Desolvation‐Triggered Versatile Transfer‐Printing of Pure BN Films with Thermal–Optical Dual Functionality

Han, Yu-Jin; Han, Hyeuk Jin; Rah, Yoonhyuk; Kim, Cheolgyu; Kim, Moohyum; Lim, Hunhee; Ahn, Kang-Hun; Jang, Hanhwi; Yu, Kyoungsik; Kim, Taek‐Soo; Cho, Eugene N.; Jung, Yeon Sik

doi:10.1002/adma.202002099

Cited by 7 publications

(1 citation statement)

References 51 publications

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“…Research pertaining to precisely designed nanophotonic devices on various substrates has recently received considerable attention driven by the growing demand for diverse mechanical and optical properties in optical elements, such as those used in augmented reality (AR) and virtual reality (VR) systems, sensors, lenses, and flexible and stretchable displays . In this regard, nanotransfer printing (nTP) has been extensively studied in industry and academia as a fabrication technique because of its ability to repeatedly produce large-area nanostructures with high efficiency. − The basic mechanism of nTP relies on the adhesion force between the mold and material ( F 1 ) being weaker than the adhesion force between the material and substrate ( F 2 ) . The relative adhesion force is defined as F 2 – F 1 , and material transfer to the substrate is possible under the condition: F 2 – F 1 > 0.…”

Section: Introductionmentioning

confidence: 99%

Nanotransfer-on-Things: From Rigid to Stretchable Nanophotonic Devices

Ahn

Jeong

et al. 2023

ACS Nano

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The growing demand for nanophotonic devices has driven the advancement of nanotransfer printing (nTP) technology. Currently, the scope of nTP is limited to certain materials and substrates owing to the temperature, pressure, and chemical bonding requirements. In this study, we developed a universal nTP technique utilizing covalent bonding-based adhesives to improve the adhesion between the target material and substrate. Additionally, the technique employed plasma-based selective etching to weaken the adhesion between the mold and target material, thereby enabling the reliable modulation of the relative adhesion forces, regardless of the material or substrate. The technique was evaluated by printing four optical materials on nine substrates, including rigid, flexible, and stretchable substrates. Finally, its applicability was demonstrated by fabricating a ring hologram, a flexible plasmonic color filter, and extraordinary optical transmission-based strain sensors. The high accuracy and reliability of the proposed nTP method were verified by the performance of nanophotonic devices that closely matched numerical simulation results.

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Section: Introductionmentioning

confidence: 99%

Nanotransfer-on-Things: From Rigid to Stretchable Nanophotonic Devices

Ahn

Jeong

et al. 2023

ACS Nano

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Syneresis‐Driven Self‐Refilling Printing of Geometry/Component‐Controlled Nano/Microstructures

Shiba,

Saito,

Minami

et al. 2024

Advanced Science

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Nano/microfabrication is of fundamental importance both in scientific and industrial situations. There are, therefore, many attempts at realizing easier, quicker, and more precise fabrication of various structures; however, achieving this aim without a bulky and costly setup is still challenging. Here, we introduce a facile and versatile means of printing an ordered structure consisting of nanoscale stripes and more complicated geometries including pillars and wavy form with a lateral resolution of single micrometers. To this end, we prepare a polydimethylsiloxane (PDMS) slab with an oxygen plasma‐induced wrinkled surface where liquid PDMS exudes by syneresis. Since this liquid PDMS is automatically loaded, the printing is repeatable without inking. A substrate moderately wettable to the liquid PDMS as well as amount/property‐controlled syneresis is primarily important for the creation of well‐defined structures. Precisely controlling these conditions will make this method universally applicable to diverse substrates and liquids including suspensions.

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Coaxial Wet Spinning of Boron Nitride Nanosheet-Based Composite Fibers with Enhanced Thermal Conductivity and Mechanical Strength

Lu,

Deng,

Liu

et al. 2023

Nano-Micro Lett.

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Hexagonal boron nitride nanosheets (BNNSs) exhibit remarkable thermal and dielectric properties. However, their self-assembly and alignment in macroscopic forms remain challenging due to the chemical inertness of boron nitride, thereby limiting their performance in applications such as thermal management. In this study, we present a coaxial wet spinning approach for the fabrication of BNNSs/polymer composite fibers with high nanosheet orientation. The composite fibers were prepared using a superacid-based solvent system and showed a layered structure comprising an aramid core and an aramid/BNNSs sheath. Notably, the coaxial fibers exhibited significantly higher BNNSs alignment compared to uniaxial aramid/BNNSs fibers, primarily due to the additional compressive forces exerted at the core-sheath interface during the hot drawing process. With a BNNSs loading of 60 wt%, the resulting coaxial fibers showed exceptional properties, including an ultrahigh Herman orientation parameter of 0.81, thermal conductivity of 17.2 W m−1 K−1, and tensile strength of 192.5 MPa. These results surpassed those of uniaxial fibers and previously reported BNNSs composite fibers, making them highly suitable for applications such as wearable thermal management textiles. Our findings present a promising strategy for fabricating high-performance composite fibers based on BNNSs.

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Desolvation‐Triggered Versatile Transfer‐Printing of Pure BN Films with Thermal–Optical Dual Functionality

Cited by 7 publications

References 51 publications

Nanotransfer-on-Things: From Rigid to Stretchable Nanophotonic Devices

Nanotransfer-on-Things: From Rigid to Stretchable Nanophotonic Devices

Syneresis‐Driven Self‐Refilling Printing of Geometry/Component‐Controlled Nano/Microstructures

Coaxial Wet Spinning of Boron Nitride Nanosheet-Based Composite Fibers with Enhanced Thermal Conductivity and Mechanical Strength

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