Linearized Gravity in the Starobinsky Model: Perturbative Deviations from General Relativity
Abstract
In this work, we linearize the field equations of f(R) gravity using the Starobinsky model, R+R2/(6m2), and examine the modifications to General Relativity. We derive an equation for the trace, T, of the energy-momentum tensor, which we then decompose using an auxiliary field. This field satisfies the wave equation with T as its source, while simultaneously acting as an effective source for the classical deviation, h, governed by the Klein-Gordon equation. The fields were expressed in terms of Green's functions, whose symmetry properties facilitated the solution of the trace equation. Then hμ was determined in terms of a modified or effective matter-energy distribution. From this, the effective energy density was obtained as the usual energy density T00, plus a perturbative correction proportional to m-2, involving the Laplacian of the integral of T, weighted by the retarded propagator of the Klein-Gordon equation. Finally, we numerically computed the perturbative term in a binary star system, evaluating it as a function of m and spatial position near the stars. In all cases, the results illustrate how the gravitational influence of the stars diminishes with distance. Additionally, the perturbation decreases as m increases, consistently recovering the relativistic limit. These results highlight the role of modified gravity corrections in the vicinity of compact objects.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.