Black holes and neutron stars in massive Hellings-Nordtvedt theory

TL;DR

This paper investigates black hole and neutron star solutions in the Hellings-Nordtvedt vector-tensor theory, analyzing asymptotic structures, constraints, and astrophysical implications of different coupling sectors.

Contribution

It identifies the conditions under which monopole-like and Schwarzschild solutions arise, and explores neutron star properties within the $A^2{ m R}$ sector of the theory.

Findings

The asymptotic vacuum condition restricts the allowed coupling sectors.

The $A^ u A^ ho{ m R}_{ u ho}$ sector admits monopole-like solutions.

The $A^2{ m R}$ sector allows asymptotically flat Schwarzschild solutions with nontrivial vector fields.

Abstract

Hellings-Nordtvedt theory is a vector-tensor theory in which a vector field $A_\mu$ is nonminimally coupled to curvature through two independent interactions $A^2{\cal R}$ and $A^\mu A^\nu{\cal R}_{\mu\nu}$. When supplemented by a potential whose zero-energy minimum occurs at nonzero $A^2$, the restricted $A^\mu A^\nu{\cal R}_{\mu\nu}$ sector is known to admit black-hole and neutron-star solutions with a monopole-like asymptotic vacuum structure. We examine whether this structure is a generic consequence of the nonzero vector vacuum or instead relies on the special Ricci-tensor coupling. By analyzing the field equations near spatial infinity, we show that the asymptotic vacuum condition is incompatible with generic nonzero values of both couplings and instead selects two allowed single-coupling sectors. The $A^\mu A^\nu{\cal R}_{\mu\nu}$ sector reproduces the known monopole-like asymptotics, whereas the $A^2{\cal R}$ sector admits an asymptotically flat Schwarzschild metric with a nontrivial radial vector field. We further compute the Noether mass in the $A^2{\cal R}$ sector, derive the corresponding Solar-System constraints, and construct neutron-star configurations. Although the weak-field deviation is constrained to be small, neutron stars can still show appreciable departures from both general relativity and the Ricci-tensor-coupling sector in their masses, radii, and moments of inertia. Our results identify that the $A^2{\cal R}$ sector of massive Hellings-Nordtvedt theory as a viable and useful framework for studying strong-field compact objects with a nonzero vector vacuum while remaining compatible with weak-field tests.