Area-Selective Lift-Off Mechanism Based on Dual-Triggered Interfacial Adhesion Switching: Highly Facile Fabrication of Flexible Nanomesh Electrode

Yu, Sanghyeon; Han, Hyeuk Jin; Kim, Jong Min; Yim, Soonmin; Sim, Dong Min; Lim, Hunhee; Lee, Jung Hye; Park, Woon Ik; Park, Jae Hong; Kim, Kwang Ho; Jung, Yeon Sik

doi:10.1021/acsnano.7b00229

Cited by 31 publications

(25 citation statements)

References 39 publications

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“…High‐performance sensors having high sensitivity, flexibility, power efficiency, and stability are very important not only in conventional healthcare, safety diagnostics, mechanics, and security, but also in future electronics, such as wearables and bioimplantable devices 5,40,140–147. In this regard, nanomaterials have been conventionally studied as a sensing material for high‐performance sensors because their unique form factors, such as light weight, high aspect ratio, and large surface‐to‐volume ratio, are appropriate to produce performance‐enhanced sensor devices 1–9. More recently, researchers have further revealed that geometrically structured nanomaterials can improve device performance and functionality because of the unexpected superior physical and chemical characteristics due to the geometry of the nanomaterials 7,8,53,77–81.…”

Section: High‐performance Sensors Using Geometrically Structured Nanomentioning

confidence: 99%

“…Over recent decades, scientific exploration and engineering of nanomaterials have gained great attention in diverse fields from academia to industry thanks to extraordinary physical and chemical phenomena originating from their nanosize effects, which cannot be realized in the bulk materials 1–13. Indeed, superior mechanical strength, electrical resistivity or mobility, electrical quantum effects, thermal resistivity or mobility, chemical reaction, and optical light emission have been observed with diverse nanomaterials, such as various metallic and semiconductor nanoparticles and nanowires, carbon nanotubes (CNTs), quantum dots, graphene, and molybdenum disulfide (MoS 2 ) 14–34.…”

Section: Introductionmentioning

confidence: 99%

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Geometrically Structured Nanomaterials for Nanosensors, NEMS, and Nanosieves

Seo

Yoo

et al. 2020

Advanced Materials

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Recently, geometrically structured nanomaterials have received great attention due to their unique physical and chemical properties, which originate from the geometric variation in such materials. Indeed, the use of various geometrically structured nanomaterials has been actively reported in enhanced‐performance devices in a wide range of applications. Recent significant progress in the development of geometrically structured nanomaterials and associated devices is summarized. First, a brief introduction of advanced nanofabrication methods that enable the fabrication of various geometrically structured nanomaterials is given, and then the performance enhancements achieved in devices utilizing these nanomaterials, namely, i) physical and gas nanosensors, ii) nanoelectromechanical devices, and iii) nanosieves are described. For the device applications, a systematic summary of their structures, working mechanisms, fabrication methods, and output performance is provided. Particular focus is given to how device performance can be enhanced through the geometric structures of the nanomaterials. Finally, perspectives on the development of novel nanomaterial structures and associated devices are presented.

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Section: High‐performance Sensors Using Geometrically Structured Nanomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Geometrically Structured Nanomaterials for Nanosensors, NEMS, and Nanosieves

Seo

Yoo

et al. 2020

Advanced Materials

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“…The polar solvent (IPA) molecules interact with the hydroxyl edge‐functional groups of the f‐BN and effectively shields the f‐BN, weakening the interaction between the f‐BN and other interfacial surfaces. The solvent provides an interfacial screening effect, [ 37 ] and thus the adhesion strength between the substrate and the BN film can be negligible in the fully solvated state, resulting in the BN film remaining on the membrane. Although f‐BN is solvated, the BN film is still bound to the membrane surface because the generated fluid pressure from the vacuum filtration process causes f‐BN to be physically adsorbed on the membrane.…”

Section: Figurementioning

confidence: 99%

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

Han

Rah

et al. 2020

Advanced Materials

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Although hexagonal boron nitride (BN) nanostructures have recently received significant attention due to their unique physical and chemical properties, their applications have been limited by a lack of processability and poor film quality. In this study, a versatile method to transfer‐print high‐quality BN films composed of densely stacked BN nanosheets based on a desolvation‐induced adhesion switching (DIAS) mechanism is developed. It is shown that edge functionalization of BN sheets and rational selection of membrane surface energy combined with systematic control of solvation and desolvation status enable extensive tunability of interfacial interactions at BN–BN, BN–membrane, and BN–substrate boundaries. Therefore, without incorporating any additives in the BN film and applying any surface treatment on target substrates, DIAS achieves a near 100% transfer yield of pure BN films on diverse substrates, including substrates containing significant surface irregularities. The printed BNs demonstrate high optical transparency (>90%) and excellent thermal conductivity (>167 W m−1 K−1) for few‐micrometer‐thick films due to their dense and well‐ordered microstructures. In addition to outstanding heat dissipation capability, substantial optical enhancement effects are confirmed for light‐emitting, photoluminescent, and photovoltaic devices, demonstrating their remarkable promise for next‐generation optoelectronic device platforms.

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“…Nanomaterials (e.g., nanowires, nanofilms, 2D materials and 3D nanostructures) have been widely used in the field of flexible electrodes, optoelectronics, and nanoelectronics, due to their exceptional optical and electrical properties [1][2][3][4][5][6]. Transfer of nanomaterials from its original substrate is one of the key components for the fabrication of the heterogeneously integrated functional systems [7].…”

Section: Introductionmentioning

confidence: 99%

Sugar transfer of nanomaterials and flexible electrodes

Hong

Shen

Yang

et al. 2020

International Journal of Smart and Nano Materials

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Nanomaterials with various dimensionalities (e.g., nanowires, nanofilms, two-dimensional materials, and three-dimensional nanostructures) have shown great potential in the recent development of flexible electronics. Conventionally, organic solvents are inevitable while integrating nanomaterials onto flexible substrates, where polymer mediator-assisted transfer techniques are involved. This often damages the flexible substrate and thus hamper the large-scale application of nanomaterials. Here we report a method using watersoluble sugar as a mediator to facilely transfer nanomaterials onto rigid or flexible substrates. This method requires no organic solvent during transfer. More importantly, the morphology and properties of transferred nanomaterials, such as shape, microstructure, resistivity, and transmittance are well preserved on the target substrate. We believe that this universal and rapid transfer method can greatly advance the applications of nanomaterials in the field of flexible devices and beyond. ARTICLE HISTORY

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Area-Selective Lift-Off Mechanism Based on Dual-Triggered Interfacial Adhesion Switching: Highly Facile Fabrication of Flexible Nanomesh Electrode

Cited by 31 publications

References 39 publications

Geometrically Structured Nanomaterials for Nanosensors, NEMS, and Nanosieves

Geometrically Structured Nanomaterials for Nanosensors, NEMS, and Nanosieves

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

Sugar transfer of nanomaterials and flexible electrodes

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