Exploring cosmic origins with CORE: Cluster science

J. B. Melin; A. Bonaldi; M. Remazeilles; S. Hagstotz; J. M. Diego; C. Hernández-Monteagudo; R. T. Génova-Santos; G. Luzzi; C. J.A.P. Martins; S. Grandis; J. J. Mohr; J. G. Bartlett; J. Delabrouille; S. Ferraro; D. Tramonte; J. A. Rubiño-Martín; J. F. Macìas-Pérez; A. Achúcarro; P. Ade; R. Allison; M. Ashdown; M. Ballardini; A. J. Banday; R. Banerji; N. Bartolo; S. Basak; K. Basu; R. A. Battye; D. Baumann; M. Bersanelli; M. Bonato; J. Borrill; F. Bouchet; F. Boulanger; T. Brinckmann; M. Bucher; C. Burigana; A. Buzzelli; Z. Y. Cai; M. Calvo; C. S. Carvalho; M. G. Castellano; A. Challinor; J. Chluba; S. Clesse; S. Colafrancesco; I. Colantoni; A. Coppolecchia; M. Crook; G. D'Alessandro; P. De Bernardis; G. De Gasperis; M. De Petris; G. De Zotti; E. Di Valentino; J. Errard; S. M. Feeney; R. Fernández-Cobos; F. Finelli; F. Forastieri; S. Galli; M. Gerbino; J. González-Nuevo; J. Greenslade; S. Hanany; W. Handley; C. Hervias-Caimapo; M. Hills; E. Hivon; K. Kiiveri; T. Kisner; T. Kitching; M. Kunz; H. Kurki-Suonio; L. Lamagna; A. Lasenby; M. Lattanzi; A. M.C.Le Brun; J. Lesgourgues; A. Lewis; M. Liguori; V. Lindholm; M. Lopez-Caniego; B. Maffei; E. Martinez-Gonzalez; S. Masi; P. Mazzotta; D. McCarthy; A. Melchiorri; D. Molinari; A. Monfardini; P. Natoli; M. Negrello; A. Notari; A. Paiella; D. Paoletti; G. Patanchon; M. Piat; G. Pisano; L. Polastri; G. Polenta; A. Pollo; V. Poulin; M. Quartin; M. Roman; L. Salvati; A. Tartari; M. Tomasi; N. Trappe; S. Triqueneaux; T. Trombetti; C. Tucker; J. Väliviita; R. Van De Weygaert; B. Van Tent; V. Vennin; P. Vielva; N. Vittorio; J. Weller; K. Young; M. Zannoni

doi:10.1088/1475-7516/2018/04/019

Exploring cosmic origins with CORE: Cluster science

J. B. Melin
, A. Bonaldi
, M. Remazeilles
, S. Hagstotz
, J. M. Diego
, C. Hernández-Monteagudo
, R. T. Génova-Santos
, G. Luzzi
, C. J.A.P. Martins
, S. Grandis
, J. J. Mohr
, J. G. Bartlett
, J. Delabrouille
, S. Ferraro
, D. Tramonte
, J. A. Rubiño-Martín
, J. F. Macìas-Pérez
, A. Achúcarro
, P. Ade
, R. Allison

