Planck 2013 results. XIX. The integrated Sachs-Wolfe effect

Planck Collaboration: P. A. R. Ade; N. Aghanim; C. Armitage-Caplan; M.; Arnaud; M. Ashdown; F. Atrio-Barandela; J. Aumont; C. Baccigalupi; A. J.; Banday; R. B. Barreiro; J. G. Bartlett; N. Bartolo; E. Battaner; K. Benabed,; A. Beno\^it; A. Benoit-L\'evy; J.-P. Bernard; M. Bersanelli; P. Bielewicz; J.; Bobin; J. J. Bock; A. Bonaldi; L. Bonavera; J. R. Bond; J. Borrill; F. R.; Bouchet; M. Bridges; M. Bucher; C. Burigana; R. C. Butler; J.-F. Cardoso; A.; Catalano; A. Challinor; A. Chamballu; H. C. Chiang; L.-Y Chiang; P. R.; Christensen; S. Church; D. L. Clements; S. Colombi; L. P. L. Colombo; F.; Couchot; A. Coulais; B. P. Crill; A. Curto; F. Cuttaia; L. Danese; R. D.; Davies; R. J. Davis; P. de Bernardis; A. de Rosa; G. de Zotti; J.; Delabrouille; J.-M. Delouis; F.-X. D\'esert; C. Dickinson; J. M. Diego; K.; Dolag; H. Dole; S. Donzelli; O. Dor\'e; M. Douspis; X. Dupac; G. Efstathiou,; T. A. En{\ss}lin; H. K. Eriksen; J. Fergusson; F. Finelli; O. Forni; P.; Fosalba; M. Frailis; E. Franceschi; M. Frommert; S. Galeotta; K. Ganga; R. T.; G\'enova-Santos; M. Giard; G. Giardino; Y. Giraud-H\'eraud; J.; Gonz\'alez-Nuevo; K. M. G\'orski; S. Gratton; A. Gregorio; A. Gruppuso; F. K.; Hansen; D. Hanson; D. Harrison; S. Henrot-Versill\'e; C.; Hern\'andez-Monteagudo; D. Herranz; S. R. Hildebrandt; E. Hivon; S. Ho; M.; Hobson; W. A. Holmes; A. Hornstrup; W. Hovest; K. M. Huffenberger; S. Ili\'c,; A. H. Jaffe; T. R. Jaffe; J. Jasche; W. C. Jones; M. Juvela; E. Keih\"anen,; R. Keskitalo; T. S. Kisner; J. Knoche; L. Knox; M. Kunz; H. Kurki-Suonio; G.; Lagache; A. L\"ahteenm\"aki; J.-M. Lamarre; M. Langer; A. Lasenby; R. J.; Laureijs; C. R. Lawrence; J. P. Leahy; R. Leonardi; J. Lesgourgues; M.; Liguori; P. B. Lilje; M. Linden-V{\o}rnle; M. L\'opez-Caniego; P. M. Lubin,; J. F. Mac\'ias-P\'erez; B. Maffei; D. Maino; N. Mandolesi; A. Mangilli; A.; Marcos-Caballero; M. Maris; D. J. Marshall; P. G. Martin; E.; Mart\'inez-Gonz\'alez; S. Masi; M. Massardi; S. Matarrese; F. Matthai; P.; Mazzotta; P. R. Meinhold; A. Melchiorri; L. Mendes; A. Mennella; M.; Migliaccio; S. Mitra; M.-A. Miville-Desch\^enes; A. Moneti; L. Montier; G.; Morgante; D. Mortlock; A. Moss; D. Munshi; P. Naselsky; F. Nati; P. Natoli,; C. B. Netterfield; H. U. N{\o}rgaard-Nielsen; F. Noviello; D. Novikov; I.; Novikov; S. Osborne; C. A. Oxborrow; F. Paci; L. Pagano; F. Pajot; D.; Paoletti; B. Partridge; F. Pasian; G. Patanchon; O. Perdereau; L. Perotto; F.; Perrotta; F. Piacentini; M. Piat; E. Pierpaoli; D. Pietrobon; S.; Plaszczynski; E. Pointecouteau; G. Polenta; N. Ponthieu; L. Popa; T.; Poutanen; G. W. Pratt; G. Pr\'ezeau; S. Prunet; J.-L. Puget; J. P. Rachen; B.; Racine; R. Rebolo; M. Reinecke; M. Remazeilles; C. Renault; A. Renzi; S.; Ricciardi; T. Riller; I. Ristorcelli; G. Rocha; C. Rosset; G. Roudier; M.; Rowan-Robinson; J. A. Rubi\~no-Mart\'in; B. Rusholme; M. Sandri; D. Santos,; G. Savini; B. M. Schaefer; F. Schiavon; D. Scott; M. D. Seiffert; E. P. S.; Shellard; L. D. Spencer; J.-L. Starck; V. Stolyarov; R. Stompor; R. Sudiwala,; R. Sunyaev; F. Sureau; P. Sutter; D. Sutton; A.-S. Suur-Uski; J.-F. Sygnet,; J. A. Tauber; D. Tavagnacco; L. Terenzi; L. Toffolatti; M. Tomasi; M.; Tristram; M. Tucci; J. Tuovinen; G. Umana; L. Valenziano; J. Valiviita; B.; Van Tent; J. Varis; M. Viel; P. Vielva; F. Villa; N. Vittorio; L. A. Wade; B.; D. Wandelt; M. White; J.-Q. Xia; D. Yvon; A. Zacchei; A. Zonca

arXiv:1303.5079·astro-ph.CO·June 15, 2015

Planck 2013 results. XIX. The integrated Sachs-Wolfe effect

Planck Collaboration: P. A. R. Ade, N. Aghanim, C. Armitage-Caplan, M., Arnaud, M. Ashdown, F. Atrio-Barandela, J. Aumont, C. Baccigalupi, A. J., Banday, R. B. Barreiro, J. G. Bartlett, N. Bartolo, E. Battaner, K. Benabed,, A. Beno\^it, A. Benoit-L\'evy, J.-P. Bernard

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TL;DR

This paper reports the detection of the integrated Sachs-Wolfe effect using Planck 2013 data through multiple methods, providing independent evidence for dark energy and the universe's accelerated expansion.

Contribution

It introduces the first detection of the ISW effect via correlation with the Planck reconstructed gravitational lensing potential, and compares multiple approaches to confirm the effect.

Findings

01

Detection significance ranges from 2 to 4 sigma.

02

First-time correlation of CMB with lensing potential using bispectrum.

03

Consistent ISW signals across different catalogues and methods.

Abstract

Based on CMB maps from the 2013 Planck Mission data release, this paper presents the detection of the ISW effect, i.e., the correlation between the CMB and large-scale evolving gravitational potentials. The significance of detection ranges from 2 to 4 sigma, depending on which method is used. We investigate three separate approaches, which cover essentially all previous studies, as well as breaking new ground. (i) Correlation of the CMB with the Planck reconstructed gravitational lensing potential (for the first time). This detection is made using the lensing-induced bispectrum; the correlation between lensing and the ISW effect has a significance close to 2.5 sigma. (ii) Cross-correlation with tracers of LSS, yielding around 3 sigma significance, based on a combination of radio (NVSS) and optical (SDSS) data. (iii) Aperture photometry on stacked CMB fields at the locations of known…

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