The Dipole Magnetic Field and Spin-down Evolutions of The High Braking Index Pulsar PSR J1640-4631

Abstract

In this work, we interpreted the high braking index of PSR J1640-4631 with a combination of the magneto-dipole radiation and dipole magnetic field decay models. By introducing a mean rotation energy conversion coefficient ζ, the ratio of the total high-energy photon energy to the total rotation energy loss in the whole life of the pulsar, and combining the pulsar's high-energy and timing observations with reliable nuclear equation of state, we estimate the pulsar's initial spin period, P0 (17-44) ms, corresponding to the moment of inertia I (0.8-2.1)× 1045 g cm2. Assuming that PSR J1640-4631 has experienced a long-term exponential decay of the dipole magnetic field, we calculate the true age t age, the effective magnetic field decay timescale τD, and the initial surface dipole magnetic field at the pole Bp(0) of the pulsar to be (2900-3100) yrs, 1.07(2)×105 yrs, and (1.84-4.20)×1013 G, respectively. The measured braking index of n=3.15(3) for PSR J1640-4631 is attributed to its long-term dipole magnetic field decay and a low magnetic field decay rate, dB p/dt -(1.66-3.85)×108 G yr-1. Our model can be applied to both the high braking index (n>3) and low braking index (n<3) pulsars, tested by the future polarization, timing, and high-energy observations of PSR J1640-4631.