M. Ashdown, M. Ballardini, A. J. Banday, R. Banerji, N. Bartolo, S. Basak, K. Basu, R. A. Battye, D. Baumann, M. Bersanelli, M. Bonato, J. Borrill, F. Bouchet, F. Boulanger, T. Brinckmann, M. Bucher, C. Burigana, A. Buzzelli, Z. Y. Cai, M. Calvo, C. S. Carvalho, M. G. Castellano, A. Challinor, J. Chluba, S. Clesse, S. Colafrancesco, I. Colantoni, A. Coppolecchia, M. Crook, G. D'Alessandro, P. De Bernardis, G. De Gasperis, M. De Petris, G. De Zotti, E. Di Valentino, J. Errard, S. M. Feeney, R. Fernández-Cobos, F. Finelli, F. Forastieri, S. Galli, M. Gerbino, J. González-Nuevo, J. Greenslade, S. Hanany, W. Handley, C. Hervias-Caimapo, M. Hills, E. Hivon, K. Kiiveri, T. Kisner, T. Kitching, M. Kunz, H. Kurki-Suonio, L. Lamagna, A. Lasenby, M. Lattanzi, A. M.C.Le Brun, J. Lesgourgues, A. Lewis, M. Liguori, V. Lindholm, M. Lopez-Caniego, B. Maffei, E. Martinez-Gonzalez, S. Masi, P. Mazzotta, D. McCarthy, A. Melchiorri, D. Molinari, A. Monfardini, P. Natoli, M. Negrello, A. Notari, A. Paiella, D. Paoletti, G. Patanchon, M. Piat, G. Pisano, L. Polastri, G. Polenta, A. Pollo, V. Poulin, M. Quartin, M. Roman, L. Salvati, A. Tartari, M. Tomasi, N. Trappe, S. Triqueneaux, T. Trombetti, C. Tucker, J. Väliviita, R. Van De Weygaert, B. Van Tent, V. Vennin, P. Vielva, N. Vittorio, J. Weller, K. Young, M. Zannoni

Institut Pierre Simon Laplace, CNRS and CEA
University of Manchester
Jodrell Bank Observatory
Universität München
Technische Universität München
Instituto de Fisica de Cantabria (CSIC-UC)
Centro de Estudios de Física del Cosmos de Aragón (CEFCA)
Instituto de Astrofisica de Canarias
Research Unit; CIBERNED and Universidad de La Laguna
University of Rome
Sezione di Roma
Ipatimup Diagnósticos
Max Planck Institut für Extraterrestrische Physik
Astroparticule and Cosmol APC
University of California, Berkeley
LTHE (UMR 5564 CNRS/IRD/Université de Grenoble)
Universiteit Leiden
University of the Basque Country
Cardiff University
Institute of Astronomy
University of Cambridge
University of Cambridge
University of Bologna
INAF Istituto di Astrofisica Spaziale e Fisica Cosmica, Bologna
INFN Sezione di Bologna
IRAP/CNRS
University of Padova
INFN
INAF Osservatorio Astronomico di Padova
School of Biotechnology
International School of Advanced Studies
University Bonn
University of Amsterdam
University of Milano
INAF Istituto di Astrofisica Spaziale e Fisica Cosmica, Milan
Tufts University
Ernest Orlando Lawrence Berkeley National Laboratory
University of California, Space Sciences Laboratory
CNRS
Institut d'Astrophysique Spatiale
RWTH Aachen University
University of Ferrara
University of Rome “Tor Vergata”
University of Science and Technology of China
Universidade de Lisboa
Max Planck Institute for Astrophysics
University of the Witwatersrand, Johannesburg
CCLRC Rutherford Appleton Laboratory
Sorbonne Université
Universités Paris VI and VII
Imperial College London
Center for Computational Astrophysics
Sezione INFN di Ferrara
Stockholm University
University of Oviedo
University of Minnesota
University of Helsinki
UCL Mullard Space Science Laboratory
University of Geneva
Universite Paris-Saclay
University of Sussex
ESAC campus
Maynooth University
University of Barcelona
Science and Research Directorate
Osservatorio Astronomico di Roma
National Centre for Nuclear Research (NCBJ)
Université Savoie Mont Blanc
Instituto de Biofisica da UFRJ
University of Groningen
Université Paris-Sud
University of Portsmouth
University of Milano-Bicocca
Jagiellonian University

