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Published July 15, 2020 | Published + Submitted
Journal Article Open

Atacama Cosmology Telescope: Component-separated maps of CMB temperature and the thermal Sunyaev-Zel'dovich effect

Madhavacheril, Mathew S. ORCID icon
Hill, J. Colin
Næss, Sigurd
Addison, Graeme E.
Aiola, Simone
Baildon, Taylor
Battaglia, Nicholas
Bean, Rachel
Bond, J. Richard ORCID icon
Calabrese, Erminia
Calafut, Victoria
Choi, Steve K.
Darwish, Omar
Datta, Rahul
Devlin, Mark J.
Dunkley, Joanna
Dünner, Rolando
Ferraro, Simone
Gallardo, Patricio A.
Gluscevic, Vera
Halpern, Mark ORCID icon
Han, Dongwon
Hasselfield, Matthew
Hilton, Matt
Hincks, Adam D.
Hložek, Renée
Ho, Shuay-Pwu Patty
Huffenberger, Kevin M. ORCID icon
Hughes, John P.
Koopman, Brian J.
Kosowsky, Arthur
Lokken, Martine
Louis, Thibaut
Lungu, Marius
MacInnis, Amanda
Maurin, Loïc
McMahon, Jeffrey J.
Moodley, Kavilan
Nati, Federico
Niemack, Michael D.
Page, Lyman A. ORCID icon
Partridge, Bruce
Robertson, Naomi
Sehgal, Neelima
Schaan, Emmanuel
Schillaci, Alessandro
Sherwin, Blake D.
Sifón, Cristóbal ORCID icon
Simon, Sara M.
Spergel, David N. ORCID icon
Staggs, Suzanne T.
Storer, Emilie R.
van Engelen, Alexander
Vavagiakis, Eve M.
Wollack, Edward J. ORCID icon
Xu, Zhilei

Abstract

Optimal analyses of many signals in the cosmic microwave background (CMB) require map-level extraction of individual components in the microwave sky, rather than measurements at the power spectrum level alone. To date, nearly all map-level component separation in CMB analyses has been performed exclusively using satellite data. In this paper, we implement a component separation method based on the internal linear combination (ILC) approach which we have designed to optimally account for the anisotropic noise (in the 2D Fourier domain) often found in ground-based CMB experiments. Using this method, we combine multifrequency data from the Planck satellite and the Atacama Cosmology Telescope Polarimeter (ACTPol) to construct the first wide-area (≈2100 sq. deg.), arcminute-resolution component-separated maps of the CMB temperature anisotropy and the thermal Sunyaev-Zel'dovich (tSZ) effect sourced by the inverse-Compton scattering of CMB photons off hot, ionized gas. Our ILC pipeline allows for explicit deprojection of various contaminating signals, including a modified blackbody approximation of the cosmic infrared background (CIB) spectral energy distribution. The cleaned CMB maps will be a useful resource for CMB lensing reconstruction, kinematic SZ cross-correlations, and primordial non-Gaussianity studies. The tSZ maps will be used to study the pressure profiles of galaxies, groups, and clusters through cross-correlations with halo catalogs, with dust contamination controlled via CIB deprojection. The data products described in this paper are available on LAMBDA.

Additional Information

© 2020 American Physical Society. Received 5 December 2019; accepted 17 June 2020; published 22 July 2020. We are grateful to Hans Kristian Eriksen, Reijo Keskitalo, and Mathieu Remazeilles for informative discussions related to Planck products and analysis. Some of the results in this paper have been derived using the healpy [126] and healpix [127] packages. This research made use of Astropy,8 a community-developed core python package for Astronomy [128,129]. We also acknowledge use of the matplotlib [130] package and the Python Image Library for producing plots in this paper, and use of the Boltzmann code camb [97] for calculating theory spectra. This work was supported by the U.S. National Science Foundation through Grants No. AST-1440226, No. AST0965625 and No. AST-0408698 for the ACT project, as well as Grants No. PHY-1214379 and No. PHY-0855887. Funding was also provided by Princeton University, the University of Pennsylvania, and a Canada Foundation for Innovation (CFI) award to UBC. ACT operates in the Parque Astronómico Atacama in northern Chile under the auspices of the Comisión Nacional de Investigación Científica y Tecnológica de Chile (CONICYT). Computations were performed on the GPC and Niagara supercomputers at the SciNet HPC Consortium. SciNet is funded by the CFI under the auspices of Compute Canada, the Government of Ontario, the Ontario Research Fund—Research Excellence; and the University of Toronto. The development of multichroic detectors and lenses was supported by NASA Grants No. NNX13AE56G and No. NNX14AB58G. Colleagues at AstroNorte and RadioSky provide logistical support and keep operations in Chile running smoothly. We also thank the Mishrahi Fund and the Wilkinson Fund for their generous support of the project. M. S. M. acknowledges support from NSF Grant No. AST-1814971. J. C. H. acknowledges support from the Simons Foundation and the W. M. Keck Foundation Fund at the Institute for Advanced Study. Flatiron Institute is supported by the Simons Foundation. R. B. and V. C. acknowledge DoE Grant No. DE-SC0011838, NASA ATP grants No. NNX14AH53G and No. 80NSSC18K0695, NASA ROSES grant No. 12-EUCLID12-0004 and funding related to the WFIRST Science Investigation Team. E. C. is supported by a STFC Ernest Rutherford Fellowship ST/M004856/2. S. K. C. acknowledges support from the Cornell Presidential Postdoctoral Fellowship. R. D. thanks CONICYT for Grant No. BASAL CATA AFB-170002. M. H. acknowledges funding support from the National Research Foundation, the South African Radio Astronomy Observatory, and the University of KwaZulu-Natal. L. M. received funding from CONICYT FONDECYT Grant No. 3170846. K. M. acknowledges support from the National Research Foundation of South Africa. N. S. acknowledges support from NSF Grant No. 1513618.

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Published - PhysRevD.102.023534.pdf

Submitted - 1911.05717.pdf

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Additional details

Identifiers Related works Funding Dates
Created:
August 19, 2023
Modified:
October 20, 2023