Euclid: Forecasts from the void-lensing cross-correlation

Bonici, M.; Carbone, C.; Davini, S.; Vielzeuf, P.; Paganin, L.; Cardone, V.; Hamaus, N.; Pisani, A.; Hawken, A. J.; Kovacs, A.; Nadathur, S.; Contarini, S.; Verza, G.; Tutusaus, I.; Marulli, F.; Moscardini, L.; Aubert, M.; Giocoli, C.; Pourtsidou, A.; Camera, S.; Escoffier, S.; Caminata, A.; Martinelli, M.; Pallavicini, M.; Pettorino, V.; Sakr, Z.; Sapone, D.; Testera, G.; Tosi, S.; Yankelevich, V.; Amara, A.; Auricchio, N.; Baldi, M.; Bonino, D.; Branchini, E.; Brescia, M.; Brinchmann, J.; Capobianco, V.; Carretero, J.; Castellano, M.; Cavuoti, S.; Cledassou, R.; Congedo, G.; Conversi, L.; Copin, Y.; Corcione, L.; Courbin, F.; Cropper, M.; Da Silva, A.; Degaudenzi, H.; Douspis, M.; Dubath, F.; Duncan, C. A. J.; Dupac, X.; Dusini, S.; Ealet, A.; Farrens, S.; Ferriol, S.; Fosalba, P.; Frailis, M.; Franceschi, E.; Fumana, M.; Gomez-Alvarez, P.; Garilli, B.; Gillis, B.; Grazian, A.; Grupp, F.; Guzzo, L.; Haugan, S. V. H.; Holmes, W.; Hormuth, F.; Hornstrup, A.; Jahnke, K.; Kummel, M.; Kermiche, S.; Kiessling, A.; Kilbinger, M.; Kunz, M.; Kurki-Suonio, H.; Laureijs, R.; Ligori, S.; Lilje, P. B.; Lloro, I.; Maiorano, E.; Mansutti, O.; Marggraf, O.; Markovic, K.; Massey, R.; Medinaceli, E.; Melchior, M.; Meneghetti, M.; Meylan, G.; Moresco, M.; Munari, E.; Niemi, S. M.; Padilla, C.; Paltani, S.; Pasian, F.; Pedersen, K.; Percival, W. J.; Pires, S.; Polenta, G.; Poncet, M.; Popa, L.; Raison, F.; Rebolo, R.; Renzi, A.; Rhodes, J.; Rossetti, E.; Saglia, R.; Sartoris, B.; Scodeggio, M.; Secroun, A.; Seidel, G.; Sirignano, C.; Sirri, G.; Stanco, L.; Starck, J. -L.; Surace, C.; Tallada-Crespi, P.; Tavagnacco, D.; Taylor, A. N.; Tereno, I.; Toledo-Moreo, R.; Torradeflot, F.; Valentijn, E. A.; Valenziano, L.; Wang, Y.; Weller, J.; Zamorani, G.; Zoubian, J.; Andreon, S.

doi:10.48550/arxiv.2206.14211

Cited by 2 publications

(3 citation statements)

References 66 publications

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“…Cosmic voids from recent galaxy surveys have been used in a wide range of cosmological applications. They are sensitive to geometric effects, such as the Alcock-Paczyński effect (Alcock & Paczynski 1979;Sutter et al 2012Sutter et al , 2014bHamaus et al 2016;Mao et al 2017a) and baryonic acoustic oscillations (Kitaura et al 2016;Liang et al 2016;Chan & Hamaus 2021;Forero-Sánchez et al 2022;Khoraminezhad et al 2022), as well as redshift-space distortions (RSD, Paz et al 2013;Hamaus et al 2014aHamaus et al , 2015Cai et al 2016;Chuang et al 2017;Achitouv et al 2017;Hawken et al 2017;Hamaus et al 2017;Correa et al 2019;Achitouv 2019;Hawken et al 2020;Hamaus et al 2020;Nadathur et al 2020;Correa et al 2022;Aubert et al 2022), weak lensing (Melchior et al 2014;Clampitt & Jain 2015;Chantavat et al 2016;Gruen & Dark Energy Survey Collaboration 2016;Chantavat et al 2017;Cai et al 2017;Sánchez et al 2017b;Baker et al 2018;Brouwer et al 2018;Fang et al 2019;Vielzeuf et al 2021;Davies et al 2021;Bonici et al 2022), the integrated Sa...…”

