Coronal Photopolarimetry with the LASCO-C2 Coronagraph over 24 Years [1996 – 2019]

We present an in-depth characterization of the polarimetric channel of the Large-Angle Spectrometric COronagraph/LASCO-C2 onboard the Solar and Heliospheric Observatory (SOHO). The polarimetric analysis of the white-light images makes use of polarized sequences composed of three images obtained thou...

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Bibliographic Details
Published in:Solar physics 2020-07, Vol.295 (7)
Main Authors: Lamy, Philippe, Llebaria Antoine, Brice, Boclet, Gilardy Hugo, Burtin, Michael, Floyd, Olivier
Format: Article
Language:English
Subjects:
Astrophysics
Corona
Coronagraphs
Coronal electrons
Electron density
Field of view
Flight tests
Instrumentation and Methods for Astrophysic
Laboratory tests
Light
Observatories
Optical components
Photopolarimetry
Polarimetry
Polarization
Polarizers
Sciences of the Universe
SOHO Mission
Solar and Stellar Astrophysics
Solar cycle
Solar physics
Spectrometry
White light
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Summary:We present an in-depth characterization of the polarimetric channel of the Large-Angle Spectrometric COronagraph/LASCO-C2 onboard the Solar and Heliospheric Observatory (SOHO). The polarimetric analysis of the white-light images makes use of polarized sequences composed of three images obtained though three polarizers oriented at +60∘, 0∘, and −60∘, complemented by a neighboring unpolarized image, and relies on the formalism of Mueller. The Mueller matrix characterizing the C2 instrument was obtained through extensive ground-based calibrations of the optical components and global laboratory tests. Additional critical corrections were derived from in-flight tests relying prominently on roll sequences of SOHO, on the basis of consistency criteria (e.g. the “tangential” direction of polarization), and from several applications, notably the time-dependent tomographic reconstruction of the coronal electron density. This took several years of effort, but resulted in the quasi-uninterrupted photopolarimetric analysis of the corona over two complete Solar Cycles 23 and 24, and the comparison with a variety of eclipse data obtained at different phases of these cycles. Our final results encompass the characterization of the polarization of the white-light corona, of its polarized radiance, of the two-dimensional electron density, and of the K-corona. The agreement with the eclipse data is excellent except for slight discrepancies affecting the innermost part of the C2 field of view. The present work leaves the two unpolarized components, F-corona and stray light, entangled and their complex separation will be dealt with in a follow-on article.
ISSN:0038-0938
1573-093X
DOI:10.1007/s11207-020-01650-y