Biodegradable transparent substrates for flexible organic-light-emitting diodes

Zhu, Hongli; Xiao, Zhengguo; Liu, Detao; Li, Yuanyuan; Weadock, Nicholas J.; Fang, Zhiqiang; Huang, Jinsong; Hu, Liangbing

doi:10.1039/c3ee40492g

Cited by 290 publications

(236 citation statements)

References 41 publications

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“…The oxidation process was carried out by adding 78 mg of 2,2,6,6-tetramethylpiperidine-1-oxyl and 514 mg NaBr to 5 g kraft bleached softwood pulp into 12% NaClO solution with a pH of 10.5 (controlled by adding NaOH). 31 After oxidation, deionized water was added to the oxidized product to prepare a 1 wt% cellulose suspension. The suspension was then processed by a microfluidizer (M-110EH, Microfluidics Ind.)…”

Section: Device Fabricationmentioning

confidence: 99%

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A flexible solar-blind 2D boron nitride nanopaper-based photodetector with high thermal resistance

Lin

Cheng

et al. 2018

npj 2D Mater Appl

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Flexible electronics are expected to play a key role in connecting human lives with versatile smart electronic devices due to their adaptability to different shapes, surfaces, and even the human body. However, heat management issues found in most flexible devices due to the low thermal conductivity of conventional plastic or paper substrates become significant for large-scale integration or high-temperature applications. In this study, we employed high thermal conductivity nanopaper composed of twodimensional (2D) hexagonal boron nitride nanosheets and one-dimensional nanofibrillated cellulose to form a flexible deepultraviolet photodetector demonstrating superior photodetectivity of up to 8.05 × 10 10 cm Hz 1/2 /W, a short response time of 0.267 s, and excellent flexible durability featuring repeatable ON/OFF photoswitching over 200 bending cycles. Because the boron nitride paper has a high thermal conductivity of 146 W/mK, which is three orders of magnitude larger than plastic or paper substrates, the photodetectors can work at high temperatures of up to 200°C. The boron nitride paper-based strategy described herein suggests a path for improving heat dissipation in flexible electronics and achieving high-performance deep-ultraviolet photodetectors, which can be applied in wearable applications.

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Section: Device Fabricationmentioning

confidence: 99%

“…Next, the suspension was disintegrated by a microfluidizer to achieve the fine NFC suspended material. The NFC, composed of fibrils featuring a diameter ranging from 5 to 100 nm, 31 formed the basis of the flexible nanopaper substrates.…”

Section: Introductionmentioning

confidence: 99%

A flexible solar-blind 2D boron nitride nanopaper-based photodetector with high thermal resistance

Lin

Cheng

et al. 2018

npj 2D Mater Appl

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“…For achieving higher efficiency, top-emitting architectures [182][183][184][185] and nanostructured/scattered electrodes or substrates [47,[130][131][132][133][134][135] can be adopted, to enhance output coupling or light extraction of the devices. However, to achieve high flexibility, extremely bendable TFC electrodes firstly need to be developed [88,120,124,146,147,177,186]. Yu et al [120] developed an AgNWs/shape-memory-polymer composite electrode deposited on PET substrate on which a flexible yellow OLED with minimum R b of 2.5 mm has been constructed.…”

Section: Ultraflexible Oledsmentioning

confidence: 99%

Thin-film organic semiconductor devices: from flexibility to ultraflexibility

Qian

Zhang

et al. 2016

Sci. China Mater.

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Flexible thin-film organic semiconductor devices have received wide attention due to favorable properties such as light-weight, flexibility, reproducible semiconductor resources, easy tuning of functional properties via molecular tailoring, and low cost large-area solution-procession. Among them, ultraflexible electronics, usually with minimum bending radius of less than 1 mm, are essential for the development of epidermal and bio-implanted electronics, wearable electronics, collapsible and portable electronics, three dimensional (3D) surface compliable electronics, and bionics. This review firstly gives a brief introduction of development from flexible to ultraflexible organic semiconductor electronics, and design of ultraflexible devices, then summarizes the recent advances in ultraflexible thin-film organic semiconductor devices, focusing on organic field effect transistors, organic light-emitting diodes, organic solar cells and organic memory devices.

