Towards testing the theory of gravity with DESI: summary statistics, model predictions and future simulation requirements

Alam, Shadab; Arnold, Christian; Avilés, Alejandro; Bean, Rachel; Cai, Yan-Chuan; Cautun, Marius; Cervantes-Cota, Jorge L.; Cuesta-Lázaro, Carolina; Devi, N. Chandrachani; Eggemeier, Alexander; Fromenteau, S.; González‐Morales, Alma X.; Halenka, V.; He, Jingliang; Hellwing, Wojciech A.; Hernández‐Aguayo, César; Ishak, Mustapha; Koyama, K.; Li, Baojiu; Macorra, Axel de la; Rizo, Jennifer Menesses; Miller, Christopher J.; Mueller, Eva Maria; Niz, Gustavo; Ntelis, Pierros; Otero, Matias Rodríguez; Sabiu, Cristiano G.; Slepian, Zachary; Stark, Andrew; Valenzuela, O.; Valogiannis, Georgios; Vargas-Magaña, Mariana; Winther, Hans A.; Zarrouk, Pauline; Zhao, Gong-Bo; Zheng, Yi

doi:10.1088/1475-7516/2021/11/050

Cited by 56 publications

(49 citation statements)

References 358 publications

(483 reference statements)

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“…However, departures from GR on cosmological scales are still possible and have received significant attention as a potentially important piece to understand the accelerated expansion of the Universe. In fact, testing gravity on cosmological scales is one of the primary science goals of the upcoming generation of large-scale structure observations and gravitational wave detectors (Alam et al 2021;Belgacem et al 2019).…”

Section: Modified Gravitymentioning

confidence: 99%

Large-scale dark matter simulations

Angulo

Hahn

2022

Living Rev Comput Astrophys

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We review the field of collisionless numerical simulations for the large-scale structure of the Universe. We start by providing the main set of equations solved by these simulations and their connection with General Relativity. We then recap the relevant numerical approaches: discretization of the phase-space distribution (focusing on N-body but including alternatives, e.g., Lagrangian submanifold and Schrödinger–Poisson) and the respective techniques for their time evolution and force calculation (direct summation, mesh techniques, and hierarchical tree methods). We pay attention to the creation of initial conditions and the connection with Lagrangian Perturbation Theory. We then discuss the possible alternatives in terms of the micro-physical properties of dark matter (e.g., neutralinos, warm dark matter, QCD axions, Bose–Einstein condensates, and primordial black holes), and extensions to account for multiple fluids (baryons and neutrinos), primordial non-Gaussianity and modified gravity. We continue by discussing challenges involved in achieving highly accurate predictions. A key aspect of cosmological simulations is the connection to cosmological observables, we discuss various techniques in this regard: structure finding, galaxy formation and baryonic modelling, the creation of emulators and light-cones, and the role of machine learning. We finalise with a recount of state-of-the-art large-scale simulations and conclude with an outlook for the next decade.

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Section: Modified Gravitymentioning

confidence: 99%

Large-scale dark matter simulations

Angulo

Hahn

2022

Living Rev Comput Astrophys

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“…We have reviewed the analytical study of marked statistics that up-weight low density regions in the Universe. [16][17][18][19] The idea behind marked statistics is to assign a value (the mark) to each entity in a catalogue and perform statistics over the resulting weighted objects. An efficient way to suppress non-linearities is by choosing a mark that gives more weight to objects that reside in low density regions, which become less important as one consider higher density regions.…”

Section: Discussionmentioning

confidence: 99%

“…Other authors working with simulations have used different parameters and mark functions. 18,[26][27][28] (3) Weight the density field of tracers 1 + δ X (x) with the mark function m(δ(x), R) to obtain the marked density field…”

Section: The Importance Of Up-weight Low Energy Density Regionsmentioning

confidence: 99%

Testing modified gravity theories with marked statistics

Avilés¹

2021

Preprint

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In the last two decades, Modified Gravity (MG) models have been proposed to explain the accelerated expansion of the Universe. However, one of the main difficulties these theories face is that they must reduce to General Relativity (GR) at sufficiently high energy densities, such as those found in the solar system. To achieve this, MG theories typically employ so-called screening mechanisms: nonlinear effects that bring them to GR at the appropriate limits. For this reason, low-energy regions where the screenings do not operate efficiently, such as cosmic voids, are identified as ideal laboratories for testing GR. Hence, the use of marked statistics that up-weight low energy densities have been proposed for being implemented with data from future galaxy surveys. In this proceeding note, we show how to construct theoretical templates for such statistics and test their accuracy with the use of N-body simulations.

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“…We use a full N-body simulation suite called elephant, which was introduced and validated in [37], to benchmark the results of our runs based on COLA. The elephant suite was produced using ecosmog [19], a MG extension of the adaptive mesh refinement code RAMSES [38] that solves the exact equations for the fifth force; these simulations were recently used to create mock galaxy catalogues in [2,39,40] 3 . Table 1 describes the parameters of the suite such as the box size, the mass resolution and the gravity models implemented, and the cosmological parameters employed are:…”

Section: Simulation Suitesmentioning

confidence: 99%

“…It is crucial to make accurate theoretical predictions of the properties of the LSS on non-linear scales to successfully constrain the gravity model (see e.g. [2]). This can be achieved by means of cosmological simulations, but O(10 3 ) realisations must be produced to match the volume of Stage IV surveys and compute an accurate estimate of the covariance matrices.…”

Section: Introductionmentioning

confidence: 99%

Fast generation of mock galaxy catalogues in modified gravity models with COLA

Fiorini,

Koyama,

Izard

et al. 2021

Preprint

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We investigate the viability of producing galaxy mock catalogues with COmoving Lagrangian Acceleration (COLA) simulations in Modified Gravity (MG) models employing the Halo Occupation Distribution (HOD) formalism. In this work, we focus on two theories of MG: f (R) gravity with the chameleon mechanism, and a braneworld model (nDGP) that incorporates the Vainshtein mechanism. We use a suite of full N-body simulations in MG as a benchmark to test the accuracy of COLA simulations. At the level of Dark Matter (DM), we show that COLA accurately reproduces the matter power spectrum up to k ∼ 1 h Mpc −1 , while it is less accurate in reproducing the velocity field. To produce halo catalogues, we find that the rockstar halo-finder does not perform well with COLA simulations. On the other hand, using a simple Friends-of-Friends (FoF) finder and an empirical mass conversion from FoF to spherical over-density masses, we are able to produce halo catalogues in COLA that are in good agreement with those in N-body simulations. To consider the effects of the MG fifth force on the halo profile, we derive simple fitting formulae for the concentration-mass and the velocity dispersion-mass relations that we calibrate using rockstar halo catalogues in N-body simulations. We then use these results to extend the HOD formalism to modified gravity simulations in COLA. We use an HOD model with five parameters that we tune to obtain galaxy catalogues in redshift space. We find that despite the great freedom of the HOD model, MG leaves characteristic imprints in the redshift space power spectrum multipoles and these features are well captured by the COLA galaxy catalogues.

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Towards testing the theory of gravity with DESI: summary statistics, model predictions and future simulation requirements

Cited by 56 publications

References 358 publications

Large-scale dark matter simulations

Large-scale dark matter simulations

Testing modified gravity theories with marked statistics

Fast generation of mock galaxy catalogues in modified gravity models with COLA

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