Phys. Rev. D 109, 023527 (2024) - Omnipotent dark energy: A phenomenological answer to the Hubble tension

Omnipotent dark energy: A phenomenological answer to the Hubble tension

Shahnawaz A. Adil, Özgür Akarsu, Eleonora Di Valentino, Rafael C. Nunes, Emre Özülker, Anjan A. Sen, and Enrico Specogna

Phys. Rev. D 109, 023527 – Published 22 January 2024

Abstract

This paper introduces the class of omnipotent dark energy (DE) models characterized by nonmonotonic energy densities that are capable of attaining negative values with corresponding equation of state parameters featuring phantom divide line (PDL) crossings and singularities. These nontrivial features are phenomenologically motivated by findings of previous studies that reconstruct cosmological functions from observations, and the success of extensions of $Λ CDM$ , whose actual or effective DE density is omnipotent, in alleviating the observational discordance within $Λ CDM$ . As an example, we focus on one embodiment of omnipotent DE, viz. the DE parametrization introduced in Di Valentino et al. [Dark energy with phantom crossing and the $H_{0}$ tension, Entropy 23, 404 (2021)] (DMS20). By updating and extending the datasets used in the original paper where it was introduced, we confirm the effectiveness of DMS20 in alleviating the observational discrepancies. Additionally, we uncover that its negative DE density feature, importance of which was not previously investigated, plays a crucial role in alleviating the tensions, along with the PDL crossing feature that the parametrization presupposes. In particular, we find that there is a positive correlation between the $H_{0}$ parameter and the scale ( $a_{p}$ ) at which DE density transitions from negative to positive, in agreement with previous studies that incorporate this transition feature. For our full dataset, the model yields $H_{0} = 70.05 \pm 0.64$ (68% CL) relaxing the $H_{0}$ tension with a preference of crossing to negative DE densities ( $a_{p} > 0$ at 99% CL), along with the constraint $a_{m} = 0.92 2_{- 0.035}^{+ 0.041}$ on the scale of the presupposed PDL crossing.

Received 19 June 2023
Accepted 27 November 2023

DOI:https://doi.org/10.1103/PhysRevD.109.023527

Physics Subject Headings (PhySH)

Cosmological parameters Dark energy Evolution of the Universe

Gravitation, Cosmology & Astrophysics

Authors & Affiliations

Shahnawaz A. Adil ^1,*, Özgür Akarsu ^2,†, Eleonora Di Valentino^3,‡, Rafael C. Nunes ^4,5,§, Emre Özülker ^2,∥, Anjan A. Sen^6,¶, and Enrico Specogna^3,**

¹Department of Physics, Jamia Millia Islamia, New Delhi-110025, India
²Department of Physics, Istanbul Technical University, Maslak 34469 Istanbul, Turkey
³School of Mathematics and Statistics, University of Sheffield, Hounsfield Road, Sheffield S3 7RH, United Kingdom
⁴Instituto de Física, Universidade Federal do Rio Grande do Sul, 91501-970 Porto Alegre, Rio Grande do Sul, Brazil
⁵Divisão de Astrofísica, Instituto Nacional de Pesquisas Espaciais, Avenida dos Astronautas 1758, São José dos Campos, 12227-010, São Paulo, Brazil
⁶Centre for Theoretical Physics, Jamia Millia Islamia, New Delhi-110025, India

^*shazadil14@gmail.com
^†akarsuo@itu.edu.tr
^‡e.divalentino@sheffield.ac.uk
^§rafadcnunes@gmail.com
^∥ozulker17@itu.edu.tr
^¶aasen@jmi.ac.in
^**especogna1@sheffield.ac.uk

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Vol. 109, Iss. 2 — 15 January 2024

