Testing gravity on cosmic scales: A case study of Jordan-Brans-Dicke theory

We provide an end-to-end exploration of a distinct modified gravitational theory in Jordan-Brans-Dicke (JBD) gravity, from an analytical and numerical description of the background expansion and linear perturbations, to the nonlinear regime captured with a hybrid suite of N-body simulations, to the cosmological constraints from existing probes of the expansion history, the large-scale structure, and the cosmic microwave background (CMB). We have focused on JBD gravity as it both approximates a wider class of Horndeski scalar-tensor theories on cosmological scales and allows us to adequately model the nonlinear corrections to the matter power spectrum. In a combined analysis of the Planck 2018 CMB temperature, polarization, and lensing reconstruction, together with Pantheon supernova distances and the Baryon Oscillation Spectroscopic Survey (BOSS) measurements of baryon acoustic oscillation distances, the Alcock-Paczynski effect, and the growth rate, we constrain the JBD coupling constant to omega BD 2.8 (95% CL), all in agreement with the standard model expectation. In fixing the sum of neutrino masses, the lower bound on the coupling constant strengthens to omega BD 1460 and omega BD > 2230 (both at 95% C.L.) in the restricted and unrestricted JBD models, respectively. We explore the impact of the JBD modeling choices, and show that a more restrictive parametrization of the coupling constant degrades the neutrino mass bound by up to a factor of three. In addition to the improved concordance between KiDS x 2dFLenS and Planck, the tension in the Hubble constant between Planck and the direct measurement of Riess et al. (2019) is reduced to similar to 3 sigma; however, we find no substantial model selection preference for JBD gravity relative to ?CDM. We further show that a positive shift in the effective gravitational constant suppresses the CMB damping tail, which might complicate future inferences of small-scale physics, given its degeneracy with the primordial helium abundance, the effective number of

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We provide a comprehensive exploration of a distinct modified gravitational theory in Jordan-Brans-Dicke (JBD) gravity, covering analytical and numerical descriptions of background expansion, linear perturbations, and nonlinear regimes. The JBD coupling constant is constrained through various cosmological probes, showing agreement with the standard model expectations. The lower bound on the coupling constant strengthens when fixing the sum of neutrino masses. Additionally, a positive shift in the effective gravitational constant impacts the CMB damping tail. No substantial preference for JBD gravity over ?CDM is found in model selection.