Colloidal photonic crystals with tunable reflection wavelengths or intensities derived from their reconfigurable structures

IF 4.7 3区材料科学 Q2 CHEMISTRY, PHYSICAL

Colloid and Interface Science Communications Pub Date : 2024-09-01 DOI:10.1016/j.colcom.2024.100806

Hikaru Namigata , Kanako Watanabe , Tom A.J. Welling , Keishi Suga , Daisuke Nagao

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Abstract

Colloidal photonic crystals (CPCs), which are the ordered assemblies of colloidal particles, can reflect specific wavelengths of light. In particular, CPCs with controllable optical properties are promising materials for advanced photonic applications. Principally, the optical properties of CPCs, i.e., reflection wavelengths and reflection intensities, are controllable. These two characteristics are closely related to the assembled structures of CPCs, especially interplanar spacing and regularity of the assembled structures. The reflection wavelength is proportional to the interplanar spacing of the structure; thus, uniform expanding/contracting of particle-to-particle distance causes red/blue shift of reflection peaks. On the other hand, the regularity affects the reflection intensity; reversible order–disorder transitions enable tuning of the reflection peak intensities. To control the structures of CPCs, various stimuli-responsive polymers and electromagnetic interactions of colloids have been employed. This review explains the above methods and clarifies the future perspectives.

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具有可调反射波长或强度的可重构结构胶体光子晶体

胶体光子晶体（CPCs）是胶体粒子的有序组合，可以反射特定波长的光。特别是，具有可控光学特性的 CPCs 是先进光子应用的理想材料。主要而言，CPC 的光学特性，即反射波长和反射强度是可控的。这两个特性与 CPC 的组装结构密切相关，尤其是组装结构的平面间距和规则性。反射波长与结构的平面间距成正比；因此，粒子与粒子间距的均匀扩展/收缩会导致反射峰的红色/蓝色偏移。另一方面，规则性也会影响反射强度；可逆的有序-无序转变可以调整反射峰强度。为了控制 CPC 的结构，人们采用了各种刺激响应聚合物和胶体的电磁相互作用。本综述解释了上述方法，并阐明了未来的发展前景。

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来源期刊

Colloid and Interface Science Communications Materials Science-Materials Chemistry

CiteScore

9.40

自引率

6.70%

发文量

125

审稿时长

43 days

期刊介绍： Colloid and Interface Science Communications provides a forum for the highest visibility and rapid publication of short initial reports on new fundamental concepts, research findings, and topical applications at the forefront of the increasingly interdisciplinary area of colloid and interface science.