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We examine the cosmological constraints that can be achieved with a galaxy cluster survey with the future CORE space mission. Using realistic simulations of the millimeter sky, produced with the latest version of the Planck Sky Model, we characterize the CORE cluster catalogues as a function of the main mission performance parameters. We pay particular attention to telescope size, key to improved angular resolution, and discuss the comparison and the complementarity of CORE with ambitious future ground-based CMB experiments that could be deployed in the next decade. A possible CORE mission concept with a 150 cm diameter primary mirror can detect of the order of 50,000 clusters through the thermal Sunyaev-Zeldovich effect (SZE). The total yield increases (decreases) by 25% when increasing (decreasing) the mirror diameter by 30 cm. The 150 cm telescope configuration will detect the most massive clusters (>10¹⁴ M_o) at redshift z>1.5 over the whole sky, although the exact number above this redshift is tied to the uncertain evolution of the cluster SZE flux-mass relation; assuming self-similar evolution, CORE will detect 0∼ 50 clusters at redshift z>1.5. This changes to 800 (200) when increasing (decreasing) the mirror size by 30 cm. CORE will be able to measure individual cluster halo masses through lensing of the cosmic microwave background anisotropies with a 1-σ sensitivity of 4×10¹⁴ M_o, for a 120 cm aperture telescope, and 10¹⁴ M_o for a 180 cm one. From the ground, we estimate that, for example, a survey with about 150,000 detectors at the focus of 350 cm telescopes observing 65% of the sky would be shallower than CORE and detect about 11,000 clusters, while a survey with the same number of detectors observing 25% of sky with a 10 m telescope is expected to be deeper and to detect about 70,000 clusters. When combined with the latter, CORE would reach a limiting mass of M₅₀₀ ∼ 2-3 × 10¹³ M_o and detect 220,000 clusters (5 sigma detection limit). Cosmological constraints from CORE cluster counts alone are competitive with other scheduled large scale structure surveys in the 2020's for measuring the dark energy equation-of-state parameters w₀ and w_a (σ_w₀=0.28, σ_{w_a}=0.31). In combination with primary CMB constraints, CORE cluster counts can further reduce these error bars on w₀ and w_a to 0.05 and 0.13 respectively, and constrain the sum of the neutrino masses, Σ m_ν, to 39 meV (1 sigma). The wide frequency coverage of CORE, 60-600 GHz, will enable measurement of the relativistic thermal SZE by stacking clusters. Contamination by dust emission from the clusters, however, makes constraining the temperature of the intracluster medium difficult. The kinetic SZE pairwise momentum will be extracted with 0S/N=7 in the foreground-cleaned CMB map. Measurements of T_CMB(z) using CORE clusters will establish competitive constraints on the evolution of the CMB temperature: (1+z)^1-β, with an uncertainty of σ_β ≲ 2.7× 10^-3 at low redshift (z ≲ 1). The wide frequency coverage also enables clean extraction of a map of the diffuse SZE signal over the sky, substantially reducing contamination by foregrounds compared to the Planck SZE map extraction. Our analysis of the one-dimensional distribution of Compton-y values in the simulated map finds an order of magnitude improvement in constraints on σ₈ over the Planck result, demonstrating the potential of this cosmological probe with CORE.

langue originale	Anglais
Numéro d'article	019
journal	Journal of Cosmology and Astroparticle Physics
Volume	2018
Numéro de publication	4
Les DOIs	https://doi.org/10.1088/1475-7516/2018/04/019
état	Publié - 5 avr. 2018
Modification externe	Oui

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10.1088/1475-7516/2018/04/019

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Melin, J. B., Bonaldi, A., Remazeilles, M., Hagstotz, S., Diego, J. M., Hernández-Monteagudo, C., Génova-Santos, R. T., Luzzi, G., Martins, C. J. A. P., Grandis, S., Mohr, J. J., Bartlett, J. G., Delabrouille, J., Ferraro, S., Tramonte, D., Rubiño-Martín, J. A., Macìas-Pérez, J. F., Achúcarro, A., Ade, P., ... Zannoni, M. (2018). Exploring cosmic origins with CORE: Cluster science. Journal of Cosmology and Astroparticle Physics, 2018(4), Article 019. https://doi.org/10.1088/1475-7516/2018/04/019

