All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

Sun, Dongming; Liu, Chang; Ren, Wencai; Cheng, Hui‐Ming

doi:10.1002/aelm.201600229

Cited by 33 publications

(23 citation statements)

References 226 publications

(298 reference statements)

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“…Employing spin coated ZrO x film (500 °C) as the dielectric layer, Dodabalapur et al demonstrated complementary inverters ( Figure a) and high speed ring oscillators (Figure b) using inkjet printed SWCNTs (p‐type) and ZTO (n‐type) semiconductors . CNTs have been attracting great interest for TFT integration over past two decades due to their high mobility, chemical stability, excellent mechanical flexibility, and potential for various applications (e.g., ICs, displays, and sensors) . Figure c shows output and transfer curves for ZTO and SWCNT TFTs, exhibiting μ FE = 4.4 and 1.7 cm 2 V −1 s −1 in the saturation region, respectively.…”

Section: Recent Achievements Of Oxide High κ Dielectrics Using Solutimentioning

confidence: 99%

Solution Processed Metal Oxide High‐κ Dielectrics for Emerging Transistors and Circuits

et al. 2018

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The electronic functionalities of metal oxides comprise conductors, semiconductors, and insulators. Metal oxides have attracted great interest for construction of large-area electronics, particularly thin-film transistors (TFTs), for their high optical transparency, excellent chemical and thermal stability, and mechanical tolerance. High-permittivity (κ) oxide dielectrics are a key component for achieving low-voltage and high-performance TFTs. With the expanding integration of complementary metal oxide semiconductor transistors, the replacement of SiO with high-κ oxide dielectrics has become urgently required, because their provided thicker layers suppress quantum mechanical tunneling. Toward low-cost devices, tremendous efforts have been devoted to vacuum-free, solution processable fabrication, such as spin coating, spray pyrolysis, and printing techniques. This review focuses on recent progress in solution processed high-κ oxide dielectrics and their applications to emerging TFTs. First, the history, basics, theories, and leakage current mechanisms of high-κ oxide dielectrics are presented, and the underlying mechanism for mobility enhancement over conventional SiO is outlined. Recent achievements of solution-processed high-κ oxide materials and their applications in TFTs are summarized and traditional coating methods and emerging printing techniques are introduced. Finally, low temperature approaches, e.g., ecofriendly water-induced, self-combustion reaction, and energy-assisted post treatments, for the realization of flexible electronics and circuits are discussed.

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Section: Recent Achievements Of Oxide High κ Dielectrics Using Solutimentioning

confidence: 99%

Solution Processed Metal Oxide High‐κ Dielectrics for Emerging Transistors and Circuits

et al. 2018

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“…In particular, the ability to realize flexible thin‐film transistors (TFTs), which are key driving/switching component of wearable electronics, offers much freedom on the target substrates. Therefore, a variety of functional materials focusing on semiconductors have been extensively explored for realizing competitive flexible TFTs, including traditional silicon, organics, oxides, carbon nanotubes (CNTs), and emerging 2D materials . Furthermore, because representative flexible or stretchable platforms, such as polymer‐based plastic and polydimethylsiloxane (PDMS) substrates, are difficult to utilize in traditional microfabrication, the development of alternative processes that can be employed for implementing low‐cost, large‐area, flexible, and biocompatible electronics is key to meet this demand.…”

Section: Introductionmentioning

confidence: 99%

“…This review highlights recent progress in inkjet‐printed TFTs to achieve improved electrical performance and their emerging electronics applications. Although several excellent reviews have already introduced printable organic, oxide, and 2D materials for large‐area TFT applications, for example, high‐speed printed circuits and transparent CNT‐based applications, the overarching aim of this review is to provide an overview of the recent efforts to realize high‐performance inkjet‐printed TFTs based on various channel materials and switching mechanisms as well as fundamental inkjet printing technology. The issues raised in the field of inkjet‐printed organic, metal‐oxide, low‐dimension thin‐film transistors in electronic and material perspectives would be systematically described, and then the currently promising strategies to address these issues will be introduced.…”

Section: Introductionmentioning

confidence: 99%

Recent Progress in Inkjet‐Printed Thin‐Film Transistors

2019

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Drop‐on‐demand inkjet printing is one of the most attractive techniques from a manufacturing perspective due to the possibility of fabrication from a digital layout at ambient conditions, thus leading to great opportunities for the realization of low‐cost and flexible thin‐film devices. Over the past decades, a variety of inkjet‐printed applications including thin‐film transistors (TFTs), radio‐frequency identification devices, sensors, and displays have been explored. In particular, many research groups have made great efforts to realize high‐performance TFTs, for application as potential driving components of ubiquitous wearable electronics. Although there are still challenges to enable the commercialization of printed TFTs beyond laboratory‐scale applications, the field of printed TFTs still attracts significant attention, with remarkable developments in soluble materials and printing methodology. Here, recent progress in printing‐based TFTs is presented from materials to applications. Significant efforts to improve the electrical performance and device‐yield of printed TFTs to match those of counterparts fabricated using conventional deposition or photolithography methods are highlighted. Moreover, emerging low‐dimension printable semiconductors, including carbon nanotubes and transition metal dichalcogenides as well as mature semiconductors, and new‐concept printed switching devices, are also discussed.

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“…Transparent transistor arrays with sufficient mechanical flexibility − have been spotlighted as key technologies for flexible opto- and nanoelectronic devices such as light-emitting diode, display, touch panel, and electronic skin . Use of transparent materials − and dimensional reduction of nontransparent materials − have been the main approaches in fabrication of transparent flexible transistors.…”

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confidence: 99%

Transparent Flexible Nanoline Field-Effect Transistor Array with High Integration in a Large Area

et al. 2020

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Transparent flexible transistor array requests large-area fabrication, high integration, high manufacturing throughput, inexpensive process, uniformity in transistor performance, and reproducibility. This study suggests a facile and reliable approach to meet the requirements. We use the Al-coated polymer nanofiber patterns obtained by electrohydrodynamic (EHD) printing as a photomask. We use the lithography and deposition to produce highly aligned nanolines (NLs) of metals, insulators, and semiconductors on large substrates. With these NLs, we demonstrate a highly integrated NL field-effect transistor (NL-FET) array (105/(4 × 4 in2), 254 pixel-per-inch) made of pentacene and indium zinc oxide semiconductor NLs. In addition, we demonstrate a NL complementary inverter (NL-CI) circuit consisting of pentacene and fullerene NLs. The NL-FET array shows high transparency (∼90%), flexibility (stable at 2.5 mm bending radius), uniformity (∼90%), and high performances (mobility = 0.52 cm2/(V s), on–off ratio = 7.0 × 106). The NL-CI circuit also shows high transparency, flexibility, and typical switching characteristic with a gain of 21. The reliable large-scale fabrication of the various NLs proposed in this study is expected to be applied for manufacturing transparent flexible nanoelectronic devices.

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All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

Cited by 33 publications

References 226 publications

Solution Processed Metal Oxide High‐κ Dielectrics for Emerging Transistors and Circuits

Solution Processed Metal Oxide High‐κ Dielectrics for Emerging Transistors and Circuits

Recent Progress in Inkjet‐Printed Thin‐Film Transistors

Transparent Flexible Nanoline Field-Effect Transistor Array with High Integration in a Large Area

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