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FOREGROUNDS IN WIDE-FIELD REDSHIFTED 21 cm POWER SPECTRA

Authors :
Haystack Observatory
Massachusetts Institute of Technology. Department of Physics
MIT Kavli Institute for Astrophysics and Space Research
Cappallo, Roger J.
Corey, Brian E.
de Oliveira-Costa, Angelica
Dillon, Joshua Shane
Ewall-Wice, Aaron Michael
Feng, L.
Goeke, Robert F.
Hewitt, Jacqueline N.
Kratzenberg, Eric W.
Lonsdale, Colin John
McWhirter, Stephen R.
Morgan, Edward H.
Neben, Abraham Richard
Rogers, Alan E. E.
Tegmark, Max Erik
Whitney, Alan R.
Williams, Christopher Leigh
Haystack Observatory
Massachusetts Institute of Technology. Department of Physics
MIT Kavli Institute for Astrophysics and Space Research
Cappallo, Roger J.
Corey, Brian E.
de Oliveira-Costa, Angelica
Dillon, Joshua Shane
Ewall-Wice, Aaron Michael
Feng, L.
Goeke, Robert F.
Hewitt, Jacqueline N.
Kratzenberg, Eric W.
Lonsdale, Colin John
McWhirter, Stephen R.
Morgan, Edward H.
Neben, Abraham Richard
Rogers, Alan E. E.
Tegmark, Max Erik
Whitney, Alan R.
Williams, Christopher Leigh
Source :
IOP Publishing
Publication Year :
2015

Abstract

Detection of 21 cm emission of H i from the epoch of reionization, at redshifts z > 6, is limited primarily by foreground emission. We investigate the signatures of wide-field measurements and an all-sky foreground model using the delay spectrum technique that maps the measurements to foreground object locations through signal delays between antenna pairs. We demonstrate interferometric measurements are inherently sensitive to all scales, including the largest angular scales, owing to the nature of wide-field measurements. These wide-field effects are generic to all observations but antenna shapes impact their amplitudes substantially. A dish-shaped antenna yields the most desirable features from a foreground contamination viewpoint, relative to a dipole or a phased array. Comparing data from recent Murchison Widefield Array observations, we demonstrate that the foreground signatures that have the largest impact on the H i signal arise from power received far away from the primary field of view. We identify diffuse emission near the horizon as a significant contributing factor, even on wide antenna spacings that usually represent structures on small scales. For signals entering through the primary field of view, compact emission dominates the foreground contamination. These two mechanisms imprint a characteristic pitchfork signature on the "foreground wedge" in Fourier delay space. Based on these results, we propose that selective down-weighting of data based on antenna spacing and time can mitigate foreground contamination substantially by a factor of ~100 with negligible loss of sensitivity.<br />National Science Foundation (U.S.) (Award AST-1109257)

Details

Database :
OAIster
Journal :
IOP Publishing
Notes :
application/pdf, en_US
Publication Type :
Electronic Resource
Accession number :
edsoai.on1141884995
Document Type :
Electronic Resource