@article{8e5e953fd9fe4c138dd84f515df20d88,

title = "Exploring cosmic origins with CORE: Cluster science",

abstract = "We examine the cosmological constraints that can be achieved with a galaxy cluster survey with the future CORE space mission. Using realistic simulations of the millimeter sky, produced with the latest version of the Planck Sky Model, we characterize the CORE cluster catalogues as a function of the main mission performance parameters. We pay particular attention to telescope size, key to improved angular resolution, and discuss the comparison and the complementarity of CORE with ambitious future ground-based CMB experiments that could be deployed in the next decade. A possible CORE mission concept with a 150 cm diameter primary mirror can detect of the order of 50,000 clusters through the thermal Sunyaev-Zeldovich effect (SZE). The total yield increases (decreases) by 25\% when increasing (decreasing) the mirror diameter by 30 cm. The 150 cm telescope configuration will detect the most massive clusters (>1014 Mo) at redshift z>1.5 over the whole sky, although the exact number above this redshift is tied to the uncertain evolution of the cluster SZE flux-mass relation; assuming self-similar evolution, CORE will detect 0∼ 50 clusters at redshift z>1.5. This changes to 800 (200) when increasing (decreasing) the mirror size by 30 cm. CORE will be able to measure individual cluster halo masses through lensing of the cosmic microwave background anisotropies with a 1-σ sensitivity of 4×1014 Mo, for a 120 cm aperture telescope, and 1014 Mo for a 180 cm one. From the ground, we estimate that, for example, a survey with about 150,000 detectors at the focus of 350 cm telescopes observing 65\% of the sky would be shallower than CORE and detect about 11,000 clusters, while a survey with the same number of detectors observing 25\% of sky with a 10 m telescope is expected to be deeper and to detect about 70,000 clusters. When combined with the latter, CORE would reach a limiting mass of M500 ∼ 2-3 × 1013 Mo and detect 220,000 clusters (5 sigma detection limit). Cosmological constraints from CORE cluster counts alone are competitive with other scheduled large scale structure surveys in the 2020's for measuring the dark energy equation-of-state parameters w0 and wa (σw0=0.28, σwa=0.31). In combination with primary CMB constraints, CORE cluster counts can further reduce these error bars on w0 and wa to 0.05 and 0.13 respectively, and constrain the sum of the neutrino masses, Σ mν, to 39 meV (1 sigma). The wide frequency coverage of CORE, 60-600 GHz, will enable measurement of the relativistic thermal SZE by stacking clusters. Contamination by dust emission from the clusters, however, makes constraining the temperature of the intracluster medium difficult. The kinetic SZE pairwise momentum will be extracted with 0S/N=7 in the foreground-cleaned CMB map. Measurements of TCMB(z) using CORE clusters will establish competitive constraints on the evolution of the CMB temperature: (1+z)1-β, with an uncertainty of σβ ≲ 2.7× 10-3 at low redshift (z ≲ 1). The wide frequency coverage also enables clean extraction of a map of the diffuse SZE signal over the sky, substantially reducing contamination by foregrounds compared to the Planck SZE map extraction. Our analysis of the one-dimensional distribution of Compton-y values in the simulated map finds an order of magnitude improvement in constraints on σ8 over the Planck result, demonstrating the potential of this cosmological probe with CORE.",

keywords = "CMBR experiments, Sunyaev-Zeldovich effect, cluster counts, galaxy clusters",

