Shinill Kang scite author profile

Fabrication strategies that pursue "simplicity" for the production process and "functionality" for a device, in general, are mutually exclusive. Therefore, strategies that are less expensive, less equipment-intensive, and consequently, more accessible to researchers for the realization of omnipresent electronics are required. Here, this study presents a conceptually different approach that utilizes the inartificial design of the surface roughness of paper to realize a capacitive pressure sensor with high performance compared with sensors produced using costly microfabrication processes. This study utilizes a writing activity with a pencil and paper, which enables the construction of a fundamental capacitor that can be used as a flexible capacitive pressure sensor with high pressure sensitivity and short response time and that it can be inexpensively fabricated over large areas. Furthermore, the paper-based pressure sensors are integrated into a fully functional 3D touch-pad device, which is a step toward the realization of omnipresent electronics.

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Hierarchical MnCo-layered double hydroxides@Ni(OH)₂ core–shell heterostructures as advanced electrodes for supercapacitors

Liu

et al. 2017

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Transparent, Flexible, Conformal Capacitive Pressure Sensors with Nanoparticles

Kim

et al. 2018

Small

122

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The fundamental challenge in designing transparent pressure sensors is the ideal combination of high optical transparency and high pressure sensitivity. Satisfying these competing demands is commonly achieved by a compromise between the transparency and usage of a patterned dielectric surface, which increases pressure sensitivity, but decreases transparency. Herein, a design strategy for fabricating high-transparency and high-sensitivity capacitive pressure sensors is proposed, which relies on the multiple states of nanoparticle dispersity resulting in enhanced surface roughness and light transmittance. We utilize two nanoparticle dispersion states on a surface: (i) homogeneous dispersion, where each nanoparticle (≈500 nm) with a size comparable to the visible light wavelength has low light scattering; and (ii) heterogeneous dispersion, where aggregated nanoparticles form a micrometer-sized feature, increasing pressure sensitivity. This approach is experimentally verified using a nanoparticle-dispersed polymer composite, which has high pressure sensitivity (1.0 kPa ), and demonstrates excellent transparency (>95%). We demonstrate that the integration of nanoparticle-dispersed capacitor elements into an array readily yields a real-time pressure monitoring application and a fully functional touch device capable of acting as a pressure sensor-based input device, thereby opening up new avenues to establish processing techniques that are effective on the nanoscale yet applicable to macroscopic processing.

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Continuous ultraviolet roll nanoimprinting process for replicating large-scale nano- and micropatterns

Cha

Myung

et al. 2006

103

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With the increasing demand for large-scale nano- and micropatterns in the field of digital displays, nano- and micropattern replication technology has become a research priority. In this study, a continuous ultraviolet (UV) roll nanoimprinting process using a pattern roll stamper for the replication of large-scale nano- and micropatterns was designed and constructed. Several flexible nano- and micropatterns with large areas were fabricated and analyzed as tests of this continuous UV imprinting process.

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Controlled electrochemical growth of Co(OH)₂flakes on 3D multilayered graphene foam for high performance supercapacitors

et al. 2014

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Nanoscale patterning of complex magnetic nanostructures by reduction with low-energy protons

Kim

Lee

et al. 2012

Nature Nanotech

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Techniques that can produce patterns with nanoscale details on surfaces have a central role in the development of new electronic, optical and magnetic devices and systems. High-energy ion irradiation can produce nanoscale patterns on ferromagnetic films by destroying the structure of layers or interfaces, but this approach can damage the film and introduce unwanted defects. Moreover, ferromagnetic nanostructures that have been patterned by ion irradiation often interfere with unpatterned regions through exchange interactions, which results in a loss of control over magnetization switching. Here, we demonstrate that low-energy proton irradiation can pattern an array of 100-nm-wide single ferromagnetic domains by reducing [Co(3)O(4)/Pd](10) (a paramagnetic oxide) to produce [Co/Pd](10) (a ferromagnetic metal). Moreover, there are no exchange interactions in the final superlattice, and the ions have a minimal impact on the overall structure, so the interfaces between alternate layers of cobalt (which are 0.6 nm thick) and palladium (1.0 nm) remain intact. This allows the reduced [Co/Pd](10) superlattice to produce a perpendicular magnetic anisotropy that is stronger than that observed in the metallic [Co/Pd](10) superlattices we prepared for reference. We also demonstrate that our non-destructive approach can reduce CoFe(2)O(4) to metallic CoFe.

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Fabrication of a microlens array using micro-compression molding with an electroformed mold insert

Moon

Lee

Kang

2002

J. Micromech. Microeng.

111

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Polymeric microlens arrays, with a diameter of 36–96 μm, a radius of curvature of 20–60 μm and a pitch of 250 μm, were fabricated using micro-compression molding with electroformed mold inserts. We used the reflow method and the electroforming process to make the mother and the metallic mold inserts, respectively. Micro-compression molding with powder polymer was developed to replicate microlenses. The surface profiles, imaging qualities, and surface roughness of the microlenses were measured and analyzed.

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Controllable sulfuration engineered NiO nanosheets with enhanced capacitance for high rate supercapacitors

et al. 2017

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Shinill Kang

Rough‐Surface‐Enabled Capacitive Pressure Sensors with 3D Touch Capability

Hierarchical MnCo-layered double hydroxides@Ni(OH)₂ core–shell heterostructures as advanced electrodes for supercapacitors

Transparent, Flexible, Conformal Capacitive Pressure Sensors with Nanoparticles

Continuous ultraviolet roll nanoimprinting process for replicating large-scale nano- and micropatterns

Controlled electrochemical growth of Co(OH)₂flakes on 3D multilayered graphene foam for high performance supercapacitors

Nanoscale patterning of complex magnetic nanostructures by reduction with low-energy protons

Fabrication of a microlens array using micro-compression molding with an electroformed mold insert

Controllable sulfuration engineered NiO nanosheets with enhanced capacitance for high rate supercapacitors

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Shinill Kang

Rough‐Surface‐Enabled Capacitive Pressure Sensors with 3D Touch Capability

Hierarchical MnCo-layered double hydroxides@Ni(OH)2 core–shell heterostructures as advanced electrodes for supercapacitors

Transparent, Flexible, Conformal Capacitive Pressure Sensors with Nanoparticles

Continuous ultraviolet roll nanoimprinting process for replicating large-scale nano- and micropatterns

Controlled electrochemical growth of Co(OH)2flakes on 3D multilayered graphene foam for high performance supercapacitors

Nanoscale patterning of complex magnetic nanostructures by reduction with low-energy protons

Fabrication of a microlens array using micro-compression molding with an electroformed mold insert

Controllable sulfuration engineered NiO nanosheets with enhanced capacitance for high rate supercapacitors

Contact Info

Product

Resources

About

Hierarchical MnCo-layered double hydroxides@Ni(OH)₂ core–shell heterostructures as advanced electrodes for supercapacitors

Controlled electrochemical growth of Co(OH)₂flakes on 3D multilayered graphene foam for high performance supercapacitors