Challenging the Presence of Scalar Charge and Dipolar Radiation in Binary Pulsars

TL;DR

This paper demonstrates that in certain scalar-tensor theories like Gauss-Bonnet gravity, neutron stars cannot have scalar charges, challenging previous assumptions and indicating black hole observations are more effective for constraining such theories.

Contribution

The paper proves neutron stars in Gauss-Bonnet gravity cannot possess scalar charge, thus evading binary pulsar constraints and shifting focus to black hole observations for testing these theories.

Findings

Neutron stars in Gauss-Bonnet gravity have no scalar charge.

Black holes in Gauss-Bonnet gravity can have scalar charge.

Black hole observations can provide stronger constraints on the theory.

Abstract

Corrections to general relativity that introduce long-ranged scalar fields which are non-minimally coupled to curvature typically predict that neutron stars possess a non-trivial scalar field profile. An observer far from a star is most sensitive to the spherically-symmetric piece of this profile that decays linearly with the inverse of the distance, the so-called scalar charge, which is related to the emission of dipolar radiation from compact binaries. The presence of dipolar radiation has the potential to very strongly constrain extended theories of gravity. These facts may lead people to believe that gravitational theories with long-ranged scalar fields have already been constrained strongly from binary pulsar observations. Here we challenge this "lore" by investigating the decoupling limit of Gauss-Bonnet gravity as an example, in which the scalar field couples linearly to the Gauss-Bonnet density in the action. We prove a theorem that neutron stars in this theory cannot possess a scalar charge. Thus Gauss-Bonnet gravity evades the strong binary pulsar constraints on dipole radiation. We discuss the astrophysical systems yielding the best constraints on Gauss-Bonnet gravity and related quadratic gravity theories. To achieve this we explicitly compute the scalar charge for slowly-rotating neutron stars in quadratic gravity theories. In generic case, either neutron star-binary or neutron star-black hole systems can be used to constrain the theory, but Gauss-Bonnet gravity evades the neutron star-binary constraints. However, black holes in Gauss-Bonnet gravity do anchor scalar charge. The best constraints on Gauss-Bonnet gravity will thus come from black hole observations, for example via pulsar-black hole binaries. We estimate these constraints to be ten times better than the current estimated bound, and also include estimated constraints on generic quadratic gravity theories.