LiteBIRD science goals and forecasts. Mapping the hot gas in the Universe

Remazeilles, M.; Douspis, M.; Rubiño-Martín, J.A.; Banday, A.J.; Chluba, J.; De Bernardis, P.; De Petris, M.; Hernández-Monteagudo, C.; Luzzi, G.; Macias-Perez, J.; Masi, S.; Namikawa, T.; Salvati, L.; Tanimura, H.; Aizawa, K.; Anand, A.; Aumont, J.; Baccigalupi, C.; Ballardini, M.; Barreiro, R.B.; Bartolo, N.; Basak, S.; Bersanelli, M.; Blinov, D.; Bortolami, M.; Brinckmann, T.; Calabrese, E.; Campeti, P.; Carinos, E.; Carones, A.; Casas, F.J.; Cheung, K.; Clermont, L.; Columbro, F.; Coppolecchia, A.; Cuttaia, F.; De Haan, T.; De La Hoz, E.; Della Torre, S.; Diego-Palazuelos, P.; D'Alessandro, G.; Eriksen, H.K.; Finelli, F.; Fuskeland, U.; Galloni, G.; Galloway, M.; Gervasi, M.; Génova-Santos, R.T.; Ghigna, T.; Giardiello, S.; Gimeno-Amo, C.; Gjerløw, E.; González González, R.; Gruppuso, A.; Hazumi, M.; Henrot-Versillé, S.; Hergt, L.T.; Herranz, D.; Kohri, K.; Komatsu, E.; Lamagna, L.; Lattanzi, M.; Leloup, C.; Levrier, F.; Lonappan, A.I.; López-Caniego, M.; Maffei, B.; Martínez-González, E.; Matarrese, S.; Matsumura, T.; Micheli, S.; Migliaccio, M.; Monelli, M.; Montier, L.; Morgante, G.; Nagano, Y.; Nagata, R.; Novelli, A.; Omae, R.; Pagano, L.; Paoletti, D.; Pavlidou, V.; Piacentini, F.; Pinchera, M.; Polenta, G.; Porcelli, L.; Ritacco, A.; Ruiz-Granda, M.; Sakurai, Y.; Scott, D.; Shiraishi, M.; Stever, S.L.; Sullivan, R.M.; Takase, Y.; Tassis, K.; Terenzi, L.; Tomasi, M.; Tristram, M.; Vacher, L.; Van Tent, B.; Vielva, P.; Wehus, I.K.; Westbrook, B.; Weymann-Despres, G.; Wollack, E.J.; Zannoni, M.; Zhou, Y.

doi:10.1088/1475-7516/2024/12/026

We assess the capabilities of the LiteBIRD mission to map the hot gas distribution in the Universe through the thermal Sunyaev-Zeldovich (SZ) effect. Our analysis relies on comprehensive simulations incorporating various sources of Galactic and extragalactic foreground emission, while accounting for the specific instrumental characteristics of the LiteBIRD mission, such as detector sensitivities, frequency-dependent beam convolution, inhomogeneous sky scanning, and 1/f noise. We implement a tailored component-separation pipeline to map the thermal SZ Compton y-parameter over 98% of the sky. Despite lower angular resolution for galaxy cluster science, LiteBIRD provides full-sky coverage and, compared to the Planck satellite, enhanced sensitivity, as well as more frequency bands to enable the construction of an all-sky thermal SZ y-map, with reduced foreground contamination at large and intermediate angular scales. By combining LiteBIRD and Planck channels in the component-separation pipeline, we also obtain an optimal y-map that leverages the advantages of both experiments, with the higher angular resolution of the Planck channels enabling the recovery of compact clusters beyond the LiteBIRD beam limitations, and the numerous sensitive LiteBIRD channels further mitigating foregrounds. The added value of LiteBIRD is highlighted through the examination of maps, power spectra, and one-point statistics of the various sky components. After component separation, the 1/f noise from LiteBIRD's intensity channels is effectively mitigated below the level of the thermal SZ signal at all multipoles. Cosmological constraints on S8 = σ8 (Ωm /0.3)0.5 obtained from the LiteBIRD-Planck combined y-map power spectrum exhibits a 15 % reduction in uncertainty compared to constraints derived from Planck alone. This improvement can be attributed to the increased portion of uncontaminated sky available in the LiteBIRD-Planck combined y-map.

