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48 results on '"Arai, Shunto"'

1. Observation of classical to quantum crossover in electron glass

Author

Murase, Hideaki, Arai, Shunto, Sato, Takuro, Miyagawa, Kazuya, Mori, Hatsumi, Hasegawa, Tatsuo, and Kanoda, Kazushi

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Soft Condensed Matter
Abstract

Glass, a ubiquitous state of matter like a frozen liquid, is a seminal issue across fundamental and applied sciences and has long been investigated in the framework of classical mechanics. A challenge in glass physics is the exploration of the quantum-mechanical behaviour of glass. Experimentally, however, the real quantum manifestation of glass and the relationship between classical and quantum glass are totally unknown and remain to be observed in real systems. Here, we report the direct observation of classical-to-quantum evolution in the frustration-induced charge glass state exhibited by interacting electrons in organic materials. We employ Raman spectroscopy to capture a snapshot of the charge density distribution of each molecule in a series of charge glasses formed on triangular lattices with different geometrical frustrations. In less frustrated glass, the charge density profile exhibits a particle-like two-valued distribution; however, it becomes continuous and narrowed with increasing frustration, demonstrating the classical-to-quantum crossover. Moreover, the charge density distribution shows contrasting temperature evolution in classical and quantum glasses, enabling us to delineate energy landscapes with distinct features. The present result is the first to experimentally identify the quantum charge glass and show how it emerges from classical glass., Comment: 33 pages including 13 figures

Published
2022

2. Spatiotemporal observation of quantum crystallization of electrons

Author

Murase, Hideaki, Arai, Shunto, Hasegawa, Tatsuo, Miyagawa, Kazuya, and Kanoda, Kazushi

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Soft Condensed Matter
Abstract

Liquids crystallize as they cool; however, when crystallization is avoided in some way, they supercool, maintaining their liquidity, and freezing into glass at low temperatures, as ubiquitously observed. These metastable states crystallize over time through the classical dynamics of nucleation and growth. However, it was recently found that Coulomb interacting electrons on charge-frustrated triangular lattices exhibit supercooled liquid and glass with quantum nature and they crystallize, raising fundamental issues : what features are universal to crystallization at large and specific to that of quantum systems? Here, we report our experimental challenges that address this issue through the spatiotemporal observation of electronic crystallization in an organic material. With Raman microspectroscopy, we are the first to successfully perform real-space and real-time imaging of electronic crystallization. The results directly capture strongly temperature-dependent crystallization profiles indicating that nucleation and growth proceed at distinctive temperature-dependent rates, which is common to conventional crystallization. Remarkably, however, the growth rate is many orders of magnitude larger than that in the conventional case, which is attributable to the quantum effect. The temperature characteristics of nucleation and growth are universal, whereas unusually fast growth kinetics features quantum crystallization where a quantum-to-classical catastrophe occurs in interacting electrons., Comment: 31 pages, 11 figures

Published
2022

6. Effects of Thiophene-Fused Isomer on High-Layered Crystallinity in π-Extended and Alkylated Organic Semiconductors

Author

Higashino, Toshiki, primary, Inoue, Satoru, additional, Arai, Shunto, additional, Tsuzuki, Seiji, additional, Matsui, Hiroyuki, additional, Kumai, Reiji, additional, Takaba, Kiyofumi, additional, Maki-Yonekura, Saori, additional, Kurokawa, Hirofumi, additional, Inoue, Ichiro, additional, Tono, Kensuke, additional, Yonekura, Koji, additional, and Hasegawa, Tatsuo, additional

Published
2024
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13. Highly stable and isomorphic donor–acceptor stacking in a family of n-type organic semiconductors of BTBT–TCNQ derivatives

Author

Matsuoka, Satoshi, primary, Ogawa, Kazuma, additional, Ono, Ryota, additional, Nikaido, Kiyoshi, additional, Inoue, Satoru, additional, Higashino, Toshiki, additional, Tanaka, Mutsuo, additional, Tsutsumi, Jun'ya, additional, Kondo, Ryusuke, additional, Kumai, Reiji, additional, Tsuzuki, Seiji, additional, Arai, Shunto, additional, and Hasegawa, Tatsuo, additional

Published
2022
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14. Emerging Disordered Layered-Herringbone Phase in Organic Semiconductors Unveiled by Electron Crystallography

Author

Inoue, Satoru, primary, Nikaido, Kiyoshi, additional, Higashino, Toshiki, additional, Arai, Shunto, additional, Tanaka, Mutsuo, additional, Kumai, Reiji, additional, Tsuzuki, Seiji, additional, Horiuchi, Sachio, additional, Sugiyama, Haruki, additional, Segawa, Yasutomo, additional, Takaba, Kiyofumi, additional, Maki-Yonekura, Saori, additional, Yonekura, Koji, additional, and Hasegawa, Tatsuo, additional

Published
2021
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34. Environmental Response Sensors Produced Using Bilayer-Type Organic Semiconductors.