author = "Melin, \{J. B.\} and A. Bonaldi and M. Remazeilles and S. Hagstotz and Diego, \{J. M.\} and C. Hern{\'a}ndez-Monteagudo and G{\'e}nova-Santos, \{R. T.\} and G. Luzzi and Martins, \{C. J.A.P.\} and S. Grandis and Mohr, \{J. J.\} and Bartlett, \{J. G.\} and J. Delabrouille and S. Ferraro and D. Tramonte and Rubi{\~n}o-Mart{\'i}n, \{J. A.\} and Mac{\`i}as-P{\'e}rez, \{J. F.\} and A. Ach{\'u}carro and P. Ade and R. Allison and M. Ashdown and M. Ballardini and Banday, \{A. J.\} and R. Banerji and N. Bartolo and S. Basak and K. Basu and Battye, \{R. A.\} and D. Baumann and M. Bersanelli and M. Bonato and J. Borrill and F. Bouchet and F. Boulanger and T. Brinckmann and M. Bucher and C. Burigana and A. Buzzelli and Cai, \{Z. Y.\} and M. Calvo and Carvalho, \{C. S.\} and Castellano, \{M. G.\} and A. Challinor and J. Chluba and S. Clesse and S. Colafrancesco and I. Colantoni and A. Coppolecchia and M. Crook and G. D'Alessandro and \{De Bernardis\}, P. and \{De Gasperis\}, G. and Petris, \{M. De\} and Zotti, \{G. De\} and Valentino, \{E. Di\} and J. Errard and Feeney, \{S. M.\} and R. Fern{\'a}ndez-Cobos and F. Finelli and F. Forastieri and S. Galli and M. Gerbino and J. Gonz{\'a}lez-Nuevo and J. Greenslade and S. Hanany and W. Handley and C. Hervias-Caimapo and M. Hills and E. Hivon and K. Kiiveri and T. Kisner and T. Kitching and M. Kunz and H. Kurki-Suonio and L. Lamagna and A. Lasenby and M. Lattanzi and Brun, \{A. M.C.Le\} and J. Lesgourgues and A. Lewis and M. Liguori and V. Lindholm and M. Lopez-Caniego and B. Maffei and E. Martinez-Gonzalez and S. Masi and P. Mazzotta and D. McCarthy and A. Melchiorri and D. Molinari and A. Monfardini and P. Natoli and M. Negrello and A. Notari and A. Paiella and D. Paoletti and G. Patanchon and M. Piat and G. Pisano and L. Polastri and G. Polenta and A. Pollo and V. Poulin and M. Quartin and M. Roman and L. Salvati and A. Tartari and M. Tomasi and N. Trappe and S. Triqueneaux and T. Trombetti and C. Tucker and J. V{\"a}liviita and \{De Weygaert\}, \{R. Van\} and Tent, \{B. Van\} and V. Vennin and P. Vielva and N. Vittorio and J. Weller and K. Young and M. Zannoni",

note = "Publisher Copyright: {\textcopyright} 2018 IOP Publishing Ltd and Sissa Medialab.",

year = "2018",

month = apr,

day = "5",

doi = "10.1088/1475-7516/2018/04/019",

language = "English",

volume = "2018",

journal = "Journal of Cosmology and Astroparticle Physics",

issn = "1475-7516",

number = "4",

}

Melin, JB, Bonaldi, A, Remazeilles, M, Hagstotz, S, Diego, JM, Hernández-Monteagudo, C, Génova-Santos, RT, Luzzi, G, Martins, CJAP, Grandis, S, Mohr, JJ, Bartlett, JG, Delabrouille, J, Ferraro, S, Tramonte, D, Rubiño-Martín, JA, Macìas-Pérez, JF, Achúcarro, A, Ade, P, Allison, R, Ashdown, M, Ballardini, M, Banday, AJ, Banerji, R, Bartolo, N, Basak, S, Basu, K, Battye, RA, Baumann, D, Bersanelli, M, Bonato, M, Borrill, J, Bouchet, F, Boulanger, F, Brinckmann, T, Bucher, M, Burigana, C, Buzzelli, A, Cai, ZY, Calvo, M, Carvalho, CS, Castellano, MG, Challinor, A, Chluba, J, Clesse, S, Colafrancesco, S, Colantoni, I, Coppolecchia, A, Crook, M, D'Alessandro, G, De Bernardis, P, De Gasperis, G, Petris, MD, Zotti, GD, Valentino, ED, Errard, J, Feeney, SM, Fernández-Cobos, R, Finelli, F, Forastieri, F, Galli, S, Gerbino, M, González-Nuevo, J, Greenslade, J, Hanany, S, Handley, W, Hervias-Caimapo, C, Hills, M, Hivon, E, Kiiveri, K, Kisner, T, Kitching, T, Kunz, M, Kurki-Suonio, H, Lamagna, L, Lasenby, A, Lattanzi, M, Brun, AMCL, Lesgourgues, J, Lewis, A, Liguori, M, Lindholm, V, Lopez-Caniego, M, Maffei, B, Martinez-Gonzalez, E, Masi, S, Mazzotta, P, McCarthy, D, Melchiorri, A, Molinari, D, Monfardini, A, Natoli, P, Negrello, M, Notari, A, Paiella, A, Paoletti, D, Patanchon, G, Piat, M, Pisano, G, Polastri, L, Polenta, G, Pollo, A, Poulin, V, Quartin, M, Roman, M, Salvati, L, Tartari, A, Tomasi, M, Trappe, N, Triqueneaux, S, Trombetti, T, Tucker, C, Väliviita, J, De Weygaert, RV, Tent, BV, Vennin, V, Vielva, P, Vittorio, N, Weller, J, Young, K & Zannoni, M 2018, 'Exploring cosmic origins with CORE: Cluster science', Journal of Cosmology and Astroparticle Physics, VOL. 2018, Numéro 4, 019. https://doi.org/10.1088/1475-7516/2018/04/019

