Probing Massive Scalar/Vector Fields with Binary Pulsars

TL;DR

This paper explores how binary pulsar observations can test theories involving massive scalar and vector fields, providing new bounds on dark matter interactions and complementing gravitational-wave constraints.

Contribution

It introduces a generic framework to analyze orbital decay modifications due to massive fields and applies it to specific theories and observational data to set new bounds.

Findings

New constraints on dark matter interactions with pulsars

Potential for future black hole-pulsar binaries to improve bounds

Constraints on massive Brans-Dicke theory and axions are comparable to previous results

Abstract

Precision tests of general relativity can be conducted by observing binary pulsars. Theories with massive fields exist to explain a variety of phenomena from dark energy to the strong CP problem. Existing pulsar binaries, such as the white dwarf-pulsar binary J1738+0333, have been used to place stringent bounds on the scalar dipole emission, and radio telescopes may detect a pulsar orbiting a black hole in the future. In this paper, we study the ability of pulsar binaries to probe theories involving massive scalar and vector fields through the measurement of the orbital decay rate. With a generic framework, we describe corrections to orbital decay rate due to (a) modification of GR quadrupolar radiation and (b) dipolar radiation of a massive field. We then consider three concrete examples: (i) massive Brans-Dicke theory, (ii) general relativity with axions, and (iii) general relativity with bound dark matter and a dark force. Finally, we apply direct observations of J1738 and simulations of a black hole-pulsar binary to bound theory parameters such as field's mass and coupling constant. We find new constraints on bound dark matter interactions with PSR J1738, and a black hole-pulsar discovery would likely improve these further. Such bounds are complementary to future gravitational-wave bounds. Regarding other theories, we find similar constraints to previous pulsar measurements for massive Brans-Dicke theory and axions. These results show that new pulsar binaries will continue to allow for more stringent tests of gravity.