The effective magnetic field decay of radio pulsars: insights from the statistical properties of their spin frequency's second derivatives

Abstract

We present a new method to investigate the effective magnetic field decay of isolated neutron stars, from the analysis of the long-term timing data of a large sample of radio pulsars 2010MNRAS.402.1027H. There are some differences between the distributions of frequency's second derivatives of the pulsar spins with different effective field decay timescales. Kolmogorov-Smirnov tests are performed to reexamine the consistency of distributions of the simulated and reported data for a series values of decay timescales. We show that the timescale of the effective field decay exceeds 5~ Myr for pulsars with spin-down age τ C< 107~ yr or 100~ Myr for pulsars with 107<τ C< 109~ yr in the sample. The result does not depend on any specific theories of the field evolution, the inclination decay or the variation in the moment of inertia. It is also found that the extent of the closed line region of the magnetic field is close to the light cylinder r lc, i.e., the corotating radius r c≈ r lc is a good approximation for the observed pulsar population.