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| Main Author: | |
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| Format: | Preprint |
| Published: |
2024
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2411.11743 |
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Table of Contents:
- It is found that a non-minimally coupled scalar tensor theory, Thawing Gravity (TG), can explain multiple tensions plaguing the standard cosmological model $Λ$CDM while fitting better to observations than the latter. Using the standard Bayes model comparison method, TG has moderate evidence over $Λ$CDM with a Bayes factor $\ln B=+1.5$ in the baseline analysis including CMB, BAO and SNIa. In the baseline+$H_0$ analysis which further takes into account the Cepheids calibration of the SNIa distance ladder from SH0ES, TG has very strong evidence over $Λ$CDM with $\ln B=+11.8$. In particular, TG yields $H_0=71.78\pm0.86 \ {\rm km/s/Mpc}$ and $S_8=0.793\pm0.012$, consistent with both the local $H_0$ measurement and the large scale structure surveys. TG predicts a prerecombination Newtonian constant $G_{\rm CMB}$ different from today's value $G_N$. A $\sim2σ$ hint for $G_{\rm CMB}/G_N>1$ is recovered in the baseline analysis with CMB+BAO+SNIa, which becomes a $>4σ$ detection when one further takes into account the local $H_0$ measurement. The obtained $G_{\rm CMB}/G_N$ is consistent with current BBN constraint and can be tested by future observations.