Mass measurements and 3D orbital geometry of PSR J1933-6211

Abstract

PSR J1933-6211 is a 3.5-ms pulsar in a 12.8-d orbit with a white dwarf (WD). Its high proper motion and low dispersion measure result in such significant interstellar scintillation that high signal-to-noise detections require long observing durations or fortuitous timing. We turn to the sensitive MeerKAT telescope and, combined with historic Parkes data, leverage PSR J1933-6211's kinematic and relativistic effects to constrain its 3D orbital geometry and the component masses. We obtain precise proper motion and parallax estimates, and measure their effects as secular changes in the Keplerian orbital parameters: a variation in orbital period of 7(1) × 10-13 s s-1 and a change in projected semi-major axis of 1.60(5) × 10-14 s s-1. A self-consistent analysis of all kinematic and relativistic effects yields a distance of 1.6+0.2-0.3 kpc, an orbital inclination, i = 55(1) deg and a longitude of the ascending node, = 255+8-14 deg. The probability densities for and i and their symmetric counterparts, (180-i, 360-), are seen to depend on the fiducial orbit used to measure the time of periastron passage. We investigate this unexpected dependence and rule out software-related causes using simulations. Nevertheless, we constrain the pulsar and WD masses to 1.4+0.3-0.2 M and 0.43(5) M respectively. These strongly disfavour a helium-dominated WD. The orbital similarities between PSRs J1933-6211 and J1614-2230 suggest they underwent Case A Roche lobe overflow, an extended evolution while the companion star is still on the Main Sequence. However, with a mass of 1.4 M, PSR J1933-6211 has not accreted significant matter. This highlights the low accretion efficiency of the spin-up process and suggests that observed neutron star masses are mostly a result of supernova physics.