학술논문
BEYONDPLANCK
Document Type
article
Author
Herman, D; Hensley, B; Andersen, KJ; Aurlien, R; Banerji, R; Bersanelli, M; Bertocco, S; Brilenkov, M; Carbone, M; Colombo, LPL; Eriksen, HK; Foss, MK; Fuskeland, U; Galeotta, S; Galloway, M; Gerakakis, S; Gjerløw, E; Iacobellis, M; Ieronymaki, M; Ihle, HT; Jewell, JB; Karakci, A; Keihänen, E; Keskitalo, R; Maggio, G; Maino, D; Maris, M; Paradiso, S; Partridge, B; Reinecke, M; Suur-Uski, A-S; Svalheim, TL; Tavagnacco, D; Thommesen, H; Wehus, IK; Zacchei, A
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Subject
Language
Abstract
We constrained the level of polarized anomalous microwave emission (AME) on large angular scales using Planck Low-Frequency Instrument (LFI) and WMAP polarization data within a Bayesian cosmic microwave background (CMB) analysis framework. We modeled synchrotron emission with a power-law spectral energy distribution, as well as the sum of AME and thermal dust emission through linear regression with the Planck High-Frequency Instrument (HFI) 353 GHz data. This template-based dust emission model allowed us to constrain the level of polarized AME while making minimal assumptions on its frequency dependence. We neglected CMB fluctuations, but show through simulations that these fluctuations have a minor impact on the results. We find that the resulting AME polarization fraction confidence limit is sensitive to the polarized synchrotron spectral index prior. In addition, for prior means βsâ