Uniting the Observed Dynamical Dark Energy Preference with the Discrepancies in Ωm and H0 across Cosmological Probes

Uniting the Observed Dynamical Dark Energy Preference with the Discrepancies in Ωm and H0 across Cosmological Probes

Recent results from Type Ia supernovae, baryon acoustic oscillations (BAOs), and the cosmic microwave background (CMB) indicate (1) potentially discrepant measurements of the matter density Ω _m and Hubble constant H _0 in the ΛCDM model when analyzed individually and (2) hint of dynamical dark ener...

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Bibliographic Details
Main Authors: Xianzhe TZ Tang, Dillon Brout, Tanvi Karwal, Chihway Chang, Vivian Miranda, Maria Vincenzi
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:The Astrophysical Journal Letters
Subjects:
Cosmology
Cosmological parameters
Dark energy
Cosmological constant
Dynamical evolution
Cosmic microwave background radiation
Online Access:https://doi.org/10.3847/2041-8213/adc4da
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Summary:Recent results from Type Ia supernovae, baryon acoustic oscillations (BAOs), and the cosmic microwave background (CMB) indicate (1) potentially discrepant measurements of the matter density Ω _m and Hubble constant H _0 in the ΛCDM model when analyzed individually and (2) hint of dynamical dark energy in a w _0 w _a CDM model when data are combined in a joint analysis. We examine whether underlying dynamical dark energy cosmologies favored by data would result in biases in Ω _m and H _0 for each probe when analyzed individually under ΛCDM. We generate mock data sets in w _0 w _a CDM cosmologies, fit the individual probes under the ΛCDM model, and find that expected biases in Ω _m are ∼0.03. Notably, the Ω _m differences between probes are consistent with values observed in real data sets. We also observe that mock DESI-BAO data sets generated in the w _0 w _a CDM cosmologies will lead to a biased measurement of H _0 higher by ∼1.2 km s ^−1 Mpc ^−1 when fitted under ΛCDM, appearing to mildly improve the Hubble tension, but as the true underlying H _0 is lower, the tension is in fact worsened. We find that the Ω _m discrepancies, the high BAO H _0 relative to the CMB, and the joint dynamical dark energy signal are all related effects that could be explained simultaneously with either new physics or new systematics. While it is possible to unite many of the discrepancies seen in recent analyses along a single axis, our results underscore the importance of understanding systematic differences in data sets, as they have unique impacts in different cosmological parameter spaces.
ISSN:2041-8205

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