Supraparticles with Tailored Absorption and Their Optical Performance as Photonic Pigments in Sustainable Water-Based Paint

ACS Applied Optical Materials Pub Date : 2025-04-17 DOI:10.1021/acsaom.5c0008010.1021/acsaom.5c00080

Tom A. J. Welling*, Keisuke Kurioka, Gantulga Tuguldur, Natsuho Tsunetomi, Hikaru Namigata, Keishi Suga, Kanako Watanabe and Daisuke Nagao,

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引用次数: 0

Abstract

Many traditional pigments and dyes are toxic or have low photostability, causing environmental concerns. On the other hand, structural color photonic pigments, which derive their color from reflectance of light rather than absorption, can be made from sustainable, inexpensive materials and are nonfading. Supraparticles, which are spherical assemblies of colloidal particles, reflect light of a certain wavelength, depending on the particle size of the building blocks. In this work, we synthesized building blocks with an optimized scattering-to-absorption ratio by employing a polydopamine coating and created supraparticles via bulk emulsification and osmotic extraction. We evaluated the optical performance of water-based paint containing supraparticles of different sizes, polydispersities, structures, and degrees of absorption. We found that a larger size and higher polydispersity of the supraparticles led to paints with a wider reflection peak. The degree of crystallinity of the supraparticles, which decreased for polydopamine-coated compared to uncoated particles and was tuned via the osmotic pressure difference between droplets, had a comparatively smaller impact on the optical performance. Additionally, the scattering-to-absorption ratio of the building blocks allowed us to precisely tune the color in the paints. After these optimizations, the photonic supraparticle paints were used to paint several drawings to showcase their applicability, providing guidelines for high-quality photonic supraparticle pigments in water-based paints.

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可持续水性涂料中具有定制吸收的超粒子及其光子颜料的光学性能

许多传统颜料和染料有毒或光稳定性低，引起环境问题。另一方面，结构色光子颜料，其颜色来源于光的反射而不是吸收，可以用可持续的、廉价的材料制成，并且不褪色。超粒子是胶体粒子的球形集合，根据构建块的颗粒大小反射一定波长的光。在这项工作中，我们利用聚多巴胺涂层合成了具有优化散射吸收比的构建模块，并通过体积乳化和渗透萃取制备了超颗粒。我们评估了含有不同尺寸、多分散度、结构和吸收程度的超颗粒的水性涂料的光学性能。我们发现，超粒子的尺寸越大，多分散性越高，涂料的反射峰越宽。与未包覆的粒子相比，包覆聚多巴胺的超粒子的结晶度降低，并通过液滴之间的渗透压差进行调节，对光学性能的影响相对较小。此外，建筑块的散射吸收比使我们能够精确地调整油漆的颜色。在这些优化之后，用光子超粒子颜料绘制了几幅图，展示了它们的适用性，为高质量的光子超粒子颜料在水性涂料中的应用提供了指导。

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来源期刊

ACS Applied Optical Materials 材料科学-光学材料-

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： ACS Applied Optical Materials is an international and interdisciplinary forum to publish original experimental and theoretical including simulation and modeling research in optical materials complementing the ACS Applied Materials portfolio. With a focus on innovative applications ACS Applied Optical Materials also complements and expands the scope of existing ACS publications that focus on fundamental aspects of the interaction between light and matter in materials science including ACS Photonics Macromolecules Journal of Physical Chemistry C ACS Nano and Nano Letters.The scope of ACS Applied Optical Materials includes high quality research of an applied nature that integrates knowledge in materials science chemistry physics optical science and engineering.