High-resolution Linear Polarimetric Imaging for the Event Horizon Telescope
Abstract
Images of the linear polarizations of synchrotron radiation around active galactic nuclei (AGNs) highlight their projected magnetic field lines and provide key data for understanding the physics of accretion and outflow from supermassive black holes. The highest-resolution polarimetric images of AGNs are produced with Very Long Baseline Interferometry (VLBI). Because VLBI incompletely samples the Fourier transform of the source image, any image reconstruction that fills in unmeasured spatial frequencies will not be unique and reconstruction algorithms are required. In this paper, we explore some extensions of the Maximum Entropy Method (MEM) to linear polarimetric VLBI imaging. In contrast to previous work, our polarimetric MEM algorithm combines a Stokes I imager that only uses bispectrum measurements that are immune to atmospheric phase corruption, with a joint Stokes Q and U imager that operates on robust polarimetric ratios. We demonstrate the effectiveness of our technique on 7 and 3 mm wavelength quasar observations from the VLBA and simulated 1.3 mm Event Horizon Telescope observations of Sgr A* and M87. Consistent with past studies, we find that polarimetric MEM can produce superior resolution compared to the standard CLEAN algorithm, when imaging smooth and compact source distributions. As an imaging framework, MEM is highly adaptable, allowing a range of constraints on polarization structure. Polarimetric MEM is thus an attractive choice for image reconstruction with the EHT.
Additional Information
© 2016. The American Astronomical Society. Received 2015 December 4; revised 2016 June 8; accepted 2016 July 6; published 2016 September 14. We thank the National Science Foundation (AST-1310896, AST-1312034, AST-1211539, and AST-1440254) and the Gordon and Betty Moore Foundation (#GBMF-3561) for financial support of this work. R.N.'s research was supported in part by NSF grant AST1312651 and NASA grant TCAN NNX14AB47G. K.B. was supported by NSF CGV-1111415 and a NSF Graduate Fellowship. We thank Svetlana Jorstad, Alan Marscher, and Kazuhiro Hada for providing the data imaged in Section 5.2 and for their helpful comments. We thank Avery Broderick, Jason Dexter, and Roman Gold for generously providing model images. We also thank Lindy Blackburn for his help on simulating gain and phase errors and Kazunori Akiyama for his suggestion of applying total variation as a polarimetric regularizer. We thank the anonymous referee, whose thorough suggestions significantly improved this paper. This study makes use of 43 GHz VLBA data from the VLBA-BU Blazar Monitoring Program (VLBA-BU-BLAZAR; http://www.bu.edu/blazars/VLBAproject.html), funded by NASA through the Fermi Guest Investigator Program. The VLBA is an instrument of the National Radio Astronomy Observatory. The National Radio Astronomy Observatory is a facility of the National Science Foundation that is operated by Associated Universities, Inc.Attached Files
Published - Chael_2016_ApJ_829_11.pdf
Accepted Version - 1605.06156.pdf
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Additional details
- Eprint ID
- 94516
- Resolver ID
- CaltechAUTHORS:20190405-150444073
- AST-1310896
- NSF
- AST-1312034
- NSF
- AST-1211539
- NSF
- AST-1440254
- NSF
- GBMF-3561
- Gordon and Betty Moore Foundation
- AST-1312651
- NSF
- NNX14AB47G
- NASA
- CGV-1111415
- NSF
- NSF Graduate Research Fellowship
- Created
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2019-04-05Created from EPrint's datestamp field
- Updated
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2021-11-16Created from EPrint's last_modified field