LiteBIRD science goals and forecasts. Mapping the hot gas in the Universe / M. Remazeilles, M. Douspis, J.A. Rubiño-Martín, A.J. Banday, J. Chluba, P. De Bernardis, M. De Petris, C. Hernández-Monteagudo, G. Luzzi, J. Macias-Perez, S. Masi, T. Namikawa, L. Salvati, H. Tanimura, K. Aizawa, A. Anand, J. Aumont, C. Baccigalupi, M. Ballardini, R.B. Barreiro, N. Bartolo, S. Basak, M. Bersanelli, D. Blinov, M. Bortolami, T. Brinckmann, E. Calabrese, P. Campeti, E. Carinos, A. Carones, F.J. Casas, K. Cheung, L. Clermont, F. Columbro, A. Coppolecchia, F. Cuttaia, T. De Haan, E. De La Hoz, S. Della Torre, P. Diego-Palazuelos, G. D'Alessandro, H.K. Eriksen, F. Finelli, U. Fuskeland, G. Galloni, M. Galloway, M. Gervasi, R.T. Génova-Santos, T. Ghigna, S. Giardiello, C. Gimeno-Amo, E. Gjerløw, R. González González, A. Gruppuso, M. Hazumi, S. Henrot-Versillé, L.T. Hergt, D. Herranz, K. Kohri, E. Komatsu, L. Lamagna, M. Lattanzi, C. Leloup, F. Levrier, A.I. Lonappan, M. López-Caniego, B. Maffei, E. Martínez-González, S. Matarrese, T. Matsumura, S. Micheli, M. Migliaccio, M. Monelli, L. Montier, G. Morgante, Y. Nagano, R. Nagata, A. Novelli, R. Omae, L. Pagano, D. Paoletti, V. Pavlidou, F. Piacentini, M. Pinchera, G. Polenta, L. Porcelli, A. Ritacco, M. Ruiz-Granda, Y. Sakurai, D. Scott, M. Shiraishi, S.L. Stever, R.M. Sullivan, Y. Takase, K. Tassis, L. Terenzi, M. Tomasi, M. Tristram, L. Vacher, B. Van Tent, P. Vielva, I.K. Wehus, B. Westbrook, G. Weymann-Despres, E.J. Wollack, M. Zannoni, Y. Zhou. - In: JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS. - ISSN 1475-7516. - 2024:12(2024 Dec 11), pp. 026.1-026.40. [10.1088/1475-7516/2024/12/026]

