Origin and binary evolution of millisecond pulsars

TL;DR

This paper reviews the formation channels and binary evolution processes leading to millisecond pulsars, emphasizing the recycling scenario, irradiation effects, and the evolutionary links with X-ray binaries and black widows.

Contribution

It provides a comprehensive overview of the binary evolution pathways and physical mechanisms that produce millisecond pulsars, including irradiation effects and transitional systems.

Findings

MSP formation linked to binary evolution and recycling.

Irradiation influences donor star evolution and system dynamics.

High MSP population in globular clusters explained by specific formation channels.

Abstract

We summarize the channels formation of neutron stars (NS) in single or binary evolution and the classic recycling scenario by which mass accretion by a donor companion accelerates old NS to millisecond pulsars (MSP). We consider the possible explanations and requirements for the high frequency of the MSP population in Globular Clusters. Basics of binary evolution are given, and the key concepts of systemic angular momentum losses are first discussed in the framework of the secular evolution of Cataclysmic Binaries. MSP binaries with compact companions represent end-points of previous evolution. In the class of systems characterized by short orbital period and low companion mass, we may instead be catching the recycling phase `in the act'. These systems are in fact either MSP, or low mass X--ray binaries (LMXB), some of which accreting X-ray MSP (AMXP), or even `transitional' systems from the accreting to the radio MSP stage. The donor structure is affected by irradiation due to X-rays from the accreting NS, or by the high fraction of MSP rotational energy loss emitted in the gamma rays range of the energy spectrum. X-ray irradiation leads to cyclic LMXB stages, causing super-Eddington mass transfer rates during the first phases of the companion evolution, and, possibly coupled with the angular momentum carried away by the non-accreted matter, helps to explain the high positive orbital period derivatives of some LMXB systems and account for the (apparently) different birthrates of LMXB and MSP. Irradiation by the MSP may be able to drive the donor to a stage in which either radio-ejection (in the redbacks) or mass loss due to the companion expansion, and `evaporation' may govern the evolution to the black widow stage and to the final disruption of the companion.