# Solar System Constraints on Scalar-Tensor Gravity with Positive Coupling   Constant upon Cosmological Evolution of the Scalar Field

**Authors:** David Anderson, Nicolas Yunes

arXiv: 1705.06351 · 2017-09-27

## TL;DR

This paper investigates scalar-tensor gravity theories with positive coupling constants, showing they can satisfy Solar System constraints and produce neutron star scalarization under specific conditions, expanding the viable models beyond previously studied classes.

## Contribution

It demonstrates that scalar-tensor theories with positive conformal exponent can pass Solar System tests and induce neutron star scalarization, unlike the negative exponent class.

## Key findings

- Solar System tests are passed only in a small parameter subset.
- Neutron star scalarization is possible with careful parameter selection.
- Scalar charge in positive exponent theories is significantly smaller.

## Abstract

Scalar-tensor theories of gravity modify General Relativity by introducing a scalar field that couples non-minimally to the metric tensor, while satisfying the weak-equivalence principle. These theories are interesting because they have the potential to simultaneously suppress modifications to Einstein's theory on Solar System scales, while introducing large deviations in the strong field of neutron stars. Scalar-tensor theories can be classified through the choice of conformal factor, a scalar that regulates the coupling between matter and the metric in the Einstein frame. The class defined by a Gaussian conformal factor with negative exponent has been studied the most because it leads to spontaneous scalarization (i.e. the sudden activation of the scalar field in neutron stars), which consequently leads to large deviations from General Relativity in the strong field. This class, however, has recently been shown to be in conflict with Solar System observations when accounting for the cosmological evolution of the scalar field. We study whether this remains the case when the exponent of the conformal factor is positive, as well as in another class of theories defined by a hyperbolic conformal factor. We find that in both of these scalar-tensor theories, Solar System tests are passed only in a very small subset of parameter space, for a large set of initial conditions compatible with Big Bang Nucleosynthesis. However, while we find that it is possible for neutron stars to scalarize, one must carefully select the coupling parameter to do so, and even then, the scalar charge is typically two orders of magnitude smaller than in the negative exponent case. Our study suggests that future work on scalar-tensor gravity, for example in the context of tests of General Relativity with gravitational waves from neutron star binaries, should be carried out within the positive coupling parameter class.

## Full text

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## Figures

21 figures with captions in the complete paper: https://tomesphere.com/paper/1705.06351/full.md

## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1705.06351/full.md

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Source: https://tomesphere.com/paper/1705.06351