Inkjet-printed stretchable and low voltage synaptic transistor array

Molina‐Lopez, Francisco; Gao, Theodore Z.; Kraft, Ulrike; Zhu, Chong; Öhlund, Thomas; Pfattner, Raphael; Feig, Vivian R.; Kim, Yeongin; Wang, S.; Yun, Youngjun; Bao, Zhenan

doi:10.1038/s41467-019-10569-3

Cited by 221 publications

(224 citation statements)

References 44 publications

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“…The interest in OLEDs for communication is driven not only by their widespread use in display technologies but also by the very same advantages that have been driving the success of organic electronics. Above all, organic semiconductors (OSs) can be cheaply deposited over large areas, either via thermal evaporation or from solution via spin 15 , blade 16 , inkjet 17 , or spray coating 18 . Large area OS-based luminaires are already entering the market 19 and are expected to be the next mass application of OSs after active-matrix OLED (AMOLED) displays.…”

Section: Introductionmentioning

confidence: 99%

Visible light communication with efficient far-red/near-infrared polymer light-emitting diodes

et al. 2020

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Visible light communication (VLC) is a wireless technology that relies on optical intensity modulation and is potentially a game changer for internet-of-things (IoT) connectivity. However, VLC is hindered by the low penetration depth of visible light in non-transparent media. One solution is to extend operation into the "nearly (in)visible" near-infrared (NIR, 700-1000 nm) region, thus also enabling VLC in photonic bio-applications, considering the biological tissue NIR semitransparency, while conveniently retaining vestigial red emission to help check the link operativity by simple eye inspection. Here, we report new far-red/NIR organic light-emitting diodes (OLEDs) with a 650-800 nm emission range and external quantum efficiencies among the highest reported in this spectral range (>2.7%, with maximum radiance and luminance of 3.5 mW/cm 2 and 260 cd/m 2 , respectively). With these OLEDs, we then demonstrate a "real-time" VLC setup achieving a data rate of 2.2 Mb/s, which satisfies the requirements for IoT and biosensing applications. These are the highest rates ever reported for an online unequalised VLC link based on solution-processed OLEDs.

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Section: Introductionmentioning

confidence: 99%

Visible light communication with efficient far-red/near-infrared polymer light-emitting diodes

et al. 2020

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“…Wang et al demonstrated an intrinsically stretchable transistor array with a device density of 347 transistors per square centimeter . Molina‐Lopez et al used inkjet printing of polymers and carbon nanotubes to fabricate stretchable transistor arrays with mobilities of 30 cm 2 V − 1 s − 1 . The fabricated devices with and without strain are shown in Figure d,e, respectively.…”

Section: Core Components Of Fhementioning

confidence: 99%

A New Frontier of Printed Electronics: Flexible Hybrid Electronics

et al. 2019

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The performance and integration density of silicon integrated circuits (ICs) have progressed at an unprecedented pace in the past 60 years. While silicon ICs thrive at low‐power high‐performance computing, creating flexible and large‐area electronics using silicon remains a challenge. On the other hand, flexible and printed electronics use intrinsically flexible materials and printing techniques to manufacture compliant and large‐area electronics. Nonetheless, flexible electronics are not as efficient as silicon ICs for computation and signal communication. Flexible hybrid electronics (FHE) leverages the strengths of these two dissimilar technologies. It uses flexible and printed electronics where flexibility and scalability are required, i.e., for sensing and actuating, and silicon ICs for computation and communication purposes. Combining flexible electronics and silicon ICs yields a very powerful and versatile technology with a vast range of applications. Here, the fundamental building blocks of an FHE system, printed sensors and circuits, thinned silicon ICs, printed antennas, printed energy harvesting and storage modules, and printed displays, are discussed. Emerging application areas of FHE in wearable health, structural health, industrial, environmental, and agricultural sensing are reviewed. Overall, the recent progress, fabrication, application, and challenges, and an outlook, related to FHE are presented.

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“…Utilizing separate nozzles, different formulations of colloidal droplets can be printed side‐by‐side or stacked, forming hybrid metal‐polymer architectures. Using an entire array of semiconducting, dielectric, insulating, and conductive materials, Molina‐Lopez et al e‐jet printed arrays of stretchable field‐effect transistors (FETs) to create flexible, stretchable electronics 325. The transistors could be stretched up to 20% before diminishing in electrical performance, upon which contact separation and electrode cracking occurred.…”

Section: Electrical Patterningmentioning

confidence: 99%

Nanomaterial Patterning in 3D Printing

et al. 2020

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The synergistic integration of nanomaterials with 3D printing technologies can enable the creation of architecture and devices with an unprecedented level of functional integration. In particular, a multiscale 3D printing approach can seamlessly interweave nanomaterials with diverse classes of materials to impart, program, or modulate a wide range of functional properties in an otherwise passive 3D printed object. However, achieving such multiscale integration is challenging as it requires the ability to pattern, organize, or assemble nanomaterials in a 3D printing process. This review highlights the latest advances in the integration of nanomaterials with 3D printing, achieved by leveraging mechanical, electrical, magnetic, optical, or thermal phenomena. Ultimately, it is envisioned that such approaches can enable the creation of multifunctional constructs and devices that cannot be fabricated with conventional manufacturing approaches.

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Inkjet-printed stretchable and low voltage synaptic transistor array

Cited by 221 publications

References 44 publications

Visible light communication with efficient far-red/near-infrared polymer light-emitting diodes

Visible light communication with efficient far-red/near-infrared polymer light-emitting diodes

A New Frontier of Printed Electronics: Flexible Hybrid Electronics

Nanomaterial Patterning in 3D Printing

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