Probing dark energy with tomographic weak-lensing aperture mass statistics

Martinet, N.; Harnois-Déraps, Joachim; Jullo, Eric; Schneider, Peter

doi:10.1051/0004-6361/202039679

Cited by 33 publications

(43 citation statements)

References 106 publications

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“…Consequently, the combination of both probes yields even tighter constraints, as seen in recent applications to observational data (e.g., Martinet et al 2018;Harnois-Déraps et al 2020). With future Stage IV surveys, this combination is also expected to improve not only our measurement of the growth of structure parameter S 8 by a factor of two, but also that of the dark energy equation of state w 0 (Martinet et al 2021) and of the sum of neutrino masses Σm ν (Li et al 2019), by factors of three and two, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…So far, most analyses have focused on studying the correlation between the shape distortions of pairs of galaxies as a function of their separation: the so-called shear two-point correlation function (γ-2PCF; e.g., Troxel et al 2018;Hikage et al 2019;Asgari et al 2021). However, it is becoming clear that other estimators, and in particular those based on weak-lensing mass maps, outperform the standard γ-2PCF (e.g., Dietrich & Hartlap 2010;Ajani et al 2020;Zürcher et al 2021;Coulton et al 2020;Martinet et al 2021). Indeed, mass maps are highly sensitive to the nonGaussian part of the matter distribution that arises from the nonlinear growth of structures, which contains information that is overlooked by two-point estimators.…”

Section: Introductionmentioning

confidence: 99%

“…Building on these previous analyses, and exploiting the cosmological analysis pipeline introduced in Martinet et al (2021), we measure for the first time the effect of baryons on the dark matter and dark energy cosmological parameters in a tomographic Stage-IV lensing survey setup. We focus on the particular case of aperture-mass (M ap ; Schneider 1996) maps, which are particularly well suited for cosmological analyses.…”

Section: Introductionmentioning

confidence: 99%

“…Both effects redistribute the matter in and around DM haloes, but the exact amplitude of the feedback varies between simulations (see Chisari et al 2019, for a recent review on feedback in cosmological hydrodynamical simulations). Extending the simulation suites of Martinet et al (2021) based on the SLICS and the cosmo-SLICS, we construct Euclid-like mocks from the Magneticum hydrodynamical simulation. We measure the impact of baryons on the γ-2PCF, on the lensing peaks, minima, and on the lensing PDF, in the form of a multiplicative baryon bias correction factor.…”

Section: Introductionmentioning

confidence: 99%

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Impact of baryons in cosmic shear analyses with tomographic aperture mass statistics

Martinet

Castro

Harnois-Déraps

et al. 2021

A&A

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NonGaussian cosmic shear statistics based on weak-lensing aperture mass (Map) maps can outperform the classical shear two-point correlation function (γ-2PCF) in terms of cosmological constraining power. However, reaching the full potential of these new estimators requires accurate modeling of the physics of baryons as the extra nonGaussian information mostly resides at small scales. We present one such modeling based on the Magneticum hydrodynamical simulation for the KiDS-450 and DES-Y1 surveys and a Euclid-like survey. We compute the bias due to baryons on the lensing PDF and the distribution of peaks and voids in Map maps and propagate it to the cosmological forecasts on the structure growth parameter S8, the matter density parameter Ωm, and the dark energy equation of state w0 using the SLICS and cosmo-SLICS sets of dark-matter-only simulations. We report a negative bias of a few percent on S8 and Ωm and also measure a positive bias of the same level on w0 when including a tomographic decomposition. These biases reach ∼5% when combining Map statistics with the γ-2PCF as these estimators show similar dependency on the AGN feedback. We verify that these biases constitute a less than 1σ shift on the probed cosmological parameters for current cosmic shear surveys. However, baryons need to be accounted for at the percentage level for future Stage IV surveys and we propose to include the uncertainty on the AGN feedback amplitude by marginalizing over this parameter using multiple simulations such as those presented in this paper. Finally, we explore the possibility of mitigating the impact of baryons by filtering the Map map but find that this process would require suppressing the small-scale information to a point where the constraints would no longer be competitive.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Impact of baryons in cosmic shear analyses with tomographic aperture mass statistics

