Coordination-bond-assisted fabrication of robust composite photonic crystal films through melt-compression†

IF 6 2区 材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Jiahao Li, Tongling Yu, Chengcai Wu, Qianyao Fang and Xin Su
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Abstract

Embedding photonic crystals (PCs) into a polymer matrix and directly promoting the interactions between building blocks through various forces (such as coordination bonds) are effective strategies for fabricating robust PC films. However, owing to the adverse effect of metal salts on electrostatic repulsion during an assembly process, coordination bonds have long been ignored as an effective force for strengthening PC films. Herein, monodisperse PS@PEA-PAA core–shell spheres were prepared through a stepwise emulsion polymerization process, and a complex with ZnCl2 to serve as a precursor for PC films was formed. Under vertical compression at elevated temperatures, polymer shell melt drove the assembly of PS cores into highly ordered arrays with steric repulsion as the necessary balancing force and locked the whole structure. With 1 mL of AA monomer added to PS@PEA-PAA building blocks and 2 mmol of ZnCl2 added to form a complex precursor, compared with the results of PS@PEA PC films, coordination bonds in PS@PEA-PAA composite PC films induced a 420.8% increase in Young's modulus, which clearly demonstrates the impressive ability of coordination bonds to promote mechanical properties. Blue, green and red PC films were prepared as the basic elements using 225 nm, 265 nm and 310 nm PS@PEA-PAA spheres as building blocks, respectively, which can be further combined selectively into cyan, violet and yellow PC films following the additive color mixing rule. The robust free-stranding PC films can be further tailored and recombined into PC patterns with versatile designing styles and abundant optional structural colors, demonstrating great value for practical applications.

Abstract Image

Abstract Image

配位键辅助通过熔融压缩制造坚固的复合光子晶体薄膜
将光子晶体(PC)嵌入聚合物基体,并通过各种作用力(如配位键)直接促进构件之间的相互作用,是制造坚固 PC 薄膜的有效策略。然而,由于金属盐在组装过程中会对静电排斥产生不利影响,配位键作为一种强化 PC 薄膜的有效作用力长期以来一直被忽视。本文通过分步乳液聚合工艺制备了单分散 PS@PEA-PAA核壳球,并与 ZnCl2 形成复合物作为 PC 薄膜的前驱体。在高温垂直压缩条件下,聚合物外壳熔体以立体斥力作为必要的平衡力,推动 PS 内核组装成高度有序的阵列,并锁定整个结构。在 PS@PEA-PAA 构建模块中加入 1 mL AA 单体,再加入 2 mmol ZnCl2 形成复合前体,与 PS@PEA PC 薄膜的结果相比,PS@PEA-PAA 复合 PC 薄膜中的配位键使杨氏模量增加了 420.8%,这清楚地表明了配位键促进机械性能的惊人能力。以 225 nm、265 nm 和 310 nm 的 PS@PEA-PAA 球体为基本元素,分别制备出了蓝色、绿色和红色 PC 薄膜。这种坚固的自由串联 PC 薄膜可进一步定制和重新组合成 PC 图案,设计风格多样,结构颜色可选性丰富,具有极高的实际应用价值。
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来源期刊
Materials Chemistry Frontiers
Materials Chemistry Frontiers Materials Science-Materials Chemistry
CiteScore
12.00
自引率
2.90%
发文量
313
期刊介绍: Materials Chemistry Frontiers focuses on the synthesis and chemistry of exciting new materials, and the development of improved fabrication techniques. Characterisation and fundamental studies that are of broad appeal are also welcome. This is the ideal home for studies of a significant nature that further the development of organic, inorganic, composite and nano-materials.
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