在聚合物/液晶复合材料中通过单步光聚合诱导相分离形成的光学各向异性、电可调微透镜阵列

Wenfeng Cai, Delai Kong, Zongjun Ma, Mengjia Cen, Jiawei Wang, Dandan Yuan, Ke Li, Ming Cheng, Shaolin Xu, D. Luo, Yan-qing Lu, Yanjun Liu
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引用次数: 0

摘要

微透镜或微阵列是许多应用中的关键元素。然而,它们的建造方法涉及多个制造过程,从而增加了制造的复杂性和成本。在这项研究中,我们展示了一个光学各向异性,电可调谐液晶(LC)微透镜阵列使用一个简单的,一步的制造方法。微透镜阵列是在聚合物/LC复合材料内部通过光聚合诱导相分离形成的。它具有偏振依赖性和电可调聚焦和成像特性。在不施加电压的情况下,微透镜阵列的自然焦距为8 mm,这是其固有的梯度折射率分布的结果。当施加高于阈值的电压时,LC分子沿着电场方向重新定向,微透镜阵列的焦距逐渐增大。基于其优越的性能,微透镜阵列进一步用于集成成像应用,展示了电可调的中心深度平面。这种LC微透镜阵列由于其平面、超薄和可调谐的优势,可以找到许多潜在的应用,包括3D显示、光学互连等。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optically anisotropic, electrically tunable microlens arrays formed via single-step photopolymerization-induced phase separation in polymer/liquid-crystal composite materials
Microlenses or arrays are key elements in many applications. However, their construction methods involve multiple fabrication processes, thereby increasing the complexity and cost of fabrication. In this study, we demonstrate an optically anisotropic, electrically tunable liquid crystal (LC) microlens array using a simple, one-step fabrication method. The microlens array is formed via photopolymerization-induced phase separation inside a polymer/LC composite. It possesses both polarization-dependent and electrically tunable focusing and imaging properties. Without applying voltage, the microlens array has a natural focal length of 8 mm, which is a result of its inherent gradient refractive index profile. Upon applying voltage above the threshold, the LC molecules reorient along the electric field direction and the focal length of the microlens array gradually increases. Based on its superior properties, the microlens array is further used for integral imaging applications, demonstrating electrically tunable central depth plane. Such LC microlens arrays could find numerous potential applications owing to their advantageous features of being flat, ultra-thin, and tunable, including 3D displays, optical interconnects, and more.
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CiteScore
10.90
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