Author

Arai, Shunto

Subjects
*ORGANIC semiconductors, *CHEMICAL detectors, *GAS detectors, *THIN film transistors, *DETECTORS, *TRANSISTORS
Abstract

In this study, we developed environmental gas sensors based on bilayer-type organic semiconductors. The number of stacked molecular bilayers was controlled through a solution-based approach. In particular, single molecular bilayers (SMBs) were produced through a geometrical frustration method that can effectively suppress the multiple stacking of bilayers. The layer number-controlled films were utilized to form thin-film transistors (TFTs) to detect the moisture in the air. We revealed that the sensitivity was enhanced in the SMB-based TFTs compared with the TFTs with thicker active layers. These findings are expected to facilitate a new route for producing flexible and lightweight chemical sensors. [ABSTRACT FROM AUTHOR]

Published
2022
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43. Nanoparticle chemisorption printing technique for conductive silver patterning with submicron resolution

Author

Yamada, Toshikazu, primary, Fukuhara, Katsuo, additional, Matsuoka, Ken, additional, Minemawari, Hiromi, additional, Tsutsumi, Jun’ya, additional, Fukuda, Nobuko, additional, Aoshima, Keisuke, additional, Arai, Shunto, additional, Makita, Yuichi, additional, Kubo, Hitoshi, additional, Enomoto, Takao, additional, Togashi, Takanari, additional, Kurihara, Masato, additional, and Hasegawa, Tatsuo, additional

Published
2016
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47. Layered‐Herringbone Polymorphs and Alkyl‐Chain Ordering in Molecular Bilayer Organic Semiconductors.

Author

Arai, Shunto, Morita, Kaede, Tsutsumi, Jun'ya, Inoue, Satoru, Tanaka, Mutsuo, and Hasegawa, Tatsuo

Subjects
*ORGANIC semiconductors, *POLYMORPHIC transformations, *ORGANIC electronics, *OPTICAL spectroscopy, *LIGHT absorption, *PRODUCTION control
Abstract

Production and control of 2D self‐organized layers of π‐conjugated molecules is a fundamental issue in organic electronics devices. This study reports that an intralayer polymorphic transformation is apparently observed in a bilayer‐type layered‐herringbone packing of a series of 2‐mono‐alkylated‐benzothieno[3,2‐b][1]benzothiophenes (mono‐Cn‐BTBTs) with the change in the substituted alkyl‐chain length, n. Slight variation in the intermolecular arrangement in the single‐crystal films is investigated with reasonable sensitivity via polarized optical absorption spectroscopy through the excitonic interactions between neighboring π‐electron cores. A clear polymorphic transition is observed based on the features of the in‐plane optical anisotropy with the change in the chain length between n = 7 (or less) and 8 (or more). A unique phase separation of the polymorphs is also observed in the films produced using a mixed solution with molecules having different n: the respective polymorphic phases appear separately, either as single molecular bilayers or multibilayer‐stacked films owing to geometrical frustration. The results indicate that the intralayer packing motif is predetermined by the competition and balance between the intermolecular core–core and chain–chain interactions. These findings pave the way for rational designing of organic molecules with considerably high layered crystallinity, and thus, of efficient carrier transport in organic thin‐film transistors. [ABSTRACT FROM AUTHOR]

Published
2020
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48. Syneresis-Driven Self-Refilling Printing of Geometry/Component-Controlled Nano/Microstructures.

Author

Shiba K, Saito K, Minami K, Arai S, Yoshikawa G, Sun L, and Tenjimbayashi M

Abstract

Nano/microfabrication is of fundamental importance both in scientific and industrial situations. There are, therefore, many attempts at realizing easier, quicker, and more precise fabrication of various structures; however, achieving this aim without a bulky and costly setup is still challenging. Here, we introduce a facile and versatile means of printing an ordered structure consisting of nanoscale stripes and more complicated geometries including pillars and wavy form with a lateral resolution of single micrometers. To this end, we prepare a polydimethylsiloxane (PDMS) slab with an oxygen plasma-induced wrinkled surface where liquid PDMS exudes by syneresis. Since this liquid PDMS is automatically loaded, the printing is repeatable without inking. A substrate moderately wettable to the liquid PDMS as well as amount/property-controlled syneresis is primarily important for the creation of well-defined structures. Precisely controlling these conditions will make this method universally applicable to diverse substrates and liquids including suspensions., (© 2024 The Author(s). Advanced Science published by Wiley‐VCH GmbH.)

Published
2024
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