TY - JOUR

T1 - Exploring cosmic origins with CORE

T2 - Cluster science

AU - Melin, J. B.

AU - Bonaldi, A.

AU - Remazeilles, M.

AU - Hagstotz, S.

AU - Diego, J. M.

AU - Hernández-Monteagudo, C.

AU - Génova-Santos, R. T.

AU - Luzzi, G.

AU - Martins, C. J.A.P.

AU - Grandis, S.

AU - Mohr, J. J.

AU - Bartlett, J. G.

AU - Delabrouille, J.

AU - Ferraro, S.

AU - Tramonte, D.

AU - Rubiño-Martín, J. A.

AU - Macìas-Pérez, J. F.

AU - Achúcarro, A.

AU - Ade, P.

AU - Allison, R.

AU - Ashdown, M.

AU - Ballardini, M.

AU - Banday, A. J.

AU - Banerji, R.

AU - Bartolo, N.

AU - Basak, S.

AU - Basu, K.

AU - Battye, R. A.

AU - Baumann, D.

AU - Bersanelli, M.

AU - Bonato, M.

AU - Borrill, J.

AU - Bouchet, F.

AU - Boulanger, F.

AU - Brinckmann, T.

AU - Bucher, M.

AU - Burigana, C.

AU - Buzzelli, A.

AU - Cai, Z. Y.

AU - Calvo, M.

AU - Carvalho, C. S.

AU - Castellano, M. G.

AU - Challinor, A.

AU - Chluba, J.

AU - Clesse, S.

AU - Colafrancesco, S.

AU - Colantoni, I.

AU - Coppolecchia, A.

AU - Crook, M.

AU - D'Alessandro, G.

AU - De Bernardis, P.

AU - De Gasperis, G.

AU - Petris, M. De

AU - Zotti, G. De

AU - Valentino, E. Di

AU - Errard, J.

AU - Feeney, S. M.

AU - Fernández-Cobos, R.

AU - Finelli, F.

AU - Forastieri, F.

AU - Galli, S.

AU - Gerbino, M.

AU - González-Nuevo, J.

AU - Greenslade, J.

AU - Hanany, S.

AU - Handley, W.

AU - Hervias-Caimapo, C.

AU - Hills, M.

AU - Hivon, E.

AU - Kiiveri, K.

AU - Kisner, T.

AU - Kitching, T.

AU - Kunz, M.

AU - Kurki-Suonio, H.

AU - Lamagna, L.

AU - Lasenby, A.

AU - Lattanzi, M.

AU - Brun, A. M.C.Le

AU - Lesgourgues, J.

AU - Lewis, A.

AU - Liguori, M.

AU - Lindholm, V.

AU - Lopez-Caniego, M.

AU - Maffei, B.

AU - Martinez-Gonzalez, E.

