Cellulose‐Based Flexible Functional Materials for Emerging Intelligent Electronics

Zhao, Dawei; Zhu, Ying; Cheng, Wanke; Chen, Wenshuai; Wu, Yiqiang; Yu, Haipeng

doi:10.1002/adma.202000619

Cited by 481 publications

(331 citation statements)

References 155 publications

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“…The authors proposed to use such a device and substrate for point-of-care sensors. For more details, the reader can refer to the recent review from Zhao et al [ 58 ], who focused on the molecular structure and nanostructures (nanocrystals, nanofibers, nanosheets), and the processing technologies for fabricating cellulose-based flexible electronics. Miyashiro et al also reviewed cellulose-based materials, more particularly mixed materials of cellulose and carbon nanotubes [ 59 ], for electronic applications.…”

Section: Discussionmentioning

confidence: 99%

“…Still using natural materials, Gaspar et al published, in 2014, a cotton-based cellulose dielectric [ 58 ] used as both a substrate and gate dielectric in an oxide amorphous semiconductor FET. With an electron mobility above 7 cm 2 V −1 ·s −1 and an on/off ratio above 10 5 , the device presented an excellent operational stability after two weeks in air, without any type of encapsulation.…”

Section: Discussionmentioning

confidence: 99%

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Sensors Made of Natural Renewable Materials: Efficiency, Recyclability or Biodegradability—The Green Electronics

Piro

Tran

Thu

2020

Sensors

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Nowadays, sensor devices are developing fast. It is therefore critical, at a time when the availability and recyclability of materials are, along with acceptability from the consumers, among the most important criteria used by industrials before pushing a device to market, to review the most recent advances related to functional electronic materials, substrates or packaging materials with natural origins and/or presenting good recyclability. This review proposes, in the first section, passive materials used as substrates, supporting matrixes or packaging, whether organic or inorganic, then active materials such as conductors or semiconductors. The last section is dedicated to the review of pertinent sensors and devices integrated in sensors, along with their fabrication methods.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Sensors Made of Natural Renewable Materials: Efficiency, Recyclability or Biodegradability—The Green Electronics

Piro

Tran

Thu

2020

Sensors

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“…CNP has been highlighted as an alternative to traditional plastic. It has broad application prospects not only for packaging but also in the fields of flexible electronics, biomedical devices, and water treatment (Zhao et al 2020). In addition, nanocellulose can be used as thin coatings for paper products to increase their barrier performance in packaging applications (Hubbe et al 2017).…”

Section: Nanocellulose and Self-assembled Nanostructuresmentioning

confidence: 99%

Untitled

2020

BioRes

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As a global environmental problem, plastic pollution has attracted worldwide attention. Plastic wastes not only disrupt ecosystems and biodiversity, but they also threaten human life and health. Countries around the world have enacted regulations in recent years to limit the use of plastics. Paper products have been proposed as promising substitutes for plastics, which undoubtedly brings unprecedented opportunities to the pulp and paper industry. However, paper products have some deficiencies in replacing certain plastic products. Research and development to improve paper properties and reduce production costs is needed to meet such challenges.

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“…[ 12 ] As one of the most common organic polymer, [ 13 ] cellulose is used for green biocomposite manufacturing and also is mechanically robust, [ 14 ] renewable, inexpensive, and biodegradable. Therefore, cellulose‐based natural composites have found a wide range of applications in thermal management, [ 15 ] electronics, [ 16 ] and construction and packaging. [ 17 ] Moreover, some cellulose derivatives, such as water‐soluble methyl cellulose and carboxymethyl cellulose, are being used in construction materials, pharmaceuticals, and cosmetics.…”

Section: Introductionmentioning

confidence: 99%

3D‐Printed Wood‐Fiber Reinforced Architected Cellular Composites

et al. 2020

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One class of state-of-the-art lightweight, energy-efficient materials with enhanced material properties is "architected cellular solids." Their exotic properties (e.g., high strength-to-weight ratio, high energy absorption capability and tunable multiphysical properties) mainly stem from their rationally designed underlying architectures (e.g., cell topology and cell connectivity) and partially from the properties of their constituent materials. [1] Cellular solids, so-called cellular-based "metamaterials," upon showing unprecedented properties, have recently received considerable attention due to their potential applications in aerospace, automotive, energy, robotics and biomedical sectors as high-performance lightweight panels, energy absorbers, morphing structures, noise reduction, waveguide devices, programmable battery electrodes, and bioimplantable medical devices. [2] Recently, advances in "3D printing," interchangeably called "additive manufacturing" (AM), have shed light on strategies for design and realization of advanced materials (including "cellular solids" and "architected metamaterials") with controlled material composition and architectural complexity. A large number of studies have been conducted to investigate the correlation between specific mechanical properties and the architecture of 3D-printed advanced materials. [3] Fast prototyping, material saving, waste minimization, design freedom, and the capability to manufacture complex architectures are the main 3D printing advantages. [4] 3D printing is a fabrication process for constructing free-form materials and structures from a computer-aided design model. The printing process typically involves layerupon-layer fabrication that enables the production of complex geometries that would be impossible by conventional manufacturing processes. [5] Several methods can be adopted for 3D printing: direct metal laser sintering (DMLS), selective laser melting (SLM), and electron beam melting (EBM) for printing metallic powders; selective laser sintering (SLS) for printing polymeric and metallic powders; laminated object manufacturing (LOM), direct foam writing, 3D extrusion freeforming of ceramics (EFF), and lithography-based ceramic manufacturing (LCM) for ceramic-based materials; stereolithography apparatus (SLA) and digital light projection (DLP) for printing photopolymeric resins; and fused deposition modeling (FDM) for printing thermoplastic polymers. [6] The simplicity, reliability, affordability (minimal waste, low processing and operational cost), multimaterial (multinozzle) printing capability, and adaptability to new materials, and composites have made FDM one of the most

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Cellulose‐Based Flexible Functional Materials for Emerging Intelligent Electronics

Cited by 481 publications

References 155 publications

Sensors Made of Natural Renewable Materials: Efficiency, Recyclability or Biodegradability—The Green Electronics

Sensors Made of Natural Renewable Materials: Efficiency, Recyclability or Biodegradability—The Green Electronics

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3D‐Printed Wood‐Fiber Reinforced Architected Cellular Composites

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