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“…Over the past decade, numerous applications for CNM have been developed and investigated worldwide. [1][2][3][4][5][6][7][8][9][10] Cellulose nanocrystals (CNC) were first isolated in the laboratory by Mukherjee and Woods in 1953, 11 and a commercially scalable process for cellulose nanofiber (CNF) production was invented by ITT Rayonier in 1977. 12,13 Since then, several inventions and techniques have led to the development of pilot-scale production methods which have been implemented across the globe (CelluForce in Canada, American Process, Inc. in the United States of America and Innventia in Sweden to name a few).…”

Section: What Are Cellulose Nanomaterialsmentioning

confidence: 99%

“…In their neat form, CNM have optical properties which result in transparent films or papers. 1,3 Under specific circumstances, CNC self-assemble into a chiral nematic crystalline order, thus having the potential to impart structural color to coated objects. 24,25 The unique surface properties of CNC, particularly, have been investigated both theoretically and experimentally.…”

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confidence: 99%

What do we still need to understand to commercialize cellulose nanomaterials?^†

et al. 2015

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What are cellulose nanomaterialsand why are they of interest?Cellulose nanomaterials (CNM) are naturally occurring nanoparticles present in lignocellulosic biomass (e.g., trees, grasses, municipal waste), bacteria (e.g., acetobacter) and invertebrate sea creatures (e.g., tunicates). Over the past decade, numerous applications for CNM have been developed and investigated worldwide. 1-10Cellulose nanocrystals (CNC) were first isolated in the laboratory by Mukherjee and Woods in 1953, 11 and a commercially scalable process for cellulose nanofiber (CNF) production was invented by ITT Rayonier in 1977. 12,13 Since then, several inventions and techniques have led to the development of pilot-scale production methods which have been implemented across the globe (CelluForce in Canada, American Process, Inc. in the United States of America and Innventia in Sweden to name a few). CNM are an attractive alternative to other high-aspect-ratio nanoparticles, such as carbon nanotubes and silica nanowhiskers, due to their renewable, sustainable origins and expected low toxicity. (Toxicology studies are ongoing but 'powdered cellulose' has recently been placed on the list of Permitted Food Additives in Canada. )Cellulose consists of glucose molecules linked together into polysaccharide chains, which align to form nanocrystalline domains. The hydroxyl substituent groups on each repeat unit form both inter-and intra-chain hydrogen bonds, leading to unique mechanical and thermal properties. 7,15 The nanocrystalline domains are linked together into nanofiber bundles by flexible, amorphous hemicellulose regions. Various processing techniques have been developed to isolate the two general classes of CNM -that is, cellulose nanofibrils and the individual CNC. Isolation of CNC is What do we still need to understand to commercialize cellulose nanomaterials? Davis, Grolman, Karim and Gilman Published with permission by the ICE under the CC-BY license.

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Biodegradable transparent substrates for flexible organic-light-emitting diodes

Cited by 290 publications

References 41 publications

A flexible solar-blind 2D boron nitride nanopaper-based photodetector with high thermal resistance

A flexible solar-blind 2D boron nitride nanopaper-based photodetector with high thermal resistance

Thin-film organic semiconductor devices: from flexibility to ultraflexibility

What do we still need to understand to commercialize cellulose nanomaterials?^†

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Biodegradable transparent substrates for flexible organic-light-emitting diodes

Cited by 290 publications

References 41 publications

A flexible solar-blind 2D boron nitride nanopaper-based photodetector with high thermal resistance

A flexible solar-blind 2D boron nitride nanopaper-based photodetector with high thermal resistance

Thin-film organic semiconductor devices: from flexibility to ultraflexibility

What do we still need to understand to commercialize cellulose nanomaterials?†

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What do we still need to understand to commercialize cellulose nanomaterials?^†