Abstract
Light degrees of freedom that modify gravity on cosmological scales must be ``screened" on solar system scales in order to be compatible with data. The Vainshtein mechanism achieves this through a breakdown of classical perturbation theory, as large interactions involving new degrees of freedom become important below the so-called Vainshtein radius. We begin to develop an extension of the Parameterized Post-Newtonian (PPN) formalism that is able to handle Vainshteinian corrections. We argue that theories with a unique Vainshtein scale must be expanded using two small parameters. In this Parameterized Post-Newtonian-Vainshteinian (PPNV) expansion, the primary expansion parameter that controls the PPN order is, as usual, the velocity v. The secondary expansion parameter, α, controls the strength of the Vainshteinian correction and is a theory-specific combination of the Schwarzschild radius and the Vainshtein radius of the source that is independent of its mass. We present the general framework and apply it to Cubic Galileon theory both inside and outside the Vainshtein radius. The PPNV framework can be used to determine the compatibility of such theories with solar system and other strong-field data.
Highlights
Tests of gravity in the solar system have reached incredible precision
This paper presents an extension of the Parameterized Post-Newtonian (PPN) framework, the Parametrised Post-Newtonian Vainshteinian (PPNV) framework that is able to handle Vainshteinian corrections and paving the way for determining the compatibility of such theories with solar system and other strong-field data
We have presented a general scheme for calculating the metric for theories exhibiting Vainshtein screening, in which there is a unique scale beyond the Schwarzschild radius where non-linearities begin to become important
Summary
The PPN formalism is a prescription for a perturbative expansion of the gravitational, matter and additional field equations of motion in successive orders of a small parameter, the velocity of matter v (in units of the speed of light). It was developed by Nordtvedt[3] and later. The metric perturbation hμν is further expanded in successive orders dictated by a small parameter: the velocity of matter v (we will assume units where the speed of light is unity). Let us discuss the Vainshtein mechanism and the modifications it introduces, leading to the PPNV expansion
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