD-MC) was fabricated and tested. • A maximum temperature was decreased by 42.1 % when using SCD-MC instead of Silicon. • The cooling enhancement of SCD-MC increased with heat flux and volumetric flow rate. [ABSTRACT FROM AUTHOR]

Published

2022

41. Probing space charge and resolving overlimiting current mechanisms at the microchannel-nanochannel interface.

Author

Schiffbauer, Jarrod, Liel, Uri, Leibowitz, Neta, Park, Sinwook, and Yossifon, Gilad

Subjects

*INTERFACE circuits, *SPACE charge, *MICROCHANNEL flow, *ELECTRIC resistance, *HIGH voltages, *IMPEDANCE spectroscopy, *ELECTRIC currents

Abstract

We present results demonstrating the space charge-mediated transition between classical, diffusion-limited current and surface-conduction dominant over-limiting current in a shallow microchannel-nanochannel device. The extended space charge layer develops at the depleted microchannel-nanochannel entrance at high current and is correlated with a distinctive maximum in the dc resistance. Experimental results for a shallow surface-conduction dominated system are compared with theoretical models, allowing estimates of the effective surface charge at high voltage to be obtained. In comparison to an equilibrium estimate of the surface charge obtained from electrochemical impedance spectroscopy, it is further observed that the effective surface charge appears to change under applied voltage. [ABSTRACT FROM AUTHOR]

Published

2015

42. Synthetic electrically driven colloids: A platform for understanding collective behavior in soft matter.

Author

Boymelgreen, Alicia, Schiffbauer, Jarrod, Khusid, Boris, and Yossifon, Gilad

Subjects

*COLLECTIVE behavior, *NONEQUILIBRIUM statistical mechanics

Abstract

The collective motion of synthetic active colloids is an emerging area of research in soft matter physics and is important both as a platform for fundamental studies ranging from non-equilibrium statistical mechanics to the basic principles of self-organization, emergent phenomena, and assembly underlying life, as well as applications in biomedicine and metamaterials. The potentially transformative nature of the field over the next decade and beyond is a topic of critical research importance. Electrokinetic active colloids represent an extremely flexible platform for the investigation and modulation of collective behavior in active matter. Here, we review progress in the past five years in electrokinetic active systems and related topics in active matter with important fundamental research and applicative potential to be investigated using electrokinetic systems. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

43. AC electrohydrodynamic propulsion and rotation of active particles of engineered shape and asymmetry.

Author

Diwakar, Nidhi M., Kunti, Golak, Miloh, Touvia, Yossifon, Gilad, and Velev, Orlin D.

Subjects

*COLLECTIVE behavior, *ROTATIONAL motion, *PARTICLE motion

Abstract

This review presents the recent progress in the development of active particles driven by alternating-current (AC) electrokinetic effects. These particles propel by asymmetrically dissipating the external energy provided by the fields. An AC field can trigger several electrohydrodynamic mechanisms depending on the field frequency and amplitude, which can also control particle–particle interactions and collective behavior. Recently there has been a strong focus on powering and controlling the motion of self-propelling particles with engineered shape, size, and composition. We introduce a tiered classification of AC field-driven active particles and discuss the fundamental electrohydrodynamic effects acting in individual and multi-particle systems. Finally, we address the limitations and challenges in the current state of AC-field driven engineered particles. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

44. Transient response of nonideal ion-selective microchannel-nanochannel devices.

Author

Leibowitz, Neta, Schiffbauer, Jarrod, Park, Sinwook, and Yossifon, Gilad

Subjects

*ELECTRODIFFUSION, *TRANSIENTS (Dynamics), *CHRONOAMPEROMETRY

Abstract

We report evidence of variation in ion selectivity of a fabricated microchannel-nanochannel device resulting in the appearance of a distinct local maximum in the overlimiting chronopotentiometric response. In this system consisting of shallow microchannels joined by a nanochannel, viscous shear at the microchannel walls suppresses the electro-osmotic instability and prevents any associated contribution to the nonmonotonic response. Thus, this response is primarily electrodiffusive. Numerical simulations indicate that concentration polarization develops not only within the microchannel but also within the nanochannel itself, with a local voltage maximum in the chronopotentiometric response correlated with interfacial depletion and having the classic i-2 Sands time dependence. Furthermore, the occurrence of the local maxima is correlated with the change in selectivity due to internal concentration polarization. Understanding the transient nonideal permselective response is essential for obtaining fundamental insight and for optimizing efficient operation of practical fabricated nanofluidic and membrane devices. [ABSTRACT FROM AUTHOR]

Published

2018

45. Robust ion current oscillations under a steady electric field: An ion channel analog.

Author

Yu Yan, Yunshan Wang, Senapati, Satyajyoti, Schiffbauer, Jarrod, Yossifon, Gilad, and Hsueh-Chia Chang

Subjects

*ION channels, *ELECTRIC fields, *NONLINEAR theories, *POROUS materials, *HYSTERESIS

Abstract

We demonstrate a nonlinear, nonequilibrium field-driven ion flux phenomenon, which unlike Teorell's nonlinear multiple field theory, requires only the application of one field: robust autonomous current-mass flux oscillations across a porous monolith coupled to a capillary with a long air bubble, which mimics a hydrophobic protein in an ion channel. The oscillations are driven by the hysteretic wetting dynamics of the meniscus when electro-osmotic flow and pressure driven backflow, due to bubble expansion, compete to approach zero mass flux within the monolith. Delayed rupture of the film around the advancing bubble cuts off the electric field and switches the monolith mass flow from the former to the latter. The meniscus then recedes and repairs the rupture to sustain an oscillation for a range of applied fields. This generic mechanism shares many analogs with current oscillations in cell membrane ion channel. At sufficiently high voltage, the system undergoes a state transition characterized by appearance of the ubiquitous 1/f power spectrum. [ABSTRACT FROM AUTHOR]

Published

2016