Subwavelength imaging using a solid-immersion diffractive optical processor

IF 27.2 Q1 OPTICS
eLight Pub Date : 2024-06-13 DOI:10.1186/s43593-024-00067-5
Jingtian Hu, Kun Liao, Niyazi Ulas Dinç, Carlo Gigli, Bijie Bai, Tianyi Gan, Xurong Li, Hanlong Chen, Xilin Yang, Yuhang Li, Çağatay Işıl, Md Sadman Sakib Rahman, Jingxi Li, Xiaoyong Hu, Mona Jarrahi, Demetri Psaltis, Aydogan Ozcan
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引用次数: 0

Abstract

Phase imaging is widely used in biomedical imaging, sensing, and material characterization, among other fields. However, direct imaging of phase objects with subwavelength resolution remains a challenge. Here, we demonstrate subwavelength imaging of phase and amplitude objects based on all-optical diffractive encoding and decoding. To resolve subwavelength features of an object, the diffractive imager uses a thin, high-index solid-immersion layer to transmit high-frequency information of the object to a spatially-optimized diffractive encoder, which converts/encodes high-frequency information of the input into low-frequency spatial modes for transmission through air. The subsequent diffractive decoder layers (in air) are jointly designed with the encoder using deep-learning-based optimization, and communicate with the encoder layer to create magnified images of input objects at its output, revealing subwavelength features that would otherwise be washed away due to diffraction limit. We demonstrate that this all-optical collaboration between a diffractive solid-immersion encoder and the following decoder layers in air can resolve subwavelength phase and amplitude features of input objects in a highly compact design. To experimentally demonstrate its proof-of-concept, we used terahertz radiation and developed a fabrication method for creating monolithic multi-layer diffractive processors. Through these monolithically fabricated diffractive encoder-decoder pairs, we demonstrated phase-to-intensity \(({\varvec{P}}\to {\varvec{I}})\) transformations and all-optically reconstructed subwavelength phase features of input objects (with linewidths of ~ λ/3.4, where λ is the illumination wavelength) by directly transforming them into magnified intensity features at the output. This solid-immersion-based diffractive imager, with its compact and cost-effective design, can find wide-ranging applications in bioimaging, endoscopy, sensing and materials characterization.

Abstract Image

使用固体浸入式衍射光学处理器进行亚波长成像
相位成像被广泛应用于生物医学成像、传感和材料表征等领域。然而,以亚波长分辨率对相位对象进行直接成像仍是一项挑战。在此,我们展示了基于全光学衍射编码和解码的相位和振幅对象亚波长成像。为了分辨物体的亚波长特征,衍射成像仪使用薄的高指数固体浸透层将物体的高频信息传输到空间优化的衍射编码器,该编码器将输入的高频信息转换/编码为低频空间模式,以便在空气中传输。随后的衍射解码器层(在空气中)通过基于深度学习的优化与编码器共同设计,并与编码器层通信,在其输出端创建输入物体的放大图像,揭示因衍射限制而被冲走的亚波长特征。我们证明,这种衍射固体浸入式编码器与后续空气中解码器层之间的全光学协作,能够以高度紧凑的设计解析输入物体的亚波长相位和振幅特征。为了在实验中证明其概念,我们使用了太赫兹辐射,并开发了一种制造单片多层衍射处理器的方法。通过这些单片制造的衍射编码器-解码器对,我们演示了相位-强度(({\varvec{P}}\to {\varvec{I}})转换,并通过在输出端直接将输入对象(线宽约为λ/3.4,其中λ为照明波长)的放大强度特征转换为亚波长相位特征,从而实现了全光学重建。这种基于固体浸透技术的衍射成像仪结构紧凑、成本低廉,可广泛应用于生物成像、内窥镜检查、传感和材料表征等领域。
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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来源期刊
CiteScore
30.40
自引率
0.00%
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