材料科学
光学成像
限制
液晶
光学
各向同性
光电子学
纳米技术
同质性(统计学)
电子工程
相(物质)
足迹
计算机科学
光束转向
医学影像学
各向异性
移相器
集成光学
生物成像
纳米制造
光开关
生物组织
作者
Xinjie Wu,Xinyuan Jiang,Yong Xie,Zeyu Zhou,Xuejun Zhang,Yubing Han,Sergey I. Bozhevolnyi,Xu Liu,Kai Wei,Mingwei Tang
标识
DOI:10.1002/lpor.202502040
摘要
Abstract Comprehensive multidimensional analysis and systematic integration of structural information in biological specimens are fundamentally essential for elucidating intricate biological processes. However, conventional multimodal imaging techniques are hindered by complex optics and bulky hardware, limiting their clinical utility for point‐of‐care diagnostics and portable healthcare. Here, an integrated multifunctional computational imaging platform based on two cascaded electrically tunable liquid crystal (LC) elements are presented, which can achieve spin‐dependent beam splitting through spatially varying birefringence, allowing for optical differentiation operations by separating circularly polarized components. The anisotropic and isotropic homogeneity of the active LC devices can be switched electrically, thus achieving flexible mode switching among bright‐field imaging, edge‐enhanced imaging, quantitative phase gradient imaging (QPGI), and quantitative phase imaging (QPI). The common‐path optical design significantly reduces the system's footprint while enhancing stability. As a proof‐of‐concept, the applicability of the proposed platform in plant cells are experimentally demonstrated, living animal cells, and animal tissue samples. The results showcase the potential of cascaded active LC elements for developing miniaturized multifunctional imaging systems for high‐contrast biomedical imaging, real‐time analog optical processing, industrial inspection, as well as other high‐precision optical applications.
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