On the dissection of degenerate cosmologies with machine learning

Merten, Julian; Giocoli, Carlo; Baldi, Marco; Meneghetti, M.; Peel, Austin; Lalande, Florian; Starck, Jean-Luc; Pettorino, V.

doi:10.1093/mnras/stz972

Cited by 44 publications

(33 citation statements)

References 112 publications

(123 reference statements)

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“…The DES Collaboration considers neutrino mass and extensions to GR in the same analysis [36], although they only state the resulting constraints on the MG parameters and not the neutrino masses. There are some promising signs that certain observables may be better at reducing or even breaking this degeneracy, such as higher-order weak lensing statistics [37] and weak lensing tomographic information at multiple redshifts [38]; as well as techniques that are superior at distinguishing models such as machine learning [39,40].…”

Section: Introductionmentioning

confidence: 99%

Investigating the degeneracy between modified gravity and massive neutrinos with redshift-space distortions

Wright

Koyama

Winther

et al. 2019

J. Cosmol. Astropart. Phys.

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There is a well known degeneracy between the enhancement of the growth of large-scale structure produced by modified gravity models and the suppression due to the free-streaming of massive neutrinos at late times. This makes the matter power-spectrum alone a poor probe to distinguish between modified gravity and the concordance ΛCDM model when neutrino masses are not strongly constrained. In this work, we investigate the potential of using redshift-space distortions (RSD) to break this degeneracy when the modification to gravity is scale-dependent in the form of Hu-Sawicki f (R). We find that if the linear growth rate can be recovered from the RSD signal, the degeneracy can be broken at the level of the dark matter field. However, this requires accurate modelling of the non-linearities in the RSD signal, and we here present an extension of the standard perturbation theory based model for non-linear RSD that includes both Hu-Sawicki f (R) modified gravity and massive neutrinos.

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Section: Introductionmentioning

confidence: 99%

Investigating the degeneracy between modified gravity and massive neutrinos with redshift-space distortions

Wright

Koyama

Winther

et al. 2019

J. Cosmol. Astropart. Phys.

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“…Machine learning provides a tool that is well suited to modelling cosmological structure formation, given its ability to learn non-linear relationships. In fact, machine learning tools have already proved useful in the context of structure formation in, for example, distinguishing between cosmological models (Merten et al 2019) or constructing mock dark matter halo catalogues (Berger & Stein 2019). However, understanding the inner workings of machine learning models remains a challenge.…”

Section: Introductionmentioning

confidence: 99%

An interpretable machine-learning framework for dark matter halo formation

Lucie-Smith

Peiris

Pontzen

2019

Monthly Notices of the Royal Astronomical Society

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We present a generalization of our recently proposed machine learning framework, aiming to provide new physical insights into dark matter halo formation. We investigate the impact of the initial density and tidal shear fields on the formation of haloes over the mass range 11.4 ≤ log(M/M ) ≤ 13.4. The algorithm is trained on an N-body simulation to infer the final mass of the halo to which each dark matter particle will later belong. We then quantify the difference in the predictive accuracy between machine learning models using a metric based on the Kullback-Leibler divergence. We first train the algorithm with information about the density contrast in the particles' local environment. The addition of tidal shear information does not yield an improved halo collapse model over one based on density information alone; the difference in their predictive performance is consistent with the statistical uncertainty of the density-only based model. This implies that our machine learning setup does not identify any significant role for the tidal shear in determining halo masses. This result is confirmed as we verify the ability of the initial conditions-to-halo mass mapping learnt from one simulation to generalize to independent simulations. Our work illustrates the broader potential of developing interpretable machine learning frameworks to gain physical understanding of non-linear large-scale structure formation.

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“…Now that the validity of the analytic model of the field cluster mass function for the f (R) gravity cosmology is confirmed, we repeat the whole process but for the fR4+0.3 eV, fR5+0.15 eV and fR6+0.06 eV cosmologies, which were shown to be degenerate with the GR in the standard statistics including the nonlinear density power spectrum, cluster mass functions and halo bias (Baldi et al 2014;Giocoli et al 2019). Figure 10 (Figure 11) depicts the same as Figure 1 (Figure 2) but for the fR4+0.3 eV, fR5+0.15 eV and fR6+0.06 eV cosmologies.…”

Section: Combined Effect Of F (R)+ν On β(Z)mentioning

confidence: 97%

“…Collapsed structures were identified through a FoF finder with a linking length parameter of l c = 0.16 followed by the unbinding procedure implemented in the SUBFIND code to identify the halo center and its spherical overdensity mass and radius for all gravitationally bound objects in each cosmology, similarly to what described above for the CoDECS simulations. For a detailed description of the technical details of the DUSTGRAIN-pathfinder simulations, see Giocoli et al (2019).…”

Section: Effect Of F (R) Gravity On β(Z)mentioning

confidence: 99%

“…Choosing as a viable MG the f (R) gravity in which the Ricci scalar term, R, in the Einstein-Hilbert action functional is replaced by an arbitrary function, f (R), Baldi et al (2014) numerically investigated a possible cosmic degeneracy between the ΛCDM + GR and the νCDM + f (R), and demonstrated that the two cosmologies cannot be discriminated from each other by several standard diagnostics such as the nonlinear density power spectra, halo bias and cluster mass functions (see also Hagstotz et al 2019;Garcia-Farieta et al 2019). The nonlinear growth rate functions, cluster velocity dispersions, and tomographic higher-order weak lensing statistics were proposed in subsequent works as candidate diagnostics that could be capable of breaking this cosmic degeneracy (Giocoli et al 2019;Hagstotz et al 2019), also employing Machine Learning techniques (Peel et al 2019;Merten et al 2019).…”

Section: Introductionmentioning

confidence: 99%

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Constraining the Neutrino Mass with the Drifting Coefficient of the Field Cluster Mass Function

Ryu

Lee

2020

ApJ

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We present a numerical analysis supporting the evidence that the redshift evolution of the drifting coefficient of the field cluster mass function is capable of breaking several cosmic degeneracies. This evidence is based on the data from the CoDECS and DUSTGRAIN-pathfinder simulations performed separately for various non-standard cosmologies including coupled dark energy, f (R) gravity and combinations of f (R) gravity with massive neutrinos as well as for the standard ΛCDM cosmology. We first numerically determine the field cluster mass functions at various redshifts in the range of 0 ≤ z ≤ 1 for each cosmology. Then, we compare the analytic formula developed in previous works with the numerically obtained field cluster mass functions by adjusting its drifting coefficient, β, at each redshift. It is found that the analytic formula with the best-fit coefficient provides a good match to the numerical results at all redshifts for all of the cosmologies. The empirically determined redshift evolution of the drifting coefficient, β(z), turns out to significantly differ among different cosmologies. It is also shown that even without using any prior information on the background cosmology the drifting coefficient, β(z), can discriminate with high statistical significance the degenerate non-standard cosmologies not only from the ΛCDM but also from one another. It is concluded that the evolution of the departure from the Einstein-de Sitter state and spherically symmetric collapse processes quantified by β(z) is a powerful probe of gravity and dark sector physics.

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On the dissection of degenerate cosmologies with machine learning

Cited by 44 publications

References 112 publications

Investigating the degeneracy between modified gravity and massive neutrinos with redshift-space distortions

Investigating the degeneracy between modified gravity and massive neutrinos with redshift-space distortions

An interpretable machine-learning framework for dark matter halo formation

Constraining the Neutrino Mass with the Drifting Coefficient of the Field Cluster Mass Function

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