LiteBIRD science goals and forecasts. Mapping the hot gas in the Universe

Douspis, M.^Secondo;Rubiño-Martín, J. A.;Banday, A. J.;Chluba, J.;de Bernardis, P.;De Petris, M.;Hernández-Monteagudo, C.;Luzzi, G.;Macias-Perez, J.;Masi, S.;Namikawa, T.;Salvati, L.;Tanimura, H.;Aizawa, K.;Anand, A.;Aumont, J.;Baccigalupi, C.;Ballardini, M.;Barreiro, R. B.;Bartolo, N.;Basak, S.;M. Bersanelli;Blinov, D.;Bortolami, M.;Brinckmann, T.;Calabrese, E.;Campeti, P.;Carinos, E.;Carones, A.;Casas, F. J.;Cheung, K.;Clermont, L.;Columbro, F.;Coppolecchia, A.;Cuttaia, F.;de Haan, T.;de la Hoz, E.;Della Torre, S.;Diego-Palazuelos, P.;D'Alessandro, G.;Eriksen, H. K.;Finelli, F.;Fuskeland, U.;Galloni, G.;Galloway, M.;Gervasi, M.;Génova-Santos, R. T.;Ghigna, T.;Giardiello, S.;Gimeno-Amo, C.;Gjerløw, E.;González González, R.;Gruppuso, A.;Hazumi, M.;Henrot-Versillé, S.;Hergt, L. T.;Herranz, D.;Kohri, K.;Komatsu, E.;Lamagna, L.;Lattanzi, M.;Leloup, C.;Levrier, F.;Lonappan, A. I.;López-Caniego, M.;Maffei, B.;Martínez-González, E.;Matarrese, S.;Matsumura, T.;Micheli, S.;Migliaccio, M.;Monelli, M.;Montier, L.;Morgante, G.;Nagano, Y.;Nagata, R.;Novelli, A.;Omae, R.;Pagano, L.;Paoletti, D.;Pavlidou, V.;Piacentini, F.;Pinchera, M.;Polenta, G.;Porcelli, L.;Ritacco, A.;Ruiz-Granda, M.;Sakurai, Y.;Scott, D.;Shiraishi, M.;Stever, S. L.;Sullivan, R. M.;Takase, Y.;Tassis, K.;Terenzi, L.;M. Tomasi;Tristram, M.;Vacher, L.;van Tent, B.;Vielva, P.;Wehus, I. K.;Westbrook, B.;Weymann-Despres, G.;Wollack, E. J.;Zannoni, M.^Penultimo;Zhou, Y.^Ultimo

2024

Abstract

We assess the capabilities of the LiteBIRD mission to map the hot gas distribution in the Universe through the thermal Sunyaev-Zeldovich (SZ) effect. Our analysis relies on comprehensive simulations incorporating various sources of Galactic and extragalactic foreground emission, while accounting for the specific instrumental characteristics of the LiteBIRD mission, such as detector sensitivities, frequency-dependent beam convolution, inhomogeneous sky scanning, and 1/f noise. We implement a tailored component-separation pipeline to map the thermal SZ Compton y-parameter over 98% of the sky. Despite lower angular resolution for galaxy cluster science, LiteBIRD provides full-sky coverage and, compared to the Planck satellite, enhanced sensitivity, as well as more frequency bands to enable the construction of an all-sky thermal SZ y-map, with reduced foreground contamination at large and intermediate angular scales. By combining LiteBIRD and Planck channels in the component-separation pipeline, we also obtain an optimal y-map that leverages the advantages of both experiments, with the higher angular resolution of the Planck channels enabling the recovery of compact clusters beyond the LiteBIRD beam limitations, and the numerous sensitive LiteBIRD channels further mitigating foregrounds. The added value of LiteBIRD is highlighted through the examination of maps, power spectra, and one-point statistics of the various sky components. After component separation, the 1/f noise from LiteBIRD's intensity channels is effectively mitigated below the level of the thermal SZ signal at all multipoles. Cosmological constraints on S8 = σ8 (Ωm /0.3)0.5 obtained from the LiteBIRD-Planck combined y-map power spectrum exhibits a 15 % reduction in uncertainty compared to constraints derived from Planck alone. This improvement can be attributed to the increased portion of uncontaminated sky available in the LiteBIRD-Planck combined y-map.

Scheda breve

Scheda completa

Scheda completa (DC)

	Parole chiave
	
				CMBR experiments; galaxy clusters; Sunyaev-Zeldovich effect;
			
	Settori scientifico-disciplinari dell'articolo (validi dal 09/05/2024)
	
				Settore PHYS-05/A - Astrofisica, cosmologia e scienza dello spazio
			
	Titolo del progetto
	
	Titolo Progetto
	
									Partecipazione italiana alla Fase A della missione LiteBIRD
								
	Acronimo
	
									LiteBIRD
								
	Nome finanziatore
	
										AGENZIA SPAZIALE ITALIANA
									
	N. Contratto
	
									2020-9-HH.0
								
	Data di pubblicazione
	
				11-dic-2024
			
	Rivista in ANCE
	
				JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS
			
	DOI
	
				https://dx.doi.org/10.1088/1475-7516/2024/12/026
			
	Tipologia
	
				Article (author)
			
	Appare nelle tipologie:
	
				01 - Articolo su periodico

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