Your search keyword '"Yuto Ochiai"' showing total 4 results

1. Synthesis of electron deficient semiconducting polymers for intrinsically stretchable n-type semiconducting materials

Author

Megumi Matsuda, Kei-ichiro Sato, Kosuke Terayama, Yuto Ochiai, Kazushi Enomoto, and Tomoya Higashihara

Subjects

Polymers and Plastics, Materials Chemistry

Published

2022

2. High-frequency and intrinsically stretchable polymer diodes

Author

Naoji Matsuhisa, Simiao Niu, Stephen J. K. O’Neill, Jiheong Kang, Yuto Ochiai, Toru Katsumata, Hung-Chin Wu, Minoru Ashizawa, Ging-Ji Nathan Wang, Donglai Zhong, Xuelin Wang, Xiwen Gong, Rui Ning, Huaxin Gong, Insang You, Yu Zheng, Zhitao Zhang, Jeffrey B.-H. Tok, Xiaodong Chen, Zhenan Bao, School of Materials Science and Engineering, and Innovative Centre for Flexible Devices

Subjects

Silver, Multidisciplinary, Nanowires, Polymers, Chemical engineering [Engineering], Fabrication, Wearable Electronic Devices, Skin Electronics, Semiconductors, Humans, Electronics, Electrodes, Wireless Technology, Skin

Abstract

Skin-like intrinsically stretchable soft electronic devices are essential to realize next-generation remote and preventative medicine for advanced personal healthcare1-4. The recent development of intrinsically stretchable conductors and semiconductors has enabled highly mechanically robust and skin-conformable electronic circuits or optoelectronic devices2,5-10. However, their operating frequencies have been limited to less than 100 hertz, which is much lower than that required for many applications. Here we report intrinsically stretchable diodes-based on stretchable organic and nanomaterials-capable of operating at a frequency as high as 13.56 megahertz. This operating frequency is high enough for the wireless operation of soft sensors and electrochromic display pixels using radiofrequency identification in which the base-carrier frequency is 6.78 megahertz or 13.56 megahertz. This was achieved through a combination of rational material design and device engineering. Specifically, we developed a stretchable anode, cathode, semiconductor and current collector that can satisfy the strict requirements for high-frequency operation. Finally, we show the operational feasibility of our diode by integrating it with a stretchable sensor, electrochromic display pixel and antenna to realize a stretchable wireless tag. This work is an important step towards enabling enhanced functionalities and capabilities for skin-like wearable electronics. Agency for Science, Technology and Research (A*STAR) This work was partially supported by SAIT, Samsung Electronics Co., Ltd., and the Agency for Science, Technology and Research (A*STAR) under its Advanced Manufacturing and Engineering (AME) Programmatic Scheme (no. A18A1b0045). N.M. was partially supported by a Japan Society for the Promotion of Science (JSPS) overseas research fellowship. Part of this work was performed at the Stanford Nano Shared Facilities (SNSF), supported by the National Science Foundation under award ECCS-1542152. Experiments performed during revision were carried out in Keio University and was supported by JST, PRESTO Grant Number JPMJPR20B7, Japan.

Published

2021

3. Strain-insensitive intrinsically stretchable transistors and circuits

Author

Rui Ning, Xuzhou Yan, Zhenan Bao, Zhitao Zhang, Jeffrey B.-H. Tok, Prajwal Kammardi Arunachala, Yuto Ochiai, Weichen Wang, Jie Xu, Youngjun Yun, Naoji Matsuhisa, Yuanwen Jiang, Masashi Miyakawa, Christian Linder, Reza Rastak, Yu Zheng, Amir M. Foudeh, Simiao Niu, Soon Ki Kwon, and Sihong Wang

Subjects

Materials science, business.industry, Amplifier, Stretchable electronics, Transistor, Transistor array, Electrical element, Elastomer, Electronic, Optical and Magnetic Materials, law.invention, Strain engineering, law, Optoelectronics, Electrical and Electronic Engineering, business, Instrumentation, Electronic circuit

Abstract

Intrinsically stretchable electronics can form intimate interfaces with the human body, creating devices that could be used to monitor physiological signals without constraining movement. However, mechanical strain invariably leads to the degradation of the electronic properties of the devices. Here we show that strain-insensitive intrinsically stretchable transistor arrays can be created using an all-elastomer strain engineering approach, in which the patterned elastomer layers with tunable stiffnesses are incorporated into the transistor structure. By varying the cross-linking density of the elastomers, areas of increased local stiffness are introduced, reducing strain on the active regions of the devices. This approach can be readily incorporated into existing fabrication processes, and we use it to create arrays with a device density of 340 transistors cm–2 and a strain insensitivity of less than 5% performance variation when stretched to 100% strain. We also show that it can be used to fabricate strain-insensitive circuit elements, including NOR gates, ring oscillators and high-gain amplifiers for the stable monitoring of electrophysiological signals. An all-elastomer strain engineering approach, which uses patterned elastomer layers with tunable stiffnesses, can be used to create intrinsically stretchable transistor arrays with a device density of 340 transistors cm–2 and strain insensitivity of less than 5% performance variation when stretched to 100% strain.

Published

2021

4. A design strategy for high mobility stretchable polymer semiconductors

Author

Jeffrey B.-H. Tok, Jaewan Mun, Yu-Qing Zheng, Yuto Ochiai, Naoji Matsuhisa, Tomoya Higashihara, Weichen Wang, Youngjun Yun, Hung-Chin Wu, Yu Zheng, and Zhenan Bao

Subjects

Materials science, Polymers, Science, Stretchable electronics, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Molecular engineering, law.invention, Crystallinity, law, Electronic devices, Electronics, chemistry.chemical_classification, Multidisciplinary, business.industry, Transistor, General Chemistry, Polymer, 021001 nanoscience & nanotechnology, Microstructure, 0104 chemical sciences, Semiconductor, chemistry, 0210 nano-technology, business

Abstract

As a key component in stretchable electronics, semiconducting polymers have been widely studied. However, it remains challenging to achieve stretchable semiconducting polymers with high mobility and mechanical reversibility against repeated mechanical stress. Here, we report a simple and universal strategy to realize intrinsically stretchable semiconducting polymers with controlled multi-scale ordering to address this challenge. Specifically, incorporating two types of randomly distributed co-monomer units reduces overall crystallinity and longer-range orders while maintaining short-range ordered aggregates. The resulting polymers maintain high mobility while having much improved stretchability and mechanical reversibility compared with the regular polymer structure with only one type of co-monomer units. Interestingly, the crystalline microstructures are mostly retained even under strain, which may contribute to the improved robustness of our stretchable semiconductors. The proposed molecular design concept is observed to improve the mechanical properties of various p- and n-type conjugated polymers, thus showing the general applicability of our approach. Finally, fully stretchable transistors fabricated with our newly designed stretchable semiconductors exhibit the highest and most stable mobility retention capability under repeated strains of 1,000 cycles. Our general molecular engineering strategy offers a rapid way to develop high mobility stretchable semiconducting polymers., Designing intrinsically stretchable semiconducting polymers with suitable charge transport and mechanical properties required for stretchable electronic devices remains a challenge. Here, the authors report terpolymer-based semiconductors with intrinsically high stretchability and mobility.

Published

2021