Martinet

Castro

Harnois-Déraps

et al. 2021

A&A

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“…Another weak lensing probe of large-scale structure is represented by cosmic voids, namely under-dense regions of the large-scale matter field (Colberg et al 2008;Pisani et al 2019). Local minima of weak lensing convergence maps, namely pixels with values smaller than their eight neighbouring pixels, have been proposed as tracers of the matter distribution voids to infer cosmological parameters, both in a mono-scale setting (Coulton et al 2020;Martinet et al 2021;Davies et al 2020) and in a multi-scale setting (Zürcher et al 2020). More specifically, Coulton et al (2020) found that lensing minima alone are slightly less constraining than the peaks alone and, in agreement with Martinet et al (2021) and Zürcher et al (2020), that the combination of the two statistics produces significantly tighter constraints than the power spectrum.…”

Section: Introductionmentioning

confidence: 99%

Starletℓ₁-norm for weak lensing cosmology

Ajani

Starck

Pettorino

2021

A&A

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We present a new summary statistic for weak lensing observables, higher than second order, suitable for extracting non-Gaussian cosmological information and inferring cosmological parameters. We name this statistic the ‘starlet ℓ1-norm’ as it is computed via the sum of the absolute values of the starlet (wavelet) decomposition coefficients of a weak lensing map. In comparison to the state-of-the-art higher-order statistics – weak lensing peak counts and minimum counts, or the combination of the two – the ℓ1-norm provides a fast multi-scale calculation of the full void and peak distribution, avoiding the problem of defining what a peak is and what a void is: the ℓ1-norm carries the information encoded in all pixels of the map, not just the ones in local maxima and minima. We show its potential by applying it to the weak lensing convergence maps provided by the MassiveNus simulations to get constraints on the sum of neutrino masses, the matter density parameter, and the amplitude of the primordial power spectrum. We find that, in an ideal setting without further systematics, the starlet ℓ1-norm remarkably outperforms commonly used summary statistics, such as the power spectrum or the combination of peak and void counts, in terms of constraining power, representing a promising new unified framework to simultaneously account for the information encoded in peak counts and voids. We find that the starlet ℓ1-norm outperforms the power spectrum by 72% on Mν, 60% on Ωm, and 75% on As for the Euclid-like setting considered; it also improves upon the state-of-the-art combination of peaks and voids for a single smoothing scale by 24% on Mν, 50% on Ωm, and 24% on As.

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Persistent homology in cosmic shear

Heydenreich¹,

Brück

Burger³

et al. 2022

A&A

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We demonstrate how to use persistent homology for cosmological parameter inference in a tomographic cosmic shear survey. We obtain the first cosmological parameter constraints from persistent homology by applying our method to the first-year data of the Dark Energy Survey. To obtain these constraints, we analyse the topological structure of the matter distribution by extracting persistence diagrams from signal-to-noise maps of aperture masses. This presents a natural extension to the widely used peak count statistics. Extracting the persistence diagrams from the cosmo-SLICS, a suite of N -body simulations with variable cosmological parameters, we interpolate the signal using Gaussian processes and marginalise over the most relevant systematic effects, including intrinsic alignments and baryonic effects.For the structure growth parameter, we find S8 = 0.747 +0.025 −0.031 , which is in full agreement with other late-time probes. We also constrain the intrinsic alignment parameter to A = 1.54 ± 0.52, which constitutes a detection of the intrinsic alignment effect at almost 3σ.

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Probing dark energy with tomographic weak-lensing aperture mass statistics

Cited by 33 publications

References 106 publications

Impact of baryons in cosmic shear analyses with tomographic aperture mass statistics

Impact of baryons in cosmic shear analyses with tomographic aperture mass statistics

Starletℓ₁-norm for weak lensing cosmology

Persistent homology in cosmic shear

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Probing dark energy with tomographic weak-lensing aperture mass statistics

Cited by 33 publications

References 106 publications

Impact of baryons in cosmic shear analyses with tomographic aperture mass statistics

Impact of baryons in cosmic shear analyses with tomographic aperture mass statistics

Starletℓ1-norm for weak lensing cosmology

Persistent homology in cosmic shear

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Product

Resources

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Starletℓ₁-norm for weak lensing cosmology