Correlation of and Facies Changes in the Carbonaceous, Calcareous, and Dolomitic Formations of the Precambrian Belt-Purcell Supergroup

Smith, Alan G.; Barnes, W. C.

doi:10.1130/0016-7606(1966)77[1399:coafci]2.0.co;2

Cited by 41 publications

(41 citation statements)

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“…8,10,[59][60][61][62][63][64][65][66][67][68][69] The applied electric fields can be used effectively to attract and align NWs normally by the dielectrophoresis forces, which are exerted on the dielectric NWs through the induced dipoles. 60,61 Up to now, various nanostructures, such as Au NWs, 60 Rh NWs, 9 Ag NWs, 65 Si NWs, 9 Se NWs, 65 axially modulated pn Si NWs, 67 InP NWs, 8 ZnO NWs, 62,64 CdSe NWs, 63 as well as polymer nanofibers 68 have been assembled by this approach. Fig.…”

Section: Assembly By Dielectrophoresis or Electric Fieldsmentioning

confidence: 99%

Recent advances in large-scale assembly of semiconducting inorganic nanowires and nanofibers for electronics, sensors and photovoltaics

et al. 2012

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Semiconducting inorganic nanowires (NWs), nanotubes and nanofibers have been extensively explored in recent years as potential building blocks for nanoscale electronics, optoelectronics, chemical/biological/ optical sensing, and energy harvesting, storage and conversion, etc. Besides the top-down approaches such as conventional lithography technologies, nanowires are commonly grown by the bottom-up approaches such as solution growth, template-guided synthesis, and vapor-liquid-solid process at a relatively low cost. Superior performance has been demonstrated using nanowires devices. However, most of the nanowire devices are limited to the demonstration of single devices, an initial step toward nanoelectronic circuits, not adequate for production on a large scale at low cost. Controlled and uniform assembly of nanowires with high scalability is still one of the major bottleneck challenges towards the materials and device integration for electronics. In this review, we aim to present recent progress toward nanowire device assembly technologies, including flow-assisted alignment, Langmuir-Blodgett assembly, bubble-blown technique, electric/magnetic-field-directed assembly, contact/roll printing, planar growth, bridging method, and electrospinning, etc. And their applications in high-performance, flexible electronics, sensors, photovoltaics, bioelectronic interfaces and nano-resonators are also presented.

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Section: Assembly By Dielectrophoresis or Electric Fieldsmentioning

confidence: 99%

Recent advances in large-scale assembly of semiconducting inorganic nanowires and nanofibers for electronics, sensors and photovoltaics

et al. 2012

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“…Among the most promising techniques for precise manipulation and positioning of micrometer or even submicrometer sized particles in these systems is the dielectrophoresis (DEP), i.e., the actuation of small particles (generally less than 10 −3 mi nd i a m e t e r )t h r o u g h the action of non-uniform electric fields [1]. Most convenient approaches to the nanoassembly by using DEP consist of bridging inorganic nanowires across electrode gaps [2][3][4][5] as well as by using the electrorotation mechanism [6] and combinations of electrophoretic and dielectrophoretic forces [7]. These techniques were already proposed or even proved to be useful in nanoelectronics for providing small connecting wires [8,9], plasmon-conducting fibers [8], or integrating DEP of metallic nanowires in biomolecular recognition [10].…”

Section: Introductionmentioning

confidence: 99%

Magnetically controlled dielectrophoresis of metallic colloids

Clime¹,

Veres²

2008

Journal of Colloid and Interface Science

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We present a finite-element/discrete-element numerical model for calculating full trajectories of cylindrical metallic colloids in liquid flows and subjected to non-uniform electric fields. The effect of the particle orientation relative to the liquid flow is investigated by considering barcode magnetic nanowires pinned in different directions by applying uniform magnetic fields. We compare the motion of free as well as vertically and horizontally pinned nanowires and demonstrate that their nanoassembly may accurately be tuned by magnetically controlling the orientation during the dielectrophoretic capture.

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“…Controlled assembly of colloidal crystals leads to interesting mechanical, 1,2 electrical, 3 and optical 4 properties. These colloidal systems have lattice spacings ranging from nanometer to micrometer scale, depending on the nature of material and method of preparation.…”

Section: Introductionmentioning

confidence: 99%

Electrically aligned binary system of nanoparticles

Pal

Basu

Chakravorty

2005

Journal of Applied Physics

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Articles you may be interested inEffects of size and interparticle interaction of silica nanoparticles on dispersion and electrical conductivity of silver/epoxy nanocomposites J. Appl. Phys. 115, 154307 (2014) Aligned arrays of binary nanoparticles of silver and silver oxide, respectively, with mean diameters of 8.5 nm have been prepared within a polymethylmethacrylate film. The alignment along an electric-field direction has been achieved by applying an electric field of ϳ10 V / mm at frequency ranging from 1 kHz to 1 MHz. This behavior has been explained as arising due to a dipole-dipole interaction between the metal and oxide nanoparticles, respectively. The electrical resistivity is shown to arise due to variable range hopping mechanism. These nanocomposites exhibit three orders of magnitude resistivity changes as the relative humidity is varied from 35% to 95%.

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Correlation of and Facies Changes in the Carbonaceous, Calcareous, and Dolomitic Formations of the Precambrian Belt-Purcell Supergroup

Cited by 41 publications

References 0 publications

Recent advances in large-scale assembly of semiconducting inorganic nanowires and nanofibers for electronics, sensors and photovoltaics

Recent advances in large-scale assembly of semiconducting inorganic nanowires and nanofibers for electronics, sensors and photovoltaics

Magnetically controlled dielectrophoresis of metallic colloids

Electrically aligned binary system of nanoparticles

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