日本接着学会誌 61 巻, 5 号

UV/EB 硬化性モノマーおよびオリゴマー

紫外線（UV）/電子線（EB）硬化材料は，UVやEBを照射することで硬化する材料であり，使用する波長としては，UVや短波長の可視光線がある。重合形式として，ラジカル重合，カチオン重合などがあり，無溶剤化が可能，硬化速度が速い事，架橋構造を有する硬化物となるため耐熱性や耐溶剤性に優れる事，が挙げることができる。本稿ではアクリレートを中心としたUV/EB 硬化性のモノマーおよびオリゴマーについて述べる。併せて，近年，ニーズの高まっている環境配慮型の材料として，バイオマスアクリレートの紹介も行う。

光重合開始剤の種類と特性

Photoinitiators are considered one of the essential components in UV curing technology. According to the kind of active species generated by UV irradiation, photoinitiators can be classified by radical and cationic types. In Japan, the majority of the market is dominated by radical photoinitiators. This paper aims to introduce radical-based photoinitiators, discuss the current toxicological classifications in Europe, and present new products that could serve as alternatives to fulfill future needs in terms of both regulatory and technology.

精密UV硬化技術の開発動向と応用展開

UV硬化技術は，印刷インキ，塗料，コーティング，接着などに汎用され，産業上も重要な製造プロセスの1 つである。迅速な光ラジカル重合に精密ラジカル重合機構を組み込むことで，硬化と同時に重合誘起型ミクロ相分離に基づくユニークな内部構造が形成できることを見出した。高分子ドーマントと呼ばれる開始・制御剤の分子設計，UV 硬化条件とナノ構造の相関，コーティングの機能化を例に，精密UV 硬化技術について概説する。

自己組織化が拓く半導体微細加工の革新

Directed self-assembly（DSA）of block copolymers（BCPs）has emerged as a promising nanofabrication technique to complement extreme ultraviolet, EUV, lithography in next-generation semiconductor manufacturing. This review highlights the background and fundamental principles of DSA, including chemical guiding patterns, neutral layers, and annealing processes, with a focus on pattern multiplication and rectification. From a materials perspective, we first discuss polystyrene-block-poly（methyl methacrylate）（PS-b-PMMA）, which has been widely used due to its excellent phase separation, thermal annealing compatibility, and dry etching suitability, but its low χ parameter limits sub-10 nm patterning. We then present our development of a higher-χ BCP, polystyrene-block-poly（glycidyl methacrylate-random-methyl methacrylate）functionalized with 2,2,2-trifluoroethanethiol（PS-b-PGFM）, which achieves stable vertical lamellae with domain spacings down to 12.4 nm and is compatible with existing PS-r-PMMA-r-poly（hydroxyethyl methacrylate）（PHEMA）neutral layers, showing defect-free DSA performance on 300 mm wafers. Additionally, we introduce a novel PS-b-PMMA derivative incorporating hydroxyl groups at the block junction, exhibiting dual functionality as both a neutral layer and a thin film material. These advancements provide new insights into the design of BCP-based nanopatterning materials and their integration with interface engineering technologies.

液晶物質の光配向技術と関連するプロセス

Photoalignment technology utilizes the duality of light, namely particle and wave properties. A surface photoreactive layer can capture both energy and wave properties from light. This combined stimulus enables the photoalignment of liquid crystals（LCs）when they get contact with the photoalignment layer. Azobenzene is a typical photochromic unit for this application. This article briefly describes the principle of photoalignment process that has recently become more important in the fabrication of LC display panels. Some other related topics involving the high-density photoresponsive polymer chain brush systems, photoalignment of LC films from the free（air）surface, surface relief grating formation via patterned light illumination, and surface fabrication via Marangoni flow, are introduced. Most of these phenomena involve dynamic collective molecular interactions at interfaces, and thus should be of help for understanding soft adhesion processes taking place in organized molecular systems.

放射線誘起反応を駆使した生体模倣システムの開発

Safety and efficacy of medicines, chemicals, drugs, cosmetics, and food have been confirmed through animal testing. However, the results of animal testing do not always apply to humans; for example, the success rate of new drug development is only about 1 in 30,000. In addition to economic issues, there are also ethical issues, and a new evaluation method is required to replace animal testing. One method that is particularly expected to be highly accurate is microphysiological systems (MPS), which place tissue models and organoids made from human cells and stem cells in microfluidic chips. MPS is expected to make it possible to evaluate the efficacy and side effects of drugs, including the interactions between organs and tissues through systemic circulation. To realize MPS, it is essential to create a culture environment in which cells can respond in the same way as in the body, and to create microfluidic chips that can accurately evaluate the responses of cells and organoids. We are attempting to solve these issues using material processing techniques that utilize ionizing radiation, such as electron beams, gamma-rays, and ion beams. This article introduces three research examples from various attempts in which control of the“ adhesion” and“ interfaces” of biomaterials is key.