Helix Electrohydrodynamic Printing of Highly Aligned Serpentine Micro/Nanofibers

Duan, Yongqing; Ding, Yajiang; Xu, Zhoulong; Yin, Zhouping

doi:10.3390/polym9090434

Cited by 39 publications

(33 citation statements)

References 38 publications

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“…demonstrated the development of hyperstretchable self‐powered piezoelectric nano/microfiber sensors with excellent mechanical and piezoelectric properties . The authors envisioned that such kind of materials and processing technique renders high stretchability and high sensitivity which can be a potential application in super artificial skin for humanoid robotics, human‐machine interfaces, and physiological analysis devices …”

Section: Introductionmentioning

confidence: 99%

Investigation of dielectric properties of free standing electrospun nonwoven mat

Tahalyani

Datar

Kandasubramanian

2017

J of Applied Polymer Sci

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Flexible materials with balanced dielectric as well as conductive characteristics have elucidated considerable demand in field of research where conventional dielectric or insulators can be replaced by recent advances in various electronics appliances. Our work describes the detailed analyses of dielectric properties like dielectric constant, losses, and electric modulus by means of broadband dielectric spectroscopy over frequency ranging from 0.1 Hz to 10 MHz and temperature ranging from 0 to 60 8C for poly(vinyl alcohol)-polyaniline (PVA-PANI) free standing electrospinning nonwoven mat. It has been contemplated that the dielectric constant was enhanced by increasing PANI concentration for complete range of frequency at room temperature. The enhanced dielectric constant value (5.14 at 0.1 Hz, 2.66 at 1 KHz, 2.58 at 10 KHz, and 2.19 at 10 MHz) was anticipated for 7 wt % loading of PANI which was attributed to the presence of dipoles and interfacial polarization enclosed by the polymers. The increased dielectric constant with PANI dosing as well as with temperature attributed to favorable interfacial polarization. Shifting of peak is noticed in the spectra of imaginary electric modulus with increase in temperature which indicates increased chain dynamics of polymers in the mat. Three-dimensional analysis of the field emission scanning electron microscopy images was carried out by SPIP analytical software.

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Section: Introductionmentioning

confidence: 99%

Investigation of dielectric properties of free standing electrospun nonwoven mat

Tahalyani

Datar

Kandasubramanian

2017

J of Applied Polymer Sci

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“…It can produce droplets at least an order of magnitude smaller than the nozzle size, and complex patterns with high‐resolution as small as sub‐micrometer can be printed . EHD direct‐writing is a straightforward, cost‐effective and high‐efficient method to print fibers with diameters ranging from several micrometers to tens of nanometers (Figure d,g), which overlaps contemporary textile fiber technology . Electrospray utilizes electrical field to disrupt the liquid cone for liquid atomization (Figure e,h), and large area thin films in nanoscale thickness could be easily fabricated …”

Section: Evolution Of Ehd Direct‐writingmentioning

confidence: 99%

Section: Evolution Of Ehd Direct‐writingmentioning

confidence: 99%

“…Several science fictional events in popular culture that inspired subsequent critical technological advancements in the development of EHD direct‐writing have been emphasized. Reproduced with permission: “Electrostatic lens,” “Spring,” “Serpentine microstructures,” “High‐temperature melt based 3D printing,” “Alternating current induced wavy direct‐writing,” “Helix EHD Printing,” Copyright, respectively, 2001, 2007, 2012, 2013, 2015, 2017, MDPI AG. “Auxiliary electrodes,” “Near‐field electrospinning,” “Light‐emitting coaxial nanofibers,” Copyright, respectively, 2003, 2006, 2012, American Chemical Society.…”

Section: Evolution Of Ehd Direct‐writingmentioning

confidence: 99%

“…The MES was able to fabricate straight fiber array with controlled diameter and position, orderly bead‐on‐string microstructures in a continuously tunable manner, and other sacrificial structures or polymer templates for micro/nanofabrication . Based on previous experimental researched on the fabrication of serpentine microstructures via electrospinning, Huang et al presented a mathematic illustration of this type of printing mode named HE‐Printing in 2017. It could individually manipulate the fiber flying in a helical manner and directly fabricate various serpentine nano/microfibers through a linear motion collector .…”

Section: Evolution Of Ehd Direct‐writingmentioning

confidence: 99%

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Large‐Scale Direct‐Writing of Aligned Nanofibers for Flexible Electronics

Ding

Duan

et al. 2018

Small

Self Cite

135

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Nanofibers/nanowires usually exhibit exceptionally low flexural rigidities and remarkable tolerance against mechanical bending, showing superior advantages in flexible electronics applications. Electrospinning is regarded as a powerful process for this 1D nanostructure; however, it can only be able to produce chaotic fibers that are incompatible with the well-patterned microstructures in flexible electronics. Electro-hydrodynamic (EHD) direct-writing technology enables large-scale deposition of highly aligned nanofibers in an additive, noncontact, real-time adjustment, and individual control manner on rigid or flexible, planar or curved substrates, making it rather attractive in the fabrication of flexible electronics. In this Review, the ground-breaking research progress in the field of EHD direct-writing technology is summarized, including a brief chronology of EHD direct-writing techniques, basic principles and alignment strategies, and applications in flexible electronics. Finally, future prospects are suggested to advance flexible electronics based on orderly arranged EHD direct-written fibers. This technology overcomes the limitations of the resolution of fabrication and viscosity of ink of conventional inkjet printing, and represents major advances in manufacturing of flexible electronics.

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The Role of 3D Printing Technologies in Soft Grippers

Xin,

Zhou,

Bark

et al. 2023

Advanced Materials

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Soft grippers are essential for precise and gentle handling of delicate, fragile, and easy‐to‐break objects, such as glassware, electronic components, food items, and biological samples, without causing any damage or deformation. This is especially important in industries such as healthcare, manufacturing, agriculture, food handling, and biomedical, where accuracy, safety, and preservation of the objects being handled are critical. This article reviews the use of 3D printing technologies in soft grippers, including those made of functional materials, nonfunctional materials, and those with sensors. 3D printing processes that can be used to fabricate each class of soft grippers are discussed. Available 3D printing technologies that are often used in soft grippers are primarily extrusion‐based printing (fused deposition modeling and direct ink writing), jet‐based printing (polymer jet), and immersion printing (stereolithography and digital light processing). The materials selected for fabricating soft grippers include thermoplastic polymers, UV‐curable polymers, polymer gels, soft conductive composites, and hydrogels. We conclude that 3D printing technologies revolutionize the way soft grippers are being fabricated, expanding their application domains and reducing the difficulties in customization, fabrication and production.This article is protected by copyright. All rights reserved

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Helix Electrohydrodynamic Printing of Highly Aligned Serpentine Micro/Nanofibers

Cited by 39 publications

References 38 publications

Investigation of dielectric properties of free standing electrospun nonwoven mat

Investigation of dielectric properties of free standing electrospun nonwoven mat

Large‐Scale Direct‐Writing of Aligned Nanofibers for Flexible Electronics

The Role of 3D Printing Technologies in Soft Grippers

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