Litcius/Paper detail

Characterization of a dual-beam, dual-camera optical imaging polarimeter

Manisha Shrestha, I. A. Steele, A. S. Piascik, Helen Jermak, R. J. Smith, C. M. Copperwheat

2020Monthly Notices of the Royal Astronomical Society32 citationsDOIOpen Access PDF

Abstract

ABSTRACT Polarization plays an important role in various time-domain astrophysics to understand the magnetic fields, geometry, and environments of spatially unresolved variable sources. In this paper we present the results of laboratory and on-sky testing of a novel dual-beam, dual-camera optical imaging polarimeter (MOPTOP) exploiting high sensitivity, low-noise CMOS technology, and designed to monitor variable and transient sources with low systematic errors and high sensitivity. We present a data reduction algorithm that corrects for sensitivity variations between the cameras on a source-by-source basis. Using our data reduction algorithm, we show that our dual-beam, dual-camera technique delivers the benefits of low and stable instrumental polarization (<0.05 per cent for lab data and <0.25 per cent for on sky data) and high throughput while avoiding the additional sky brightness and image overlap problems associated with dual-beam, single-camera polarimeters.

Topics & Concepts

PolarimeterPhysicsOpticsPolarimetryBrightnessSensitivity (control systems)Polarization (electrochemistry)SkyRemote sensingAstronomyElectronic engineeringPhysical chemistryEngineeringChemistryGeologyScatteringStellar, planetary, and galactic studiesGamma-ray bursts and supernovaeSolar and Space Plasma Dynamics