Three-Dimensional Arrangements of Polystyrene Latex Particles with a Hyperbolic Quadruple Electrode System

Abstract: An attempt was made to arrange polystyrene latex particles (2, 5, and 10 microm in diameter) dispersed in aqueous media making use of their dielectrophoresis and electrophoresis with a hyperbolic quadruple electrode system. Application of a high-frequency ac field enabled the particles to arrange themselves between the electrodes forming a particle monolayer due to the negative dielectrophoretic force. Simultaneous application of high-frequency ac and dc fields caused the particles to gather in the region surr… Show more

“…Negative DEP force at high frequency in hyperbolic quadrupolar electrodes with a non-uniform gap enforced the concentration of microspheres, thus allowing colloidal crystal domains at the center of the electrodes [41]. In our study, similar experiments were conducted using hexapolarshaped electrodes embedded in a microfluidic chamber, as shown in Fig.…”

“…Recently, dielectrophoretic assembly of colloidal microspheres has been reported as a rapid and convenient method to construct 2D colloidal crystals [10,36,41]. Negative DEP force at high frequency in hyperbolic quadrupolar electrodes with a non-uniform gap enforced the concentration of microspheres, thus allowing colloidal crystal domains at the center of the electrodes [41].…”

“…This is based on the polarizability difference between metallic and semiconducting-type carbon nanotubes. Construction of 2D or 3D photonic crystals is another promising application of the DEP technique [36,41]. A quadrupolar type of electrode in conjunction with the DEP technique was suggested to be an efficient way to fabricate 2D opaline arrays [41,42].…”

“…Construction of 2D or 3D photonic crystals is another promising application of the DEP technique [36,41]. A quadrupolar type of electrode in conjunction with the DEP technique was suggested to be an efficient way to fabricate 2D opaline arrays [41,42]. The negative DEP force acting on the non-parallel shaped channel between neighboring electrodes induces particle concentration at the center of four electrodes, allowing a colloidal crystalline structure.…”

Dielectrophoretic assembly of grain-boundary-free 2D colloidal single crystals

“…Negative DEP force at high frequency in hyperbolic quadrupolar electrodes with a non-uniform gap enforced the concentration of microspheres, thus allowing colloidal crystal domains at the center of the electrodes [41]. In our study, similar experiments were conducted using hexapolarshaped electrodes embedded in a microfluidic chamber, as shown in Fig.…”

“…Recently, dielectrophoretic assembly of colloidal microspheres has been reported as a rapid and convenient method to construct 2D colloidal crystals [10,36,41]. Negative DEP force at high frequency in hyperbolic quadrupolar electrodes with a non-uniform gap enforced the concentration of microspheres, thus allowing colloidal crystal domains at the center of the electrodes [41].…”

“…This is based on the polarizability difference between metallic and semiconducting-type carbon nanotubes. Construction of 2D or 3D photonic crystals is another promising application of the DEP technique [36,41]. A quadrupolar type of electrode in conjunction with the DEP technique was suggested to be an efficient way to fabricate 2D opaline arrays [41,42].…”

“…Construction of 2D or 3D photonic crystals is another promising application of the DEP technique [36,41]. A quadrupolar type of electrode in conjunction with the DEP technique was suggested to be an efficient way to fabricate 2D opaline arrays [41,42]. The negative DEP force acting on the non-parallel shaped channel between neighboring electrodes induces particle concentration at the center of four electrodes, allowing a colloidal crystalline structure.…”

Dielectrophoretic assembly of grain-boundary-free 2D colloidal single crystals

“…Due to its ability to handle cells or particles without any modification of them, it has become one of the most attractive manipulation techniques in a microfluidic device or a lab-on-a-chip. In recent studies, many research groups have revealed the dielectric properties of polystyrene microbeads (Abe et al 2004;Choi and Park 2005), DNA (Lao and Hsing 2005), bacteria (Li and Bashir 2002;Lagally et al 2005), yeast (Perch-Nielsen et al 2003;Doh and Cho 2005), leukocytes (Wang et al 2000), and erythrocytes (Minerick et al 2003). The dielectrophoretic force is described as follows:…”

Lab-on-a-display: a new microparticle manipulation platform using a liquid crystal display (LCD)

Electrokinetic Coupling in Colloidal Arrays Formed under AC Electric Fields