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Main Authors: Sharbaf, Z., Ferreras, I., Negri, A., Angthopo, J., Vecchia, C. Dalla, Lahav, O., Somerville, R. S.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.08945
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author Sharbaf, Z.
Ferreras, I.
Negri, A.
Angthopo, J.
Vecchia, C. Dalla
Lahav, O.
Somerville, R. S.
author_facet Sharbaf, Z.
Ferreras, I.
Negri, A.
Angthopo, J.
Vecchia, C. Dalla
Lahav, O.
Somerville, R. S.
contents Cosmological hydrodynamical simulations provide valuable insights on galaxy evolution when coupled with observational data. Comparisons with real galaxies are typically performed via scaling relations of the observables. Here we follow an alternative approach based on the spectral covariance in a model-independent way. We build upon previous work by Sharbaf et al. that studied the covariance of high quality SDSS continuum-subtracted spectra in a relatively narrow range of velocity dispersion ($σ\in [100,150]$\,km\,s$^{-1}$). Here the same analysis is applied to synthetic data from the EAGLE and Illustris TNG100 simulations, to assess the ability of these runs to mimic real galaxies. The real and simulated spectra are consistent regarding spectral covariance, although with subtle differences that can inform the implementation of subgrid physics. Spectral fitting done a posteriori on stacks segregated with respect to latent space reveals that the first principal component (PC1) is predominantly influenced by the stellar age distribution, with an underlying age-metallicity degeneracy. Good agreement is found regarding star formation prescriptions but there is disagreement with AGN feedback, that also affects the subset of quiescent galaxies. We show a substantial difference in the implementation of the AGN subgrid prescriptions, regarding central black hole seeding, that could lead to the mismatch. Differences are manifest between these two simulations in the star formation histories stacked with respect to latent space. We emphasise that this methodology only relies on the spectral covariance to assess whether simulations provide a true representation of galaxy formation.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08945
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Evaluating quenching in cosmological simulations of galaxy formation with spectral covariance in the optical window
Sharbaf, Z.
Ferreras, I.
Negri, A.
Angthopo, J.
Vecchia, C. Dalla
Lahav, O.
Somerville, R. S.
Cosmology and Nongalactic Astrophysics
Astrophysics of Galaxies
Cosmological hydrodynamical simulations provide valuable insights on galaxy evolution when coupled with observational data. Comparisons with real galaxies are typically performed via scaling relations of the observables. Here we follow an alternative approach based on the spectral covariance in a model-independent way. We build upon previous work by Sharbaf et al. that studied the covariance of high quality SDSS continuum-subtracted spectra in a relatively narrow range of velocity dispersion ($σ\in [100,150]$\,km\,s$^{-1}$). Here the same analysis is applied to synthetic data from the EAGLE and Illustris TNG100 simulations, to assess the ability of these runs to mimic real galaxies. The real and simulated spectra are consistent regarding spectral covariance, although with subtle differences that can inform the implementation of subgrid physics. Spectral fitting done a posteriori on stacks segregated with respect to latent space reveals that the first principal component (PC1) is predominantly influenced by the stellar age distribution, with an underlying age-metallicity degeneracy. Good agreement is found regarding star formation prescriptions but there is disagreement with AGN feedback, that also affects the subset of quiescent galaxies. We show a substantial difference in the implementation of the AGN subgrid prescriptions, regarding central black hole seeding, that could lead to the mismatch. Differences are manifest between these two simulations in the star formation histories stacked with respect to latent space. We emphasise that this methodology only relies on the spectral covariance to assess whether simulations provide a true representation of galaxy formation.
title Evaluating quenching in cosmological simulations of galaxy formation with spectral covariance in the optical window
topic Cosmology and Nongalactic Astrophysics
Astrophysics of Galaxies
url https://arxiv.org/abs/2411.08945