Organic thin-film transistors with sub-10-micrometer channel length with printed polymer/carbon nanotube electrodes

Kim, Jiye; Lee, Seungyoung; Lee, Dong Yun; Lim, Sooman; Lee, Jaewoong; Kim, Se Hyun

doi:10.1016/j.orgel.2017.10.023

Cited by 16 publications

(7 citation statements)

References 47 publications

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“…Several researchers have studied the incorporation of maturity models into the determination of the I4.0 maturity level [14,28,29,[33][34][35][36][37][38][39][40][41][42][43][44][45]. This subject has already been widely discussed in the literature, with a focus on the benefits of Industry 4.0 the potential challenges that enterprises will encounter when implementing these technologies [98][99][100][101][102][103][104][105][106][107][108][109][110][111]. Moreover, critical factors of I4.0, managerial capacity, digital information sharing, enterprise strategy, and industrial performance objectives are extensively discussed in the literature [12,110,112,113].…”

Section: Discussionmentioning

confidence: 99%

A Framework for Industry 4.0 Readiness and Maturity of Smart Manufacturing Enterprises: A Case Study

2021

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Recently, researchers have proposed various maturity models (MMs) for assessing Industry 4.0 (I4.0) adoption; however, few have proposed a readiness framework (F/W) integrated with technology forecasting (TF) to evaluate the growth of I4.0 adoption and consequently provide a roadmap for the implementation of I4.0 for smart manufacturing enterprises. The aims of this study were (1) to review the research related to existing I4.0 MMs and F/Ws; (2) to propose a modular MM with four dimensions, five levels, 60 second-level dimensions, and 246 sub-dimensions, and a generic F/W with four layers and seven hierarchy levels; and (3) to conduct a survey-based case study of an automobile parts manufacturing enterprise by applying the MM and F/W to assess the I4.0 adoption level and TF model to anticipate the growth of I4.0. MM and F/W integrated with TF provides insight into the current situation and growth of the enterprise regarding I4.0 adoption, by identifying the gap areas, and provide a foundation for I4.0 integration. Case study findings show that the enterprise’s overall maturity score is 2.73 out of 5.00, and the forecasted year of full integration of I4.0 is between 2031 and 2034 depending upon the policy decisions.

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Section: Discussionmentioning

confidence: 99%

A Framework for Industry 4.0 Readiness and Maturity of Smart Manufacturing Enterprises: A Case Study

2021

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“…Then, the droplets are ejected from the nozzle to deposit at predefined positions, forming the desired pattern with high resolution on the targeted substrate, as shown in Figure 2 . Electrohydrodynamic printing can be applied in the manufacture of thin-film transistors [ 29 , 30 , 31 ], protein microarrays [ 32 ], DNA microarrays [ 33 ], block copolymer thin films with self-assembly effects [ 16 ], optical devices, conductive electrodes [ 34 , 35 , 36 , 37 ] etc., and can be used in technologies such as cell culture, quantum dot displays [ 38 , 39 ], and 3D structural printing.…”

Section: Typical Generation Mechanisms Of Droplet Printingmentioning

confidence: 99%

Review of Droplet Printing Technologies for Flexible Electronic Devices: Materials, Control, and Applications

Jiang,

Chen,

Mei

et al. 2024

Micromachines

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Flexible devices have extensive applications in areas including wearable sensors, healthcare, smart packaging, energy, automotive and aerospace sectors, and other related fields. Droplet printing technology can be utilized to print flexible electronic components with micro/nanostructures on various scales, exhibiting good compatibility and wide material applicability for device production. This paper provides a comprehensive review of the current research status of droplet printing technologies and their applications across various domains, aiming to offer a valuable reference for researchers in related areas.

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“…Among them, PDMS are suitable for EHD printed electronics. Recent studies focus on fabricating flexible pressure and strain sensor array [143,144], ion-gel-based transistor [145], flexible electrodes [146][147][148], organic thin-film transistor (OTFT) [149,150] etc. Although PEDOT: PSS is commonly used in printed electronics, the ink properties, geometrical pattern and array can be further optimized for targeted applications and multi-modal sensor integration.…”

Section: Polymersmentioning

confidence: 99%

“…These 3DP techniques have already been demonstrated as effective methods in physical sensors fabrication, with many sensor devices successfully fabricated. The 3DP physical sensors include tactile (touch sensors) [173,204], acoustic sensors [205,206], microcantilever sensors [207], transistors [145,[148][149][150]208,209], strain sensors [143,171,172,210], pressure sensors [66,135,144,151,154,170,211,212] and (piezo resistance, piezoelectricity, capacitance, triboelectricity), photosensors [213][214][215][216]. etc.…”

Section: Electronic 421 Physical Sensormentioning

confidence: 99%

High Precision 3D Printing for Micro to Nano Scale Biomedical and Electronic Devices

et al. 2022

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Three dimensional printing (3DP), or additive manufacturing, is an exponentially growing process in the fabrication of various technologies with applications in sectors such as electronics, biomedical, pharmaceutical and tissue engineering. Micro and nano scale printing is encouraging the innovation of the aforementioned sectors, due to the ability to control design, material and chemical properties at a highly precise level, which is advantageous in creating a high surface area to volume ratio and altering the overall products’ mechanical and physical properties. In this review, micro/-nano printing technology,mainly related to lithography, inkjet and electrohydrodynamic (EHD) printing and their biomedical and electronic applications will be discussed. The current limitations to micro/-nano printing methods will be examined, covering the difficulty in achieving controlled structures at the miniscule micro and nano scale required for specific applications.

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Organic thin-film transistors with sub-10-micrometer channel length with printed polymer/carbon nanotube electrodes

Cited by 16 publications

References 47 publications

A Framework for Industry 4.0 Readiness and Maturity of Smart Manufacturing Enterprises: A Case Study

A Framework for Industry 4.0 Readiness and Maturity of Smart Manufacturing Enterprises: A Case Study

Review of Droplet Printing Technologies for Flexible Electronic Devices: Materials, Control, and Applications

High Precision 3D Printing for Micro to Nano Scale Biomedical and Electronic Devices

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