Cascaded chiral birefringent media enabled planar lens with programable chromatic aberration

IF 15.7 Q1 OPTICS PhotoniX Pub Date : 2024-05-06 DOI:10.1186/s43074-024-00132-9
Dewei Zhang, Chun-Ting Xu, Quan-Ming Chen, Han Cao, Hong-Guan Yu, Qing-Gui Tan, Yan-qing Lu, Wei Hu
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Abstract

Wavefront control is the fundamental requirement in optical informatics. Planar optics have drawn intensive attention due to the merits of compactness and light weight. However, it remains a challenge to freely manipulate the dispersion, hindering practical applications, especially in imaging. Here, we propose the concept of frequency-synthesized phase engineering to solve this problem. A phasefront-frequency matrix is properly designed to encode different spatial phases to separate frequencies, thus makes arbitrary dispersion tailoring and even frequency-separated functionalization possible. The periodically rotated director endows cholesteric liquid crystal with a spin and frequency selective reflection. Moreover, via presetting the local initial orientation of liquid crystal, geometric phase is encoded to the reflected light. We verify the proposed strategy by cascading the chiral anisotropic optical media of specifically designed helical pitches and initial director orientations. By this means, planar lenses with RGB achromatic, enhanced chromatic aberration and color routing properties are demonstrated. Inch-sized and high-efficient lenses are fabricated with low crosstalk among colors. It releases the freedom of dispersion control of planar optics, and even enables frequency decoupled phase modulations. This work brings new insights to functional planar optics and may upgrade the performance of existing optical apparatuses.

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具有可编程色差的级联手性双折射介质平面透镜
波前控制是光学信息学的基本要求。平面光学因其结构紧凑、重量轻等优点而备受关注。然而,自由操纵色散仍然是一项挑战,阻碍了实际应用,尤其是成像应用。在此,我们提出了频率合成相位工程的概念来解决这一问题。相位前沿-频率矩阵经过适当设计,可将不同的空间相位编码为不同的频率,从而实现任意色散定制,甚至是频率分离功能化。周期性旋转的导向器使胆甾液晶具有自旋和频率选择性反射。此外,通过预设液晶的局部初始方向,几何相位被编码到反射光中。我们通过级联专门设计的螺旋间距和初始导向的手性各向异性光学介质,验证了所提出的策略。通过这种方法,我们展示了具有 RGB消色差、增强色差和色彩路由特性的平面透镜。英寸大小的高效透镜制造出来后,颜色之间的串扰很低。它释放了平面光学的色散控制自由度,甚至实现了频率解耦相位调制。这项工作为功能平面光学带来了新的见解,并可能提升现有光学设备的性能。
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CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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