Spin evolution of neutron stars in two modes: implication for millisecond pulsars
Abstract
An understanding of spin frequency () evolution of neutron stars in the low-mass X-ray binary (LMXB) phase is essential to explain the observed -distribution of millisecond pulsars (MSPs), and to probe the stellar and binary physics, including the possibility of continuous gravitational wave emission. Here, using numerical computations we conclude that can evolve in two distinctly different modes, as may approach a lower spin equilibrium value ( eq,per) for persistent accretion for a long-term average accretion rate (M av) greater than a critical limit (M av,crit), and may approach a higher effective spin equilibrium value ( eq,eff) for transient accretion for M av < M av,crit. For example, when M av falls below M av,crit for an initially persistent source, increases considerably due to transient accretion, which is counterintuitive. We also find that, contrary to what was suggested, a fast or sudden decrease of M av to zero in the last part of the LMXB phase is not essential for the genesis of spin-powered MSPs, and neutron stars could spin up in this M av-decreasing phase. Our findings imply that the traditional way of -evolution computation is inadequate in most cases, even for initially persistent sources, and may not even correctly estimate whether increases or decreases.
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