Electrohydrodynamic Flow and Colloidal Patterning near Inhomogeneities on Electrodes

Ristenpart, William D.; Jiang, Peng; Słowik, Marta; Punckt, Christian; Saville, D. A.; Aksay, İlhan A.

doi:10.1021/la801419k

Cited by 44 publications

(43 citation statements)

References 29 publications

(41 reference statements)

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“…Previous investigations have shown that colloidal patterning can occur on the surface of planar ITO due to inhomogeneous current densities when the ITO film is altered physically 20 or with applied ultraviolet illumination. 16 For our experiments, nanoparticle aggregation occurred not only on the surface of ITO, but on gold as well.…”

Section: Image Acquisition and Analysismentioning

confidence: 99%

A simple, optically induced electrokinetic method to concentrate and pattern nanoparticles

et al. 2009

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We demonstrate an optically induced electrokinetic technique that continuously concentrates nanoparticles on the surface of a parallel plate electrode that is biased with an AC signal. A highly focused beam of near-infrared light (1064 nm) was applied, inducing an electrothermal microfluidic vortex that carried nanoparticles to its center where they were accumulated. This technique was demonstrated with 49 nm and 100 nm fluorescent polystyrene particles and characterized as a function of applied AC frequency and voltage. With this technique the location and shape of colloidal concentration was reconfigured by controlling the optical landscape, yielding dynamic control of the aggregation. Colloidal concentration was demonstrated with a plain parallel plate electrode configuration without the need of photoconductive materials or complex microfabrication procedures.

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Section: Image Acquisition and Analysismentioning

confidence: 99%

A simple, optically induced electrokinetic method to concentrate and pattern nanoparticles

et al. 2009

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“…EHD flow, a second mechanism, is one form of fluid flow that is induced by the mutual attraction which an applied electric field exerts on ions in a fluid. According to studies by Fagan et al and Green et al, the flow affects the motion of particles on an electrode surface in an AC frequency region above 500 Hz [119][120][121][122][123][124][125][126]. It gathers the particles laterally, lifting them up slightly from the electrode surface.…”

Section: Opto-electrokinetic Physics Of Repmentioning

confidence: 99%

Microfluidic Technology for Cell Manipulation

Kwon

2018

Applied Sciences

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Featured Application: Microfluidic manipulation techniques not only improve the efficiency and reliability of biological/clinical analysis, but also further enable the development of a high-performance bioassay system. Abstract: Microfluidic techniques for cell manipulation have been constantly developed and integrated into small chips for high-performance bioassays. However, the drawbacks of each of the techniques often hindered their further advancement and their wide use in biotechnology. To overcome this difficulty, an examination and understanding of various aspects of the developed manipulation techniques are required. In this review, we provide the details of primary microfluidic techniques that have received much attention for bioassays. First, we introduce the manipulation techniques using a sole driving source, i.e., dielectrophoresis, electrophoresis, optical tweezers, magnetophoresis, and acoustophoresis. Next, we present rapid electrokinetic patterning, a hybrid opto-electric manipulation technique developed recently. It is introduced in detail along with the underlying physical principle, operating environment, and current challenges. This paper will offer readers the opportunity to improve existing manipulation techniques, suggest new manipulation techniques, and find new applications in biotechnology.

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“…Of course, since the first demonstration of self healing behaviour via the liquid healing agent route, alternative routes have been identified to induce self healing behaviour such as elastic recovery in combination with reversible physical networks as employed in ionomers ], reversible hydrogen and other chemical bonds as employed in supra molecular materials [Sijbesma et al 1997], crack jamming by transport of particles under the influence of an electrical field [Ristenpart 2008], long distance reptation of dissolved linear molecules in a thermoset matrix [Hayes 2007], atomistic diffusion followed by local formation of strengthening precipitates in aluminium alloys [Lumley 2003], local oxidation of the crack zone leading to the formation of new phases with a higher specific volume as in a very special high temperature ceramic [Song et al 2008] volumetric expansion of a nanostructure clay micro-layer to fill cracks in a multilayered coating [Micciche 2008, Hikasa 2004, and finally local deposits in the crack surface of bio-concrete grades due to bacterial excrements . In all the above examples the matrix is the more rigid phase and the healing agent is the mobile, i.e.…”

Section: Introductionmentioning

confidence: 99%

Self‐Healing in Nanoparticle‐Reinforced Polymers and other Polymer Systems

Picken

Mookhoek

Fischer

et al. 2010

Optimization of Polymer Nanocomposite Properties

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This chapter aims at combining new insights in the field of (liquid encapsulated) self healing polymer systems as well as nanoparticle reinforced polymers to set the direction for the development of nanoparticle reinforced self healing polymers. In the case of self healing polymers the strategy is to minimise the volume fraction encapsulated healing agent for a desired healing performance. In the case of nanoparticle reinforced polymers the challenge is to maximise the mechanical property improvement for a certain fraction of nanoparticles.For both systems the property to be optimised, i.e. the healing potential or the strengthening effect, is mathematically shown to depend on the aspect ratio of the added ingredient as well as its volume fraction. The chapter ends with a first exploration of the use of nanoparticle reinforcement to get attractive repetitive self healing behaviour in a polymer system still meeting minimal mechanical properties.

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Electrohydrodynamic Flow and Colloidal Patterning near Inhomogeneities on Electrodes

Cited by 44 publications

References 29 publications

A simple, optically induced electrokinetic method to concentrate and pattern nanoparticles

A simple, optically induced electrokinetic method to concentrate and pattern nanoparticles

Microfluidic Technology for Cell Manipulation

Self‐Healing in Nanoparticle‐Reinforced Polymers and other Polymer Systems

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