Abstract
ABSTRACT Radio pulsars provide some of the most important constraints for our understanding of matter at supranuclear densities. So far, these constraints are mostly given by precision mass measurements of neutron stars (NS). By combining single measurements of the two most massive pulsars, J0348+0432 and J0740+6620, the resulting lower limit of 1.98 M⊙ (99 per cent confidence) of the maximum NS mass, excludes a large number of equations of state (EOSs). Further EOS constraints, complementary to other methods, are likely to come from the measurement of the moment of inertia (MOI) of binary pulsars in relativistic orbits. The Double Pulsar, PSR J0737−3039A/B, is the most promising system for the first measurement of the MOI via pulsar timing. Reviewing this method, based in particular on the first MeerKAT observations of the Double Pulsar, we provide well-founded projections into the future by simulating timing observations with MeerKAT and the SKA. For the first time, we account for the spin-down mass-loss in the analysis. Our results suggest that an MOI measurement with 11 per cent accuracy (68 per cent confidence) is possible by 2030. If by 2030 the EOS is sufficiently well known, however, we find that the Double Pulsar will allow for a 7 per cent test of Lense–Thirring precession, or alternatively provide a ∼3σ-measurement of the next-to-leading order gravitational wave damping in GR. Finally, we demonstrate that potential new discoveries of double NS systems with orbital periods shorter than that of the Double Pulsar promise significant improvements in these measurements and the constraints on NS matter.
Highlights
Neutron stars (NSs) are among the most compact and exotic objects in nature, comprised of extraordinarily dense matter that is not accessible in laboratory experiments
It is fair to assume that the gravitational wave (GW) and X-ray observations will place a more stringent constraint on the equations of state (EOSs) within the 10 years, and if the EOS can be known with sufficient precision, we can in turn use this information as an input to our analysis, test the LT precession and constrain theories of gravity with the Double Pulsar
We have developed a consistent method to measure the moment of inertia (MOI) of radio pulsars, which has been applied to mock data for the Double Pulsar
Summary
Neutron stars (NSs) are among the most compact and exotic objects in nature, comprised of extraordinarily dense matter that is not accessible in laboratory experiments. About 3000 pulsars are known, and the ability of radio astronomers to measure pulsar properties precisely via a technique known as “pulsar timing”, suggests that important information about the EOS of NSs can be derived from such measurements. The most direct and best known route is to measure the masses of NSs precisely This is possible in binary pulsars using relativistic orbital effects, potentially combined with other information.
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