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未来材料 Vol.2 ~日本の材料分野を牽引する研究者たち~
ISBN:978-4-86469-105-5 C3050
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- 発行所:(株)エヌ・ティー・エス
発刊日 2026年4月10日 頁 数 96頁 造 本 冊子版 B5/PDF版【CD or ダウンロード】(直取引のみ) 発行所 (株)エヌ・ティー・エス ISBN(冊子) 978-4-86469-105-5 C3050 巻頭言 激変する時代の一歩先を読み解く,『未来材料』 相澤益男(科学技術国際交流センター) Best Shot 写真でひもとく未来材料 キトラ古墳壁画の保存修復に使用された材料 早川典子(東京文化財研究所) 現代「ものづくり」考 「いぶきGW」による宇宙からの温室効果ガス・水循環観測の重要性について 小島寧(宇宙航空研究開発機構) 解説Review 単結晶有機半導体とスケーラブルな量子エレクトロニクス Single-crystal organic semiconductors and scalable quantum electronics 竹谷純一(東京大学)水素をつくる光触媒材料の進化と人工光合成への展開 Evolution of photocatalytic materials for hydrogen production and their application to artificial photosynthesis 影島洋介・堂免一成(信州大学)Abstract
Single-crystal organic semiconductors and scalable quantum electronics Junichi TAKEYA It is found that organic semiconductor molecules are self-assembled to large-area single crystal ultra-thin films with simple near-room-temperature process from solution and that the electrons acquire charge coherence essential for high-speed integrated circuits and quantum electronics. This article focuses on the self-assembling solution process, room temperature charge transport mechanism, several practical applications to sensors and integrated computing circuits and recently found quantum features at low temperatures.液体界面の役割とは何か? そして未来への挑戦とは? What are the important roles of liquid interfaces in science? What future challenges lie ahead? 有賀克彦(物質・材料研究機構)Abstract
Evolution of photocatalytic materials for hydrogen production and their application to artificial photosynthesis Yosuke KAGESHIMA and Kazunari DOMEN Photocatalytic water splitting has been considered a promising means of solar energy harvesting in the form of hydrogen. This review article summarizes recent developments of visible-light-responsive photocatalytic particulate materials for water splitting. A simple, economically-feasible method to fabricate a photocatalyst sheet consisting of hydrogen and oxygen-evolving photocatalytic materials is also discussed.OLEDの高性能化 ─ 有機ダブルヘテロ構造と熱活性化遅延蛍光分子の創製 High-performance OLEDs ─Development of organic double heterostructures and thermally activated delayed fluorescence molecules 安達千波矢(九州大学)Abstract
What are the important roles of liquid interfaces in science? What future challenges lie ahead? Katsuhiko ARIGA This review introduces several examples of research using air-water interfaces and considers the essential role of liquid interfaces. Perpendicular to the membrane, electronic properties can be delicately adjusted according to changes in dielectric constant. On the other hand, delicate forces can be applied within the liquid interface. Liquid interfaces provide a field in which intermolecular interactions and structural changes similar to those in living organisms can be delicately adjusted.動く架橋点が高分子材料を変える ─ ポリロタキサンが拓く環動高分子と次世代ビトリマー Movable crosslinks transform polymer materials ─Slide-ring polymers and next-generation vitrimers enabled by polyrotaxanes 安藤翔太・伊藤耕三(東京大学)Abstract
High-performance OLEDs ─Development of organic double heterostructures and thermally activated delayed fluorescence molecules Chihaya ADACHI Thirty years ago, OLEDs were limited to internal EL efficiencies of a few percent and durability of a few hours. Today, they achieve 100% internal quantum efficiency and durability of hundreds of thousands of hours. Thorough consideration of the unique electron-donating and electron-accepting properties of organic materials has driven progress in the development of layered device structures and innovative light-emitting materials. We introduce advances in OLEDs, focusing on the creation of double heterostructures and thermally activated delayed fluorescence (TADF) molecules.エレクトライドの物質科学と応用 Materials science and application of electrides 細野秀雄(東京科学大学)Abstract
Movable crosslinks transform polymer materials ─Slide-ring polymers and next-generation vitrimers enabled by polyrotaxanes Shota ANDO and Kohzo ITO Slide-ring materials form networks in which the crosslinking points, constructed from topological supramolecular structures typified by polyrotaxanes, can move along polymer chains. Such movable crosslinks spontaneously redistribute stress, enabling the simultaneous achievement of high toughness and processability. This article outlines the fundamental concepts of slide-ring materials and discusses the design principles and future perspectives of polyrotaxane-containg vitrimers.タンパク質を未来材料とするリガンド指向性化学 Ligand-directed chemistry enables to make natural proteins functional in vivo 浜地格(京都大学)Abstract
Materials science and application of electrides Hideo HOSONO Electrides are materials in which electrons serve as anions. The first electride was synthesized employing organic ethers as complexant in 1982. However, the materials research was uncultivated due to the fatal drawback of extremely high sensitivity to heat and/or water/O2. This long-standing issue was overcome in 2003 by synthesis of a stable electride using a nanocage crystal 12CaO·7Al2O3. Since then, the materials concept was extended in several aspects: ionic crystals to intermetallics, and from crystalline to amorphous solids in host materials, 0-dimensional to 1 and 2 dimensional materials in electron-confined space and electron-rich to neutral and electron-poor materials in stoichiometry. Found were several intriguing properties such as low work function and large mobility arising from inherent nature. Exploring new electrides by computational approach and high pressure are rapidly advanced. Finally, we propose a concept of an electron-active crystallographic voids as an active structural element for materials designing.リサーチ・ナビ 宇宙戦略基金SX拠点─ 月面開発のための宇宙資源開発拠点 宮本英昭(東京大学) WANTS-NEEDS-SEEDS 超高容量かつ低コストの鉄系全固体フッ化物イオン二次電池正極材料の開発 山本健太郎(奈良女子大学) チャレンジロード 単分散粒子の魅力にひかれて 櫻井和朗(北九州市立大学) 未来への道しるべ 「量子」から光機能材料を眺める 関隆広(名古屋大学) 研究余録:研究者 拓く荒野に 苦楽の碑!(連載 第1回) 光るほど 機能が冴える 分子かな!(前編) ─ 光応答性を示す機能性分子の設計に辿り着いた道程 新海征治(九州大学) 編集委員のSide Notes 冨田育義(東京科学大学)Abstract
Ligand-directed chemistry enables to make natural proteins functional in vivo Itaru HAMACHI Proteins are representative functional biomacromolecules. Their chemical modification is extremely important not only in foundational research of chemical biology, but also for the application of proteins as functional materials of the future. Looking further ahead, the establishment of strategies for chemically modifying target proteins within cells and living environments is crucial, because it enables the sophisticated functionalization of natural proteins precisely in the environments where their activity is desired. Here, we present an overview of selective modification and functionalization strategies in biological systems, based on ligand-directed chemistry (LDchem). Through LDchem-based chemical modification of receptor proteins in the live brain, endogenous membrane-proteins can be directly converted into biosensors or photo-catalysts, enabling in situ analysis of various biological events occurring in the vicinity of target proteins (from nanometer to micrometer scales) within the brains of living organisms.