AU - Masi, S.

AU - Mazzotta, P.

AU - McCarthy, D.

AU - Melchiorri, A.

AU - Molinari, D.

AU - Monfardini, A.

AU - Natoli, P.

AU - Negrello, M.

AU - Notari, A.

AU - Paiella, A.

AU - Paoletti, D.

AU - Patanchon, G.

AU - Piat, M.

AU - Pisano, G.

AU - Polastri, L.

AU - Polenta, G.

AU - Pollo, A.

AU - Poulin, V.

AU - Quartin, M.

AU - Roman, M.

AU - Salvati, L.

AU - Tartari, A.

AU - Tomasi, M.

AU - Trappe, N.

AU - Triqueneaux, S.

AU - Trombetti, T.

AU - Tucker, C.

AU - Väliviita, J.

AU - De Weygaert, R. Van

AU - Tent, B. Van

AU - Vennin, V.

AU - Vielva, P.

AU - Vittorio, N.

AU - Weller, J.

AU - Young, K.

AU - Zannoni, M.

PY - 2018/4/5

Y1 - 2018/4/5

N2 - We examine the cosmological constraints that can be achieved with a galaxy cluster survey with the future CORE space mission. Using realistic simulations of the millimeter sky, produced with the latest version of the Planck Sky Model, we characterize the CORE cluster catalogues as a function of the main mission performance parameters. We pay particular attention to telescope size, key to improved angular resolution, and discuss the comparison and the complementarity of CORE with ambitious future ground-based CMB experiments that could be deployed in the next decade. A possible CORE mission concept with a 150 cm diameter primary mirror can detect of the order of 50,000 clusters through the thermal Sunyaev-Zeldovich effect (SZE). The total yield increases (decreases) by 25% when increasing (decreasing) the mirror diameter by 30 cm. The 150 cm telescope configuration will detect the most massive clusters (>1014 Mo) at redshift z>1.5 over the whole sky, although the exact number above this redshift is tied to the uncertain evolution of the cluster SZE flux-mass relation; assuming self-similar evolution, CORE will detect 0∼ 50 clusters at redshift z>1.5. This changes to 800 (200) when increasing (decreasing) the mirror size by 30 cm. CORE will be able to measure individual cluster halo masses through lensing of the cosmic microwave background anisotropies with a 1-σ sensitivity of 4×1014 Mo, for a 120 cm aperture telescope, and 1014 Mo for a 180 cm one. From the ground, we estimate that, for example, a survey with about 150,000 detectors at the focus of 350 cm telescopes observing 65% of the sky would be shallower than CORE and detect about 11,000 clusters, while a survey with the same number of detectors observing 25% of sky with a 10 m telescope is expected to be deeper and to detect about 70,000 clusters. When combined with the latter, CORE would reach a limiting mass of M500 ∼ 2-3 × 1013 Mo and detect 220,000 clusters (5 sigma detection limit). Cosmological constraints from CORE cluster counts alone are competitive with other scheduled large scale structure surveys in the 2020's for measuring the dark energy equation-of-state parameters w0 and wa (σw0=0.28, σwa=0.31). In combination with primary CMB constraints, CORE cluster counts can further reduce these error bars on w0 and wa to 0.05 and 0.13 respectively, and constrain the sum of the neutrino masses, Σ mν, to 39 meV (1 sigma). The wide frequency coverage of CORE, 60-600 GHz, will enable measurement of the relativistic thermal SZE by stacking clusters. Contamination by dust emission from the clusters, however, makes constraining the temperature of the intracluster medium difficult. The kinetic SZE pairwise momentum will be extracted with 0S/N=7 in the foreground-cleaned CMB map. Measurements of TCMB(z) using CORE clusters will establish competitive constraints on the evolution of the CMB temperature: (1+z)1-β, with an uncertainty of σβ ≲ 2.7× 10-3 at low redshift (z ≲ 1). The wide frequency coverage also enables clean extraction of a map of the diffuse SZE signal over the sky, substantially reducing contamination by foregrounds compared to the Planck SZE map extraction. Our analysis of the one-dimensional distribution of Compton-y values in the simulated map finds an order of magnitude improvement in constraints on σ8 over the Planck result, demonstrating the potential of this cosmological probe with CORE.

