Abstract
Investigating celestial polarization patterns in the case of different environments is important for exploring the atmospheric radiative transfer mechanism. Although intensive studies on clear sky, foggy sky, and even total solar eclipse sky have been conducted, the polarization distribution generated by the moonlight has not been well investigated. This study analyzes celestial polarization patterns generated by the Super Blue Blood Moon (SBBM) through several comparative studies. The polarization patterns under the SBBM are collected, analyzed, and compared with both those generated by the ideal single-scattering Rayleigh model and those in the normal sky. From the analysis of the relative variation of the celestial polarization characteristics including the Degree of Polarization (DoP) and Angle of Polarization (AoP), the changes of the extremum, frequency, symmetric line, and neutral points are discussed. As a result, SBBM polarization patterns change at the beginning of the partial eclipse, and the neutral points vary from traditional neutral points. The value of DoP gradually decreases as the obscuration ratio of the Moon increases. The AoP is no longer symmetrical about the celestial meridian. As a conclusion, it is suggested that the variation of the polarized skylight during the SBBM should be considered in atmospheric model calculation for nocturnal biological activity and navigation information computation.
Highlights
IntroductionSkylight polarization significantly impacts biological orientation [1,2,3]
Caused by atmospheric scattering, skylight polarization significantly impacts biological orientation [1,2,3]
The Degree of Polarization (DoP; Table S1) and Angle of Polarization (AoP; Table S2) from the celestial patterns measured during the Super Blue Blood Moon (SBBM) are presented in the first and second columns, respectively
Summary
Skylight polarization significantly impacts biological orientation [1,2,3]. Many animals, including bees [4], bats [5], spiders [6,7], and dung beetles [8], can sense the polarized light generated by sunlight or moonlight. The polarized light serves as a compass cue [9,10]. Skylight polarization is a viable option for navigation [11,12] and remote sensing [13,14]. Atmospheric polarization applications have expanded to include atmospheric sunlit sky polarization [18], in-water polarization [19,20], and moonlit sky polarization [21,22]
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