A Lagrangian perturbation theory in the presence of massive neutrinos

Avilés, Alejandro; Banerjee, Arka

doi:10.1088/1475-7516/2020/10/034

Cited by 42 publications

(86 citation statements)

References 72 publications

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“…This increased precision, however, comes at the cost of very large inaccuracies beyond the nonlinear scale at which the self-gravitating dark matter fluid ceases to be perturbative (Blas et al 2014;McQuinn & White 2016). In addition, perturbative frameworks provide a rigorous, first-principles approach to include physics beyond the standard ΛCDM model in large-scale structure observables such as neutrinos, baryonic effects and more exotic early-universe scenarios (Lewandowski et al 2015;Senatore & Zaldarriaga 2017;Aviles & Banerjee 2020;Chen et al 2020c;Laguë et al 2020;Ivanov et al 2020; ? ; .…”

Section: Introductionmentioning

confidence: 99%

The cosmology dependence of galaxy clustering and lensing from a hybrid N-body–perturbation theory model

Kokron

DeRose

Chen

et al. 2021

Monthly Notices of the Royal Astronomical Society

114

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We implement a model for the two-point statistics of biased tracers that combines dark matter dynamics from N-body simulations with an analytic Lagrangian bias expansion. Using Aemulus, a suite of N-body simulations built for emulation of cosmological observables, we emulate the cosmology dependence of these nonlinear spectra from redshifts z = 0 to z = 2. We quantify the accuracy of our emulation procedure, which is sub-per cent at k = 1 hMpc−1 for the redshifts probed by upcoming surveys and improves at higher redshifts. We demonstrate its ability to describe the statistics of complex tracer samples, including those with assembly bias and baryonic effects, reliably fitting the clustering and lensing statistics of such samples at redshift z ≃ 0.4 to scales of kmax ≈ 0.6 hMpc−1. We show that the emulator can be used for unbiased cosmological parameter inference in simulated joint clustering and galaxy–galaxy lensing analyses with data drawn from an independent N-body simulation. These results indicate that our emulator is a promising tool that can be readily applied to the analysis of current and upcoming datasets from galaxy surveys.

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Section: Introductionmentioning

confidence: 99%

The cosmology dependence of galaxy clustering and lensing from a hybrid N-body–perturbation theory model

Kokron

DeRose

Chen

et al. 2021

Monthly Notices of the Royal Astronomical Society

114

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show abstract

“…It was found that the mean matter pairwise velocity decreases with increasing neutrino mass at those pair separations. For analytical predictions, Aviles & Banerjee (2020) studied the effect of massive neutrinos on pairwise velocity using Lagrangian perturbation theory for biased tracers at quasi-linear scales and above. The pairwise velocity measurement from kSZ experiments has been shown to be a novel probe to constrain the summed neutrino mass (Mueller et al 2015b), and provide complementary constraints with respect to galaxy clustering and CMB experiments.…”

Section: Introductionmentioning

confidence: 99%

Information content in mean pairwise velocity and mean relative velocity between pairs in a triplet

Kuruvilla

Aghanim

2021

A&A

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Velocity fields provide a complementary avenue to constrain cosmological information, either through the peculiar velocity surveys or the kinetic Sunyaev Zel’dovich effect. One of the commonly used statistics is the mean radial pairwise velocity. Here, we consider the three-point mean relative velocity (i.e. the mean relative velocities between pairs in a triplet). Using halo catalogs from the Quijote suite of N-body simulations, we first showcase how the analytical prediction for the mean relative velocities between pairs in a triplet achieve better than 4−5% accuracy using standard perturbation theory at leading order for triangular configurations with a minimum separation of r ≥ 50 h−1 Mpc. Furthermore, we present the mean relative velocity between pairs in a triplet as a novel probe of neutrino mass estimation. We explored the full cosmological information content of the halo mean pairwise velocities and the mean relative velocities between halo pairs in a triplet. We did this through the Fisher-matrix formalism using 22 000 simulations from the Quijote suite and by considering all triangular configurations with a minimum and a maximum separation of 20 h−1 Mpc and 120 h−1 Mpc, respectively. We find that the mean relative velocities in a triplet allows a 1σ neutrino mass (Mν) constraint of 0.065 eV, which is roughly 13 times better than the mean pairwise velocity constraint (0.877 eV). This information gain is not limited to neutrino mass, but it extends to other cosmological parameters: Ωm, Ωb, h, ns, and σ8, achieving an information gain of 8.9, 11.8, 15.5, 20.9, and 10.9 times, respectively. These results illustrate the possibility of exploiting the mean three-point relative velocities to constrain the cosmological parameters accurately from future cosmic microwave background experiments and peculiar velocity surveys.

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“…The neutrino flavour oscillations provide strong evidence of non null masses for these particles, this fact is also considered as one of the proofs for physics beyond the standard model of particles. However, despite their very small masses they have a non negligible contribution to the total cosmological density at low redshifts playing a relevant role on the formation of large scale structures [39]. The avoidance of clustering of matter inhomogeneities could also be due to the neutrino presence.…”

Section: B Massive Neutrinosmentioning

confidence: 99%

Holographic dark energy in curved spacetime for interacting fluids

Bolaños¹,

Crúz²,

Lepe³

et al. 2021

Preprint

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In this work we explore some aspects of two holographic models for dark energy within the interacting scenario for the dark sector with the inclusion of spatial curvature. A statistical analysis for each holographic model is performed together with their corresponding extensions given by the consideration of massive neutrinos. The first holographic approach considers the usual formula proposed by Li for the dark energy density with a constant parameter c and for the second model we have a function c(z) instead a constant parameter, this latter model is inspired in the apparent horizon. By considering the best fit values of the cosmological parameters we show that the interaction term for each holographic model, Q, keeps positive along the cosmic evolution and exhibits a future singularity for a finite value of the redshift, this is inherited from the Hubble parameter.The temperatures for the components of the dark sector are computed and have a growing behavior in both models. The cosmic evolution in this context it is not adiabatic and the second law it is fulfilled only under certain well-established conditions for the temperatures of the cosmic components and the interacting Q-term.

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A Lagrangian perturbation theory in the presence of massive neutrinos

Cited by 42 publications

References 72 publications

The cosmology dependence of galaxy clustering and lensing from a hybrid N-body–perturbation theory model

The cosmology dependence of galaxy clustering and lensing from a hybrid N-body–perturbation theory model

Information content in mean pairwise velocity and mean relative velocity between pairs in a triplet

Holographic dark energy in curved spacetime for interacting fluids

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