Patterned polydiacetylene-embedded polystyrene nanofibers based on electrohydrodynamic jet printing

Song, Chiho; Rogers, John A.; Kim, Jong Man; Ahn, Heejoon

doi:10.1007/s13233-015-3024-2

Cited by 29 publications

(22 citation statements)

References 45 publications

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“…When the collector speed is significantly reduced and the deposition rate is increased, repulsive forces arising from residual charge result in ejected droplet-fiber oscillation or buckling motion. However, when the stage speed is comparatively greater than the deposition rate, a straight linear fiber geometry is obtained [58]. While greater deposition precision, compared to ES, will give rise to the development of more ordered drug delivery dosage forms, other applications which rely on surface properties (e.g.…”

Section: Effect Of Collector Speed Applied Voltage and Working Distamentioning

confidence: 99%

Fabrication of patterned polymer-antibiotic composite fibers via electrohydrodynamic (EHD) printing

Wang

Chang

Ahmad

et al. 2016

Journal of Drug Delivery Science and Technology

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Section: Effect Of Collector Speed Applied Voltage and Working Distamentioning

confidence: 99%

Fabrication of patterned polymer-antibiotic composite fibers via electrohydrodynamic (EHD) printing

Wang

Chang

Ahmad

et al. 2016

Journal of Drug Delivery Science and Technology

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“…Once formed, the fibers can be collected and processed using external pumps, alternating applied electric fields, spinnerets, coagulation, and wash chambers, or heated drum rolls to form aligned functional materials . Several electrospinning techniques have been developed to further control fiber deposition and structure, producing aligned fibrous nanostructures by minimizing the distance between a charged nozzle and grounded collector . While these modifications enable geometries which were previously unattainable for electrospun fibers, the technique remains limited in both speed and the range of materials used.…”

Section: Introductionmentioning

confidence: 99%

Design and Fabrication of Fibrous Nanomaterials Using Pull Spinning

Deravi

Sinatra

Chantre

et al. 2017

Macro Materials & Eng

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catalysts, [11,12] and optical devices. [13][14][15] Such a broad scope of applications demands versatile manufacturing techniques amenable to multiple materials processing and collection conditions. Currently, fiber-fabrication systems can be characterized as melt, [16][17][18] dry, [19,20] wet, [21][22][23] or electrospinning [24,25] -all of which produce nanofibers using high temperature and pressure (melt, dry, and wet spinning) or electric fields (5-20 kV, electrospinning). [24][25][26][27] Once formed, the fibers can be collected and processed using external pumps, alternating applied electric fields, spinnerets, coagulation, and wash chambers, or heated drum rolls to form aligned functional materials. [18,[24][25][26]28,29] Several electrospinning techniques have been developed to further control fiber deposition and structure, producing aligned fibrous nanostructures by minimizing the distance between a charged nozzle and grounded collector. [30][31][32][33][34][35] While these modifications enable geometries which were previously unattainable for electrospun fibers, the technique remains limited in both speed and the range of materials used. Furthermore, harsh reaction environments, The assembly of natural and synthetic polymers into fibrous nanomaterials has applications ranging from textiles, tissue engineering, photonics, and catalysis. However, rapid manufacturing of these materials is challenging, as the state of the art in nanofiber assembly remains limited by factors such as solution polarity, production rate, applied electric fields, or temperature. Here, the design and development of a rapid nanofiber manufacturing system termed pull spinning is described. Pull spinning is compact and portable, consisting of a high-speed rotating bristle that dips into a polymer or protein reservoir and pulls a droplet from solution into a nanofiber. When multiple layers of nanofibers are collected, they form a nonwoven network whose composition, orientation, and function can be adapted to multiple applications. The capability of pull spinning to function as a rapid, point-of-use fiber manufacturing platform is demonstrated for both muscle tissue engineering and textile design.

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“…Their chemical structures, conjugation system, crystallinity, and chain packing orientation affect charge transport properties of the wires, and can be easily modified. [1][2][3][4][5][6][7][8][9][26][27][28][44][45][46][51][52][53][54] Many electronic applications based on large-scale OSC NWs have been developed and show possibilities as next-generation electronic devices. [4][5][6][7][8][9][26][27][28]46,[51][52][53][54] e-Nanowire printing has been used to produce highly aligned polymer NWs (Figure 2b), and to fabricate NW-based devices arrays over a large area.…”

Section: Semiconducting Nanowires For Electronic Devicesmentioning

confidence: 99%

Large‐Scale Highly Aligned Nanowire Printing

Lee

Min

Lee

2017

Macro Materials & Eng

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Nanowires (NWs) are 1D confined nanostructures; this geometry gives them unique properties that have been exploited in fabrication of high-density and high-tech electronic devices. Current method to produce NWs cannot fabricate largescale-aligned NW arrays with precise control of length, orientation, location, and number of NWs individually; these inabilities hinder application of NWs in practical electronics. This paper describes e-nanowire printing, a method to print highly aligned NWs on a large scale, and then reviews recent progress in various electronic applications with highly aligned NWs. Finally, future research is suggested to advance nanoelectronics.

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Patterned polydiacetylene-embedded polystyrene nanofibers based on electrohydrodynamic jet printing

Cited by 29 publications

References 45 publications

Fabrication of patterned polymer-antibiotic composite fibers via electrohydrodynamic (EHD) printing

Fabrication of patterned polymer-antibiotic composite fibers via electrohydrodynamic (EHD) printing

Design and Fabrication of Fibrous Nanomaterials Using Pull Spinning

Large‐Scale Highly Aligned Nanowire Printing

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