Modelling annual and orbital variations in the scintillation of the relativistic binary PSR J1141-6545

Abstract

We have observed the relativistic binary pulsar PSR J1141-6545 over a period of 6 years using the Parkes 64 m radio telescope, with a focus on modelling the diffractive intensity scintillations to improve the accuracy of the astrometric timing model. The long-term scintillation, which shows orbital and annual variations, allows us to measure parameters that are difficult to measure with pulsar timing alone. These include: the orbital inclination i; the longitude of the ascending node ; and the pulsar system transverse velocity. We use the annual variations to resolve the previous ambiguity in the sense of the inclination angle. Using the correct sense, and a prior probability distribution given by a constraint from pulsar timing (i=733), we find =24.81.8 and we estimate the pulsar distance to be D=10+4-3 kpc. This then gives us an estimate of this pulsar's proper motion of μαδ=2.91.0 mas yr-1 in right ascension and μδ=1.80.6 mas yr-1 in declination. Finally, we obtain measurements of the spatial structure of the interstellar electron density fluctuations, including: the spatial scale and anisotropy of the diffraction pattern; the distribution of scattering material along the line of sight; and spatial variation in the strength of turbulence from epoch to epoch. We find that the scattering is dominated by a thin screen at a distance of (0.7240.008)D, with an anisotropy axial ratio A r = 2.140.11.