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Figure 1
The evolution of DMS20 DE densities divided by $ρ_{c 0}$ for various values of the free parameters $a_{m}$ , $α$ , and $β$ ; and, their corresponding EoS parameters. The filled disks correspond to solutions of $a_{p}$ , squares to $a_{m}$ , and diamonds to $a_{n}$ of the plots with matching colors. The dashed line in the top panel shows a constant energy density, hence, its EoS parameter describes the PDL. The vertical dotted line marks the present day, and on its right, we briefly extend the plots to the future. For all the plots in the figure, we use $ρ_{DE 0} / ρ_{c 0} = 0.7$ .
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Figure 2
1D posterior distribution and 2D contour plots for a few parameters of interest.
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Figure 3
Two-dimensional (at 68% and 95% CL) marginalized posterior distributions of $H_{0}$ vs the free parameter $a_{m}$ , and the derived parameters $a_{p}$ and $a_{n}$ . The blue band shows the $Λ CDM$ value $H_{0} = 67.27 \pm 0.60 km s^{- 1} {Mpc}^{- 1}$ (68% CL) [7] inferred from Planck 2018 with $1 σ$ and $2 σ$ errors, and the gray band shows the SH0ES measurement $H_{0} = 73.04 \pm 1.04 km s^{- 1} {Mpc}^{- 1}$ (68% CL) [34].
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Figure 4
Posterior distributions (68% and 95% CL) of $H (z) / (1 + z)$ for the $Planck + PantheonPlus & SH 0 ES$ (shown in red) and $Planck + BAO + PantheonPlus & SH 0 ES$ (shown in violet) data combinations. For comparison, we show the $Λ CDM$ Plik best fit result from Ref. [7] with a dashed gray line. The vertical bars show various data with 68% errors. The blue bars are the TRGB $H_{0} = 69.8 \pm 0.8 km s^{- 1} {Mpc}^{- 1}$ measurement [138] and the SH0ES $H_{0} = 73.04 \pm 1.04 km s^{- 1} {Mpc}^{- 1}$ measurement [34]. The rest are BAO data that can be found in Ref. [104] and references therein: the red bars are the BOSS DR12 consensus Galaxy (from $z_{eff} = 0.38$ , 0.51) measurements; the black bar is the eBOSS DR16 LRG (from $z_{eff} = 0.70$ ) measruement; the green bar is the eBOSS DR16 Quasar (from $z_{eff} = 1.48$ ); the purple bars are the eBOSS DR16 Ly- $α$ -Ly- $α$ (from $z_{eff} = 2.33$ ) and eBOSS DR16 Ly- $α$ -quasar (from $z_{eff} = 2.33$ but shifted to $z = 2.35$ in the figures for visual clarity) measurements.
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Figure 5
The figure shows the posteriors of $ρ_{DE} (z) / ρ_{c 0}$ (top panels) and $w_{DE} (z)$ (bottom panels); the more frequent the lines, the more probable. Violet is for the analysis with the Planck+PantheonPlus&SH0ES dataset, and red is for $Planck + BAO + PantheonPlus & SH 0 ES$ . The bolder solid lines correspond to the best-fit sample of their corresponding dataset. The horizontal gray dashed line in the top panels show the Plik best fit value in Ref. [7] for comparison, and the horizontal black dashed line in the bottom panels is the PDL. The vertical dashed lines in the bottom panels show the redshifts DE crosses to negative values for the best fit samples of the same color, i.e., they show the best fit $z_{p}$ ; these dashed lines also correspond to the asymptotes of $w_{DE} (z)$ for the best-fit plots. The inset plots show the same posteriors but with a linear scale on the horizontal axes.
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Figure 6
The figure shows the posteriors of $ρ_{{DE}^{+}} (z) / ρ_{c 0}$ and $ρ_{Λ} / ρ_{c 0}$ on the top panels, and $w_{{DE}^{+}} (z)$ on the bottom panel; the more frequent the lines, the more probable. Violet is for the analysis with the $Planck + PantheonPlus & SH 0 ES$ dataset, and red is for $Planck + BAO + PantheonPlus & SH 0 ES$ . The bolder solid lines correspond to the best fit sample of their corresponding dataset. For comparison, the horizontal gray dashed line in the top panels show the Plik best fit value of $ρ_{Λ}$ in Ref. [7]. In the bottom panels, the horizontal black dashed line is the PDL and the horizontal black dotted line shows the limit $w_{{DE}^{+}} (a = 0) = - 4 / 3$ that holds by construction (see Sec. 3a).
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Physical Review D

covering particles, fields, gravitation, and cosmology

Omnipotent dark energy: A phenomenological answer to the Hubble tension

Shahnawaz A. Adil, Özgür Akarsu, Eleonora Di Valentino, Rafael C. Nunes, Emre Özülker, Anjan A. Sen, and Enrico Specogna

Phys. Rev. D 109, 023527 – Published 22 January 2024

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Physical Review D

covering particles, fields, gravitation, and cosmology

Omnipotent dark energy: A phenomenological answer to the Hubble tension

Shahnawaz A. Adil, Özgür Akarsu, Eleonora Di Valentino, Rafael C. Nunes, Emre Özülker, Anjan A. Sen, and Enrico Specogna

Phys. Rev. D 109, 023527 – Published 22 January 2024

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