AB - We examine the cosmological constraints that can be achieved with a galaxy cluster survey with the future CORE space mission. Using realistic simulations of the millimeter sky, produced with the latest version of the Planck Sky Model, we characterize the CORE cluster catalogues as a function of the main mission performance parameters. We pay particular attention to telescope size, key to improved angular resolution, and discuss the comparison and the complementarity of CORE with ambitious future ground-based CMB experiments that could be deployed in the next decade. A possible CORE mission concept with a 150 cm diameter primary mirror can detect of the order of 50,000 clusters through the thermal Sunyaev-Zeldovich effect (SZE). The total yield increases (decreases) by 25% when increasing (decreasing) the mirror diameter by 30 cm. The 150 cm telescope configuration will detect the most massive clusters (>1014 Mo) at redshift z>1.5 over the whole sky, although the exact number above this redshift is tied to the uncertain evolution of the cluster SZE flux-mass relation; assuming self-similar evolution, CORE will detect 0∼ 50 clusters at redshift z>1.5. This changes to 800 (200) when increasing (decreasing) the mirror size by 30 cm. CORE will be able to measure individual cluster halo masses through lensing of the cosmic microwave background anisotropies with a 1-σ sensitivity of 4×1014 Mo, for a 120 cm aperture telescope, and 1014 Mo for a 180 cm one. From the ground, we estimate that, for example, a survey with about 150,000 detectors at the focus of 350 cm telescopes observing 65% of the sky would be shallower than CORE and detect about 11,000 clusters, while a survey with the same number of detectors observing 25% of sky with a 10 m telescope is expected to be deeper and to detect about 70,000 clusters. When combined with the latter, CORE would reach a limiting mass of M500 ∼ 2-3 × 1013 Mo and detect 220,000 clusters (5 sigma detection limit). Cosmological constraints from CORE cluster counts alone are competitive with other scheduled large scale structure surveys in the 2020's for measuring the dark energy equation-of-state parameters w0 and wa (σw0=0.28, σwa=0.31). In combination with primary CMB constraints, CORE cluster counts can further reduce these error bars on w0 and wa to 0.05 and 0.13 respectively, and constrain the sum of the neutrino masses, Σ mν, to 39 meV (1 sigma). The wide frequency coverage of CORE, 60-600 GHz, will enable measurement of the relativistic thermal SZE by stacking clusters. Contamination by dust emission from the clusters, however, makes constraining the temperature of the intracluster medium difficult. The kinetic SZE pairwise momentum will be extracted with 0S/N=7 in the foreground-cleaned CMB map. Measurements of TCMB(z) using CORE clusters will establish competitive constraints on the evolution of the CMB temperature: (1+z)1-β, with an uncertainty of σβ ≲ 2.7× 10-3 at low redshift (z ≲ 1). The wide frequency coverage also enables clean extraction of a map of the diffuse SZE signal over the sky, substantially reducing contamination by foregrounds compared to the Planck SZE map extraction. Our analysis of the one-dimensional distribution of Compton-y values in the simulated map finds an order of magnitude improvement in constraints on σ8 over the Planck result, demonstrating the potential of this cosmological probe with CORE.

KW - CMBR experiments

KW - Sunyaev-Zeldovich effect

KW - cluster counts

KW - galaxy clusters

UR - https://www.scopus.com/pages/publications/85047567724

U2 - 10.1088/1475-7516/2018/04/019

DO - 10.1088/1475-7516/2018/04/019

M3 - Article

AN - SCOPUS:85047567724

SN - 1475-7516

VL - 2018

JO - Journal of Cosmology and Astroparticle Physics

JF - Journal of Cosmology and Astroparticle Physics

IS - 4

M1 - 019

ER -

Exploring cosmic origins with CORE: Cluster science

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