Hasegawa Masatoshi, Shinoda Takehiro, Nakadai Kanata, Ishii Junichi, Okuyama Tetsuo, Tokuda Kaya, Wakui Hiroyuki, Watanabe Naoki, Kitamura Kota
Department of Chemistry, Faculty of Science, Toho University, 2-2-1 Miyama, Funabashi, Chiba 274-8510, Japan.
Toyobo Co., Ltd., Corporate Research Center, 1-1, Katata 2-chome, Otsu-shi, Shiga 520-0292, Japan.
Polymers (Basel). 2025 Jul 7;17(13):1887. doi: 10.3390/polym17131887.
This study presents colorless polyimides (PIs) suitable for use as plastic substrates in flexible displays, designed to be compatible with controlled soft adhesion and easy delamination (temporary adhesion) processes. For this purpose, we focused on a PI system derived from norbornane-2-spiro-α-cyclopentanone-α'-spiro-2″-norbornane-5,5″,6,6″-tetracarboxylic dianhydride (CpODA) and 2,2'-bis(trifluoromethyl)benzidine (TFMB). This system was selected with the aim of exhibiting excellent optical transparency and low linear coefficient of thermal expansion (CTE) properties. However, fabricating this PI film via the conventional two-step process was challenging because of crack formation. In contrast, modified one-pot polymerization at 200 °C using a combined catalyst resulted in a homogeneous solution of PI with an exceptionally high molecular weight, yielding a flexible cast film. The solubility of PI plays a crucial role in its success. This study delves into the mechanism behind the significant catalytic effect on enhancing molecular weight. The CpODA/TFMB PI cast film simultaneously achieved very high optical transparency, an extremely high glass transition temperature ( = 411 °C), a significantly low linear coefficient of thermal expansion (CTE = 16.7 ppm/K), and sufficient film toughness, despite the trade-off between low CTE and high film toughness. The CpODA/TFMB system was modified by copolymerization with minor contents of another cycloaliphatic tetracarboxylic dianhydride, 5,5'-(1,4-phenylene)--bis(hexahydro-4,7-methanoisobenzofuran--1,3-dione) (BzDAxx). This approach was effective in improving the film toughness without sacrificing the low CTE and other target properties. The peel strengths () of laminates comprising surface-modified glass substrates and various colorless PI films were measured to evaluate the compatibility with the temporary adhesion process. Most colorless PI films studied were found to be incompatible. Additionally, no correlation between and PI structure was observed, making it challenging to identify the structural factors influencing control. Surprisingly, a strong correlation was observed between and CTE of the PI films, suggesting that the observed solid-solid lamination is closely linked to the unexpectedly high surface mobility of the PI films. The laminate using CpODA(90);BzDAxx(10)/TFMB copolymer exhibited suitable adhesion strength for the temporary adhesion process, while meeting other target properties. The modified one-pot polymerization method significantly contributed to the development of colorless PIs suitable for plastic substrates.
本研究展示了适用于柔性显示器中作为塑料基板的无色聚酰亚胺(PI),其设计目的是与可控的软粘附和易于分层(临时粘附)工艺兼容。为此,我们专注于一种由降冰片烷-2-螺-α-环戊酮-α'-螺-2″-降冰片烷-5,5″,6,6″-四羧酸二酐(CpODA)和2,2'-双(三氟甲基)联苯胺(TFMB)衍生而来的PI体系。选择该体系的目的是展现出优异的光学透明度和低热膨胀线性系数(CTE)特性。然而,通过传统的两步法制备这种PI薄膜具有挑战性,因为会形成裂纹。相比之下,使用组合催化剂在200℃下进行改性的一锅法聚合得到了具有异常高分子量的PI均匀溶液,从而得到了柔性流延膜。PI的溶解性在其成功中起着关键作用。本研究深入探讨了对提高分子量具有显著催化作用背后的机制。尽管在低CTE和高薄膜韧性之间存在权衡,但CpODA/TFMB PI流延膜同时实现了非常高的光学透明度、极高的玻璃化转变温度(=411℃)、极低的热膨胀线性系数(CTE = 16.7 ppm/K)以及足够的薄膜韧性。通过与少量另一种脂环族四羧酸二酐5,5'-(1,4-亚苯基)-双(六氢-4,7-亚甲基异苯并呋喃-1,3-二酮)(BzDAxx)共聚对CpODA/TFMB体系进行了改性。这种方法有效地提高了薄膜韧性,同时又不牺牲低CTE和其他目标性能。测量了包含表面改性玻璃基板和各种无色PI薄膜的层压板的剥离强度(),以评估与临时粘附工艺的兼容性。研究发现大多数无色PI薄膜不兼容。此外,未观察到与PI结构之间的相关性,这使得识别影响控制的结构因素具有挑战性。令人惊讶的是,可以观察到PI薄膜的与CTE之间存在很强的相关性,这表明观察到的固-固层压与PI薄膜出人意料的高表面迁移率密切相关。使用CpODA(90);BzDAxx(10)/TFMB共聚物的层压板在满足其他目标性能的同时,展现出了适用于临时粘附工艺的粘附强度。改性的一锅法聚合方法对开发适用于塑料基板的无色PI做出了重大贡献。
