Color Modulation in Morpho Butterfly Wings Using Liquid Crystalline Elastomers

Advanced Intelligent Systems Pub Date : 2020-06-14 DOI:10.1002/aisy.202000035

Isabella De Bellis, Bin Ni, D. Martella, C. Parmeggiani, P. Keller, D. Wiersma, Min‐Hui Li, S. Nocentini

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引用次数: 10

Abstract

Nature provides well‐engineered and evolutionary optimized examples of brilliant structural colors in animals and plants. Morpho butterflies are among the well‐known species possessing iridescent bright blue coloration due to multiple optical effects generated by the complex structuration of the wing scales. Such surprising solution can be replicated to fabricate efficient devices. Maybe even more interesting, novel approaches can be developed to combine wings with synthetic smart materials to achieve complex structures responsive to external stimuli. This study demonstrates the proof of concept of an innovative biotic–abiotic hybrid smart structure made by the integration of a butterfly wing with thermoresponsive liquid crystalline elastomers, and their capability to actuate the mechanical action of the wing, thus controlling its spectral response. Exploiting two fabrication strategies, it is demonstrated how different mechanisms of color tuning can be achieved by temperature control. In addition, due to the thermally induced mechanical deformation of the elastomer and superhydrophobic properties of the wing, a potential self‐cleaning behavior of the bilayer material is demonstrated.

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用液晶弹性体调制大闪蝶翅膀的颜色

大自然为动物和植物提供了精心设计和进化优化的明亮结构颜色的例子。大闪蝶是众所周知的物种之一，由于翅膀鳞片的复杂结构产生了多种光学效应，它们具有彩虹般明亮的蓝色。这种令人惊讶的解决方案可以被复制来制造高效的设备。也许更有趣的是，可以开发出新颖的方法，将机翼与合成智能材料结合起来，以实现对外部刺激做出反应的复杂结构。该研究证明了一种创新的生物-非生物混合智能结构的概念，该结构将蝴蝶翅膀与热响应液晶弹性体集成在一起，并证明了它们能够驱动翅膀的机械作用，从而控制其光谱响应。利用两种制造策略，演示了如何通过温度控制来实现不同的颜色调谐机制。此外，由于弹性体的热诱导机械变形和机翼的超疏水性，证明了双层材料的潜在自清洁行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advanced Intelligent Systems

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