Showing papers by "Pawan Kumar published in 1998"

On the orbital decay of the PSR J0045-7319 binary

Abstract: Recent observations of PSR J0045-7319, a radio pulsar in a close eccentric orbit with a massive main-sequence B star companion, indicate that the system's orbital period is decreasing on a timescale ~5 ? 105 yr. Timing observations of PSR J0045-7319 also indicate that the B star is rotating rapidly, perhaps close to its breakup rotation rate. For rapid (supersynchronous) prograde rotation of the B star, tidal dissipation leads to an increasing orbital period for the binary system, while for retrograde rotation of any magnitude, the orbital period decreases with time. We show that if tidal effects are to account for the observed orbital decay of the PSR J0045-7319 binary, the B star must have retrograde rotation. This implies that the supernova that produced the pulsar in this binary system likely had a dipole anisotropy. For a reasonably wide range of retrograde rotation rates, the energy in the dynamical tide of the B star needs to be dissipated in about one orbital period in order to account for the observed orbital evolution time. We show, however, that the radiative dissipation of the dynamical tide in a rigidly rotating B star is too inefficient by a factor of ? 103, regardless of the magnitude of the rotation rate. We describe how, when the surface of the B star is rotating nearly synchronously, the energy in the dynamical tide is dissipated in less than an orbital period, thus reconciling the theoretical and observed rates of orbital evolution. Nonlinear parametric decay of the equilibrium tide, for rigid retrograde rotation of the B star, may also be able to explain the observed rate of orbital evolution, although the margin of instability is too small to draw definitive conclusions about the relevance of this process for the PSR J0045-7319 binary.

Dissipation of a Tide in a Differentially Rotating Star

Abstract: The orbital period of the binary pulsar PSR J0045-7319, which is located in our neighboring galaxy, the Small Magellanic Cloud (SMC), appears to be decreasing on a timescale of ~5 × 105 yr. This timescale is more than 2 orders of magnitude smaller than what is expected from the standard theory of tidal dissipation. Kumar & Quataert proposed that this rapid evolution could be understood provided that the neutron star's companion, a main-sequence B star, has set up significant differential rotation. The goal of this paper is to evaluate the redistribution of angular momentum in the B star due to meridional circulation and shear stresses and to calculate the evolution of the rotation profile when these two processes act in competition with the deposition of momentum by the tidal wave. We find that although angular momentum redistribution is important, the B star may continue to have sufficient differential rotation so that tidal waves are entirely absorbed as they arrive at the surface. The mechanism proposed by Kumar & Quataert to speed up the orbital evolution of the SMC binary pulsar should therefore work as suggested.