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Abstract
Optical polarization imaging has played an important role in many biological and biomedical applications, as it provides a label-free and non-invasive detection scheme to reveal the polarization information of optical rotation, birefringence, and photoelasticity distribution inherent in biological samples. However, the imaging speeds of the previously demonstrated polarization imaging techniques were often limited by the slow frame rates of the arrayed imaging detectors, which usually run at frame rates of several hundred hertz. By combining the optical coherent detection of orthogonal polarizations and the optical time-stretch imaging technique, we achieved ultrafast polarization bio-imaging at an extremely fast record line scanning rate up to 100 MHz without averaging. We experimentally demonstrated the superior performance of our method by imaging three slices of different kinds of biological samples with the retrieved Jones matrix and polarization-sensitive information including birefringence and diattenuation. The proposed system in this paper may find potential applications for ultrafast polarization dynamics in living samples or some other advanced biomedical research.
Highlights
Optical polarization imaging detects the changes in the polarization states of light after passing through or being reflected by polarization-sensitive samples through a combination of a polarizer and an analyzer [1]
Since imaging polarization information with an ultrahigh temporal resolution is essential in understanding ultrafast polarization-sensitive dynamics, developing an ultrafast polarization imaging system is highly desirable
We present a coherent detection and time-stretch based ultrafast polarization imaging system that is capable of delivering spatially dependent Jones matrix of biological samples with a record line scanning rate up to 100 MHz without averaging
Summary
Optical polarization imaging detects the changes in the polarization states of light after passing through or being reflected by polarization-sensitive samples through a combination of a polarizer and an analyzer [1]. These changes, which are normally related to optical rotation, birefringence, and photoelastic effect, are difficult to be detected or sensed using conventional light intensity- and phase-based imaging systems [2]. Since imaging polarization information with an ultrahigh temporal resolution is essential in understanding ultrafast polarization-sensitive dynamics, developing an ultrafast polarization imaging system is highly desirable
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