Decaying Dark Matter and Lyman-α forest constraints

Fuß, Lea; Garny, Mathias

doi:10.1088/1475-7516/2023/10/020

J. Cosmol. Astropart. Phys.

2023

DOI: 10.1088/1475-7516/2023/10/020

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Decaying Dark Matter and Lyman-α forest constraints

Lea Fuß,

Mathias Garny

Abstract: Decaying Cold Dark Matter (DCDM) is a model that is currently under investigation regarding primarily the S 8 tension between cosmic microwave background (CMB) and certain large-scale structure measurements. The decay into one massive and one (or more) massless daughter particle(s) leads to a suppression of the power spectrum in the late universe that depends on the relative mass splitting ϵ = (1 - m 2/M 2)/2 between the mother and massive daughter … Show more

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Cited by 9 publications

References 86 publications

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Probing the two-body decaying dark matter scenario with weak lensing and the cosmic microwave background

Bucko,

Giri,

Peters

et al. 2024

A&A

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Decaying dark matter (DDM) scenarios have recently regained attention due to their potential ability to resolve the well-known clustering (or $S_8$) tension between weak lensing (WL) and cosmic microwave background (CMB) measurements. In this paper, we investigate a well-established model where the original dark matter particle decays into a massless particle and a massive daughter particle. The latter obtains a velocity kick during the decay process that results in the suppression of the matter power spectrum at scales that are observable with WL shear observations. We perform the first fully non-linear WL analysis of this two-body decaying dark matter (Lambda DDM) scenario, including intrinsic alignment and baryonic feedback processes. We used the cosmic shear band power spectra from KiDS-1000 data and combined it with temperature and polarisation data from Planck in order to constrain the Lambda DDM model. We report new limits on the decay rate and mass splitting parameters that are significantly stronger than previous results, especially in the case of low-mass splittings. Regarding the $S_8$ tension, we found a reduction from about 3 to 2 sigma , depending on which statistical measure is applied. We therefore conclude that the two-body Lambda DDM model is able to reduce the $S_8$ tension without convincingly solving it.

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Probing the two-body decaying dark matter scenario with weak lensing and the cosmic microwave background

Bucko,

Giri,

Peters

et al. 2024

A&A

View full text Add to dashboard Cite

show abstract

Constraining hot dark matter sub-species with weak lensing and the cosmic microwave background radiation

Hervas Peters,

Schneider,

Bucko

et al. 2024

A&A

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Although it is well known that the bulk of dark matter (DM) has to be cold, the existence of an additional sub-dominant, hot species remains a valid possibility. In this paper we investigate the potential of the cosmic shear power spectrum to constrain such a mixed (hot plus cold) DM scenario with two additional free parameters, the hot-to-total DM fraction ($f_ hdm $) and the thermal mass of the hot component ($m_ hdm $). Running a Bayesian inference analysis for both the Kilo-Degree Survey cosmic shear data ( as well as the cosmic microwave background (CMB) temperature and polarisation data from Planck we derive new constraints for the mixed DM scenario. We find a 95 per cent confidence limit of $f_ hdm <0.08$ for a very hot species of $m_ hdm eV. This constraint is weakened to hdm <0.25$ for $m_ hdm eV. Scenarios with masses above hdm eV remain unconstrained by the data. Next to providing limits, we investigate the potential of mixed DM to address the clustering (or $S_8$) tension between lensing and the CMB. We find a reduction of the 2D ($ - S_8$) tension from 2.9sigma to 1.6sigma when going from a pure cold DM to a mixed DM scenario. When computing the 1D Gaussian tension on $S_8$ the improvement is milder, from 2.4sigma to 2.0sigma

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Reconciling cosmological tensions with inelastic dark matter and dark radiation in a U(1)_Dframework

Cho,

Choi,

Mahapatra

2024

J. Cosmol. Astropart. Phys.

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We propose a novel and comprehensive particle physics framework that addresses multiple cosmological tensions observed in recent measurements of the Hubble parameter, S 8, and Lyman-α forest data. Our model, termed `SIDR+z t ' (Self Interacting Dark Radiation with transition redshift), is based on an inelastic dark matter (IDM) scenario coupled with dark radiation, governed by a U(1) D gauge symmetry. This framework naturally incorporates cold dark matter (DM), strongly interacting dark radiation (SIDR), and the interactions between these components. The fluid-like behavior of the dark radiation component which originates from the self-quartic coupling of the U(1) D breaking scalar can suppress the free-streaming effects. Simultaneously, the interacting DM-DR system can attenuate the matter power spectrum at small scales. The inelastic nature of DM provides a distinct temperature dependence for the DM-DR interaction rate determined by the mass-splitting between the inelastic dark fermions which is crucial for resolving the Ly-α discrepancies. We present a cosmologically consistent analysis of the model by solving the relevant Boltzmann equations to obtain the energy density and number density evolution of different species of the model. The DR undergoes two “steps” of increased energy density when the heavier dark species freeze out and become non-relativistic, transferring their entropy to the dark radiation and enhancing ΔN eff. The analysis showcases the model's potential to uphold the Big Bang Nucleosynthesis (BBN) prediction of ΔN eff but dominantly producing additional contributions prior to recombination, while simultaneously achieving correct relic density of DM though an hybrid of freeze-in and non-thermal production.

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Decaying Dark Matter and Lyman-α forest constraints

Cited by 9 publications

References 86 publications

Probing the two-body decaying dark matter scenario with weak lensing and the cosmic microwave background

Probing the two-body decaying dark matter scenario with weak lensing and the cosmic microwave background

Constraining hot dark matter sub-species with weak lensing and the cosmic microwave background radiation

Reconciling cosmological tensions with inelastic dark matter and dark radiation in a U(1)_Dframework

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Product

Resources

About

Decaying Dark Matter and Lyman-α forest constraints

Cited by 9 publications

References 86 publications

Probing the two-body decaying dark matter scenario with weak lensing and the cosmic microwave background

Probing the two-body decaying dark matter scenario with weak lensing and the cosmic microwave background

Constraining hot dark matter sub-species with weak lensing and the cosmic microwave background radiation

Reconciling cosmological tensions with inelastic dark matter and dark radiation in a U(1)Dframework

Contact Info

Product

Resources

About

Reconciling cosmological tensions with inelastic dark matter and dark radiation in a U(1)_Dframework