Abstract
Probing the polarization response of an object with the well-acknowledged technique of optical polarimetry enables determination of the specimen’s inner properties. Prominent examples include the measurement of the chirality of proteins and molecules [1] or the induced anisotropy of disease-affected cells and tissues [2]. Aiming for better signal-to-noise ratio, lower photon flux of the probing beam and non-local diagnostics, polarimetric approaches employing the quantum nature of light and entanglement are currently rapidly developing [6] without necessity for full density matrix reconstruction of the quantum state.
© 2023 IEEE
PDF ArticleMore Like This
Audrey Eshun, Xiyu Yi, Ashleigh Wilson, Sam Jeppson, Shervin Kiannejad, Mike Rushford, Tiziana Bond, and Ted Laurence
JTh2A.34 CLEO: Applications and Technology (CLEO:A&T) 2023
Matthew Reichert, Hugo Defienne, and Jason W. Fleischer
JW4A.31 Frontiers in Optics (FiO) 2017
Korenobu Matsuzaki and Tahei Tahara
ch_9_1 The European Conference on Lasers and Electro-Optics (CLEO/Europe) 2023