Materials and noncoplanar mesh designs for integrated circuits with linear elastic responses to extreme mechanical deformations

Kim, Dae‐Hyeong; Song, Jizhou; Choi, Won Mook; Kim, Hoon‐Sik; Kim, Rakhwan; Liu, Zhuangjian; Huang, Yonggang; Hwang, Kwang‐il; Zhang, Yong‐Wei; Rogers, John A.

doi:10.1073/pnas.0807476105

Cited by 639 publications

(478 citation statements)

References 12 publications

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“…To achieve this functionality, we suggest a patternable and foldable substrate using our CNF hybrid film. Although many previous studies have reported on stretchable interconnects using graphene, 35 metal nanowires, 36 metal nanofiber, 37,38 and geometrical approaches, 39 conventional electronic devices fabricated on the elastomeric substrate are easily broken because most of the semiconductor, dielectric and encapsulation materials are still brittle. Therefore, the approach using origami substrates made of strain-free rigid plates with reversibly foldable and stretchable, elastomeric joints 40 has been considered as a promising strategy for stretchable electronics.…”

Section: Demonstration Of a Transparent Oled On The Hybrid Filmmentioning

confidence: 99%

Photo-patternable and transparent films using cellulose nanofibers for stretchable origami electronics

Hyun

Kim

et al. 2016

NPG Asia Mater

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Substantial progress in flexible or stretchable electronics over the past decade has extensively impacted various technologies such as wearable devices, displays and automotive electronics for smart cars. An important challenge is the reliability of these deformable devices under thermal stress. Different coefficients of thermal expansion (CTE) between plastic substrates and the device components, which include multiple inorganic layers of metals or ceramics, induce thermal stress in the devices during fabrication processes or long-term operations with repetitions of thermal cyclic loading-unloading, leading to device failure and reliability degradation. Here, we report an unconventional approach to form photo-patternable, transparent cellulose nanofiber (CNF) hybrid films as flexible and stretchable substrates to improve device reliability using simultaneous electrospinning and spraying. The electrospun polymeric backbones and sprayed CNF fillers enable the resulting hybrid structure to be photolithographically patternable as a negative photoresist and thermally and mechanically stable, presenting outstanding optical transparency and low CTE. We also formed stretchable origami substrates using the CNF hybrid that are composed of rigid support fixtures and elastomeric joints, exploiting the photo-patternability. A demonstration of transparent organic light-emitting diodes and touchscreen panels on the hybrid film suggests its potential for use in next-generation electronics.

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Section: Demonstration Of a Transparent Oled On The Hybrid Filmmentioning

confidence: 99%

Photo-patternable and transparent films using cellulose nanofibers for stretchable origami electronics

Hyun

Kim

et al. 2016

NPG Asia Mater

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“…To date, two primary strategies have been suggested for the fabrication of stretchable electronic parts apart from complex lithography-based approaches that can shape inorganic conductive materials or metals into buckled geometries, including island-bridge systems. [6][7][8][9] The first strategy is the inclusion of micro-or nano-scale conductive carbon materials into elastic polymer matrices. 1,[10][11][12][13] For example, carbon-based materials, such as carbon nanotubes and graphene, have been extensively researched for stretchable/foldable conductors.…”

Section: Introductionmentioning

confidence: 99%

A highly stretchable, helical copper nanowire conductor exhibiting a stretchability of 700%

et al. 2014

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Recent advances in unconventional foldable and stretchable electronics have forged a new field in electronics. However, traditional conducting metal oxides and metal thin films are inappropriate as electrodes for stretchable devices because they are vulnerable to tensile strain as well as bending strain. In this study, we describe the fabrication of annealing-free, copper nanowire (CuNW)-based stretchable electrodes using an inexpensive metal source through a simple and scalable process at low temperature without a vacuum. We also introduce a reversible and extremely stretchable (up to 700% of strain) helical, CuNW-based conducting spring, which has not been previously used for stretchable electrodes. NPG Asia Materials (2014) 6, e132; doi:10.1038/am.2014.88; published online 26 September 2014 INTRODUCTION Recent advances in unconventional foldable and stretchable electronics show great potential for future wearable applications, including smart skins, electronic eye-type imagers, skin-like pressure sensors, electronic textiles and muscle-like soft actuators. 1-5 Most of these applications require sufficient elasticity for bending, stretching, twisting and deformation into complex, non-planar shapes while maintaining good electrical properties and reliability. Stretchability is the most crucial property for the development of next-generation wearable devices. To date, two primary strategies have been suggested for the fabrication of stretchable electronic parts apart from complex lithography-based approaches that can shape inorganic conductive materials or metals into buckled geometries, including island-bridge systems. [6][7][8][9] The first strategy is the inclusion of micro-or nano-scale conductive carbon materials into elastic polymer matrices. 1,10-13 For example, carbon-based materials, such as carbon nanotubes and graphene, have been extensively researched for stretchable/foldable conductors. Ma et al. 13 fabricated helical ribbon-structured composites composed of carbon nanotubes and Ag flakes using a shape-memory polymer, demonstrating stable resistivity up to a strain of 600%. However, the application of these materials in large-area, integrated devices may be restricted by their relatively poor electrical properties and their high cost. The second strategy is to use highly conductive metallic nanostructures, such as rectangular-patterned gold nanosheets 14 (strain (ε) = 100% on Ecoflex substrate) or silver nanoparticles embedded in composite materials 15 (ε = 140% on elastomeric rubber fiber).Recently, networks of one-dimensional metal nanowires, accompanied by a simple, scalable process (for example, solution-phase

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“…One approach to such technology relies on the development of new electronic materials, e.g., organic semiconductors that can flex (4) and composite elastomer conductors that can stretch (7). Different strategies use optimized structural configurations (8) of established inorganic materials for stretchable interconnects (8)(9)(10)(11)(12)(13) and/or active devices (8,(14)(15)(16). The concepts that enable stretchy properties from these brittle materials are simple.…”

mentioning

confidence: 99%

“…work involves characterizing the microscopic behavior of the material structures, the devices, circuits, and systems, where the length scales for the relevant deformations range from millimeters to nanometers (8,10,12,(14)(15)(16). Fig.…”

mentioning

confidence: 99%

A curvy, stretchy future for electronics

Rogers

Huang²

2009

Proc. Natl. Acad. Sci. U.S.A.

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Materials and noncoplanar mesh designs for integrated circuits with linear elastic responses to extreme mechanical deformations

Cited by 639 publications

References 12 publications

Photo-patternable and transparent films using cellulose nanofibers for stretchable origami electronics

Photo-patternable and transparent films using cellulose nanofibers for stretchable origami electronics

A highly stretchable, helical copper nanowire conductor exhibiting a stretchability of 700%

A curvy, stretchy future for electronics

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