Cosmic dissonance: are new physics or systematics behind a short sound horizon?

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Dokumenter

  • aa36720-19

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  • Nikki Arendse
  • Wojtak, Radoslaw Jan
  • Agnello, Adriano
  • Geoff C-F Chen
  • Christopher D. Fassnacht
  • Dominique Sluse
  • Stefan Hilbert
  • Martin Millon
  • Vivien Bonvin
  • Kenneth C. Wong
  • Frederic Courbin
  • Sherry H. Suyu
  • Simon Birrer
  • Tommaso Treu
  • Leon V. E. Koopmans

Context. Persistent tension between low-redshift observations and the cosmic microwave background radiation (CMB), in terms of two fundamental distance scales set by the sound horizon r(d) and the Hubble constant H-0, suggests new physics beyond the Standard Model, departures from concordance cosmology, or residual systematics.

Aims. The role of different probe combinations must be assessed, as well as of different physical models that can alter the expansion history of the Universe and the inferred cosmological parameters.

Methods. We examined recently updated distance calibrations from Cepheids, gravitational lensing time-delay observations, and the tip of the red giant branch. Calibrating the baryon acoustic oscillations and type Ia supernovae with combinations of the distance indicators, we obtained a joint and self-consistent measurement of H-0 and r(d) at low redshift, independent of cosmological models and CMB inference. In an attempt to alleviate the tension between late-time and CMB-based measurements, we considered four extensions of the standard Lambda CDM model.

Results. The sound horizon from our different measurements is r(d)=(137 +/- 3(stat) +/- 2(syst.)) Mpc based on absolute distance calibration from gravitational lensing and the cosmic distance ladder. Depending on the adopted distance indicators, the combined tension in H-0 and r(d) ranges between 2.3 and 5.1 sigma, and it is independent of changes to the low-redshift expansion history. We find that modifications of Lambda CDM that change the physics after recombination fail to provide a solution to the problem, for the reason that they only resolve the tension in H-0, while the tension in r(d) remains unchanged. Pre-recombination extensions (with early dark energy or the effective number of neutrinos N-eff = 3.24 +/- 0.16) are allowed by the data, unless the calibration from Cepheids is included.

Conclusions. Results from time-delay lenses are consistent with those from distance-ladder calibrations and point to a discrepancy between absolute distance scales measured from the CMB (assuming the standard cosmological model) and late-time observations. New proposals to resolve this tension should be examined with respect to reconciling not only the Hubble constant but also the sound horizon derived from the CMB and other cosmological probes.

OriginalsprogEngelsk
ArtikelnummerA57
TidsskriftAstronomy & Astrophysics
Vol/bind639
Antal sider13
ISSN0004-6361
DOI
StatusUdgivet - 7 jul. 2020

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