Impact of Star Pressure on γ in Modified Gravity beyond Post-Newtonian Approach

Abstract

We provide a concrete example exhibiting marked deviation from the PPN approximation in a modified theory of gravity. Specifically, we derive the exact formula for the Robertson parameter γ in Brans-Dicke gravity for compact mass sources, explicitly incorporating the pressure content of these sources. We achieve this by exploiting the integrability of the 00-component of the Brans-Dicke field equation. In place of the conventional PPN result γPPN=ω+1ω+2, we obtain the analytical expression γ\,exact=ω+1+(ω+2)ω+2+(ω+1) where is the ratio of the total pressure P*+2P* and total energy E* contained within the mass source. Our non-perturbative formula is valid for all field strengths and types of matter comprising the mass source. We draw four key conclusions: (1) The usual γPPN formula is violated in the presence of pressure, viz. when ≠0, revealing a limitation of the PPN approximation in Brans-Dicke gravity. (2) The PPN result mainly stems from the assumption of pressureless matter. Even in the weak-field star case, non-zero pressure leads to a violation of the PPN γ formula. Conversely, the PPN result is a good approximation for low-pressure matter, i.e. when ≈0, for all field strengths. (3) Observational constraints on γ set joint bounds on ω and , with the latter representing a global characteristic of a mass source. If the equation of state of matter in the mass source approaches the ultra-relativistic form, entailing 1, γ\,exact converges to 1 irrespective of ω. (4) In a broader context, our findings indicate the latent significance of considering the interior structure of stars in observational astronomy.