Section: Introductionmentioning

confidence: 99%

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Euclid: Cosmological forecasts from the void size function

Contarini

Verza

Pisani

et al. 2022

A&A

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The Euclid mission -with its spectroscopic galaxy survey covering a sky area over 15 000 deg 2 in the redshift range 0.9 < z < 1.8 -will provide a sample of tens of thousands of cosmic voids. This paper thoroughly explores for the first time the constraining power of the void size function on the properties of dark energy (DE) from a survey mock catalogue, the official Euclid Flagship simulation. We identified voids in the Flagship light-cone, which closely matches the features of the upcoming Euclid spectroscopic data set. We modelled the void size function considering a state-of-the art methodology: we relied on the volume-conserving (Vdn) model, a modification of the popular Sheth & van de Weygaert model for void number counts, extended by means of a linear function of the large-scale galaxy bias. We found an excellent agreement between model predictions and measured mock void number counts. We computed updated forecasts for the Euclid mission on DE from the void size function and provided reliable void number estimates to serve as a basis for further forecasts of cosmological applications using voids. We analysed two different cosmological models for DE: the first described by a constant DE equation of state parameter, w, and the second by a dynamic equation of state with coefficients w 0 and w a . We forecast 1σ errors on w lower than 10% and we estimated an expected figure of merit (FoM) for the dynamical DE scenario FoM w 0 ,wa = 17 when considering only the neutrino mass as additional free parameter of the model. The analysis is based on conservative assumptions to ensure full robustness, and is a pathfinder for future enhancements of the technique. Our results showcase the impressive constraining power of the void size function from the Euclid spectroscopic sample, both as a stand-alone probe, and to be combined with other Euclid cosmological probes.

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Section: Introductionmentioning

confidence: 99%

“…We note that we leave for future work the measurement of the void size function in the photometric galaxy distribution from Euclid, for which the data treatment greatly differs from the spectroscopic one (see e.g. Pollina et al 2019 andBonici et al 2022).…”

Section: Introductionmentioning

confidence: 99%

Euclid: Cosmological forecasts from the void size function

Contarini

Verza

Pisani

et al. 2022

A&A

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“…This opens up a vast observational window to conduct cosmological experiments, allowing us to make use of voids ranging from a few (or possibly less) to hundreds of Mpc in diameter. As linear dynamics holds up in all voids irrespective of their size, void catalogs can not only be extended via enlarging survey volumes towards higher redshifts (as planned for a number of next-generation surveys, such as Euclid [126][127][128]), but also by conducting deeper observations that provide denser tracer samples and hence smaller sub-voids (e.g., as planned for Roman [129] and 4MOST [130]), even at low redshift. This would open up the possibility to maximize the number of observable linear modes of the density field of large-scale structure that can be exploited for the purpose of cosmological inference, far beyond the previously imposed limits.…”

Section: Discussionmentioning

confidence: 99%

Why Cosmic Voids Matter: Nonlinear Structure & Linear Dynamics

Schuster¹,

Hamaus²,

Dolag³

et al. 2022

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We use the Magneticum suite of state-of-the-art hydrodynamical simulations to identify cosmic voids based on the watershed technique and investigate their most fundamental properties across different resolutions in mass and scale. This encompasses the distributions of void sizes, shapes, and content, as well as their radial density and velocity profiles traced by the distribution of cold dark matter particles and halos. We also study the impact of various tracer properties, such as their sparsity and mass, and the influence of void merging on these summary statistics. Our results reveal that all of the analyzed void properties are physically related to each other and describe universal characteristics that are largely independent of tracer type and resolution. Most notably, we find that the motion of tracers around void centers is perfectly consistent with linear dynamics, both for individual, as well as stacked voids. Despite the large range of scales accessible in our simulations, we are unable to identify the occurrence of nonlinear dynamics even inside voids of only a few Mpc in size. This suggests voids to be among the most pristine probes of cosmology down to scales that are commonly referred to as highly nonlinear in the field of large-scale structure.

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Euclid: Forecasts from the void-lensing cross-correlation

Cited by 2 publications

References 66 publications

Euclid: Cosmological forecasts from the void size function

Euclid: Cosmological forecasts from the void size function

Why Cosmic Voids Matter: Nonlinear Structure & Linear Dynamics

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