The hierarchical cosmic web and assembly bias

Coloma-Nadal, J.M.; Kitaura, F.-S.; García-Farieta, J.E.; Sinigaglia, F.; Favole, G.; Forero Sánchez, D.

doi:10.1088/1475-7516/2024/07/083

J. Cosmol. Astropart. Phys.

2024

DOI: 10.1088/1475-7516/2024/07/083

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The hierarchical cosmic web and assembly bias

J.M. Coloma-Nadal,

F.-S. Kitaura,

J.E. García-Farieta

et al.

Abstract: Accurate modeling of galaxy distributions is paramount for cosmological analysis using galaxy redshift surveys. However, this endeavor is often hindered by the computational complexity of resolving the dark matter halos that host these galaxies. To address this challenge, we propose the development of effective assembly bias models down to small scales, i.e., going beyond the local density dependence capturing non-local cosmic evolution. We introduce a hierarchical cosmic web classification that indirectly cap… Show more

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2024

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Cited by 3 publications

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Fast simulation mapping: From standard to modified gravity cosmologies using the bias assignment method

García-Farieta,

Balaguera-Antolínez,

Kitaura

2024

A&A

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We assess the effectiveness of a non-parametric bias model in generating mock halo catalogues for modified gravity (MG) cosmologies, relying on the distribution of dark matter from either MG or Lambda cold dark matter ( simulations. We aim to generate halo catalogues that effectively capture the distinct impact of MG, ensuring high accuracy in both two- and three-point statistics for a comprehensive analysis of large-scale structures. We investigated the inclusion of MG in non-local bias to directly map the tracers onto fields, which would significantly reduce computational costs. We employed the bias assignment method ( BAM ) to model halo distribution statistics by leveraging seven high-resolution COLA simulations of MG cosmologies. Taking cosmic-web dependences into account when learning the bias relations, we designed two experiments to map the MG effects: one utilising the consistent MG density fields and the other employing the benchmark \ density field. BAM generates MG halo catalogues from both calibration experiments with excellent summary statistics, achieving a $ 1<!PCT!>$ accuracy in the power spectrum across a wide range of $k$ modes, with minimal differences well below 10<!PCT!> for modes subject to cosmic variance, particularly below $k<0.07$ The reduced bispectrum remains consistent with the reference catalogues within 10<!PCT!> for the studied configuration. Our results demonstrate that a non-linear and non-local bias description can model the effects of MG starting from a field.

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Fast simulation mapping: From standard to modified gravity cosmologies using the bias assignment method

García-Farieta,

Balaguera-Antolínez,

Kitaura

2024

A&A

View full text Add to dashboard Cite

show abstract

CosmoMIA: cosmic web-based redshift space halo distribution

Forero Sánchez,

Kitaura,

Sinigaglia

et al. 2024

J. Cosmol. Astropart. Phys.

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Modern galaxy surveys demand extensive survey volumes and resolutions surpassing current dark matter-only simulations' capabilities. To address this, many methods employ effective bias models on the dark matter field to approximate object counts on a grid. However, realistic catalogs necessitate specific coordinates and velocities for a comprehensive understanding of the Universe. In this research, we explore sub-grid modeling to create accurate catalogs, beginning with coarse grid number counts at resolutions of approximately 5.5 h -1 Mpc per side. These resolutions strike a balance between modeling nonlinear damping of baryon acoustic oscillations and facilitating large-volume simulations. Augmented Lagrangian Perturbation Theory (ALPT) is utilized to model the dark matter field and motions, replicating the clustering of a halo catalog derived from a massive simulation at z = 1.1. Our approach involves four key stages: Tracer Assignment: Allocating dark matter particles to tracers based on grid cell counts, generating additional particles to address discrepancies. Attractor Identification: Defining attractors based on particle cosmic web environments, acting as gravitational focal points. Tracer Collapse: Guiding tracers towards attractors, simulating structure collapse. Redshift Space Distortions: Introducing redshift space distortions to simulated catalogs using ALPT and a random dispersion term. Results demonstrate accurate reproduction of monopoles and quadrupoles up to wave numbers of approximately k = 0.6 h Mpc-1. This method holds significant promise for galaxy surveys like DESI, EUCLID, and LSST, enhancing our understanding of the cosmos across scales.

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The dependence of halo bias on the protohalo shape alignment with the initial tidal field

Lee,

Moon

2024

J. Cosmol. Astropart. Phys.

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We present a numerical evidence supporting the primordial origin of secondary halo bias even on the galactic mass scale. Analyzing the data from the TNG 300-1 simulations, we investigate the dependence of halo bias on the degree of misalignment between the protohalo inertia and initial tidal tensors, τ, measured at redshift, z i =127. From the TNG 300-1 galactic halos in logarithmic mass range of 10.5 < m ≡ log[M/(h -1 M ⊙)] ≤ 13 identified at z=0, 0.5 and 1, a clear signal of τ bias is detected. For the case that τ is measured from the initial tidal field smoothed on the scale of Rf /(h -1Mpc) ≲ 1, the halo τ bias is found to be very similar in its tendency and amplitude to the spin bias at all of the three redshifts, if the effects of backsplash halos are properly eliminated. For the case of Rf /(h -1Mpc) = 2, the τ bias at z=1 turns out to behave like the age bias, diminishing rapidly in the range of m > 12. At z=0 and 0.5, however, the τ and age bias factors show large differences in their overall strengths, which is attributed to the dominant nonlinear effects that undermine the former but enhance the latter. Given these numerical results along with the previous finding [1] that τ shares a large amount of mutual information with the formation epochs and spin parameters of galactic halos, it is concluded that the origins of halo age and spin bias must be closely linked with the primordial factor, τ, and that the difference in the tendency between the two bias factors on the galactic mass scale reflects the multi-scale influence of τ on the halo secondary properties.

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The hierarchical cosmic web and assembly bias

Cited by 3 publications

References 192 publications

Fast simulation mapping: From standard to modified gravity cosmologies using the bias assignment method

Fast simulation mapping: From standard to modified gravity cosmologies using the bias assignment method

CosmoMIA: cosmic web-based redshift space halo distribution

The dependence of halo bias on the protohalo shape alignment with the initial tidal field

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