Add to BibSonomy
Abstract
We present a novel, to the best of our knowledge, form of polarization microscopy capable of producing quantitative optic-axis and phase retardation maps of transparent and anisotropic materials. The proposed method operates on differential phase-contrast (DPC) microscopy that produces a phase image of a thin specimen using multi-axis intensity measurements. For polarization-sensitive imaging, patterned illumination light is circularly polarized to illuminate a specimen. The light transmitted through a specimen is split into two orthogonal polarization states and measured by an image sensor. Subsequent DPC computation based on the illumination patterns, acquired images, and the imaging model enables the retrieval of polarization-dependent quantitative phase images, which are utilized to reconstruct the orientation and retardation of the specimen. We demonstrate the validity of the proposed method by measuring the optic-axis and phase retardation maps of calibrated and various anisotropic samples.
© 2021 Optical Society of America
Full Article | PDF ArticleMore Like This
Soocheol Kim, Barry Cense, and Chulmin Joo
Opt. Lett. 45(14) 3965-3968 (2020)
Baekcheon Seong, Ingyoung Kim, Taegyun Moon, Malith Ranathunga, Daesuk Kim, and Chulmin Joo
Opt. Lett. 48(13) 3607-3610 (2023)
Yongshuai Ge, Jianwei Chen, Jiecheng Yang, Peiping Zhu, Huitao Zhang, Hairong Zheng, and Dong Liang
Opt. Lett. 46(11) 2791-2794 (2021)