Spin, inclination, and magnetic field evolution of magnetar population in vacuum and plasma-filled magnetospheres

TL;DR

This study investigates the evolution of magnetars, focusing on their spin, inclination, and magnetic field decay in different magnetospheric environments, revealing subclass-specific evolutionary behaviors through Monte Carlo simulations.

Contribution

It introduces a detailed simulation-based analysis of magnetar evolution, highlighting the roles of spin, magnetic field, and inclination, and distinguishes different evolutionary channels for subclasses.

Findings

Magnetar periods show a bimodal distribution, defining two subclasses.

Evolution depends on spin and magnetic field, but not significantly on inclination or environment for one subclass.

Different subclasses may follow distinct evolutionary pathways.

Abstract

Magnetars are potential energy sources or central engines for numerous transient phenomena in the Universe. How newborn magnetars evolve in different environments remains an open question. Based on both observed and candidate magnetars, it is found that the periods of all magnetars or candidates appear as a bimodal distribution, and are defined as the ``long-P'' and ``short-P'' magnetar subclasses, respectively. We find that for the ``short-P'' subclass of magnetars, the $\dot{P}$ values also appear as a bimodal distribution, and therefore can be classified as ``high-$\dot{P}$ short-P'' and ``low-$\dot{P}$ short-P'' magnetar subclasses. In this paper, we use Monte Carlo simulations to generate synthetic magnetar populations and investigate the evolution of the ``high-$\dot{P}$ short-P'' and ``low-$\dot{P}$ short-P'' magnetar subclasses by considering both the magnetar spin and inclination, as well as the decay of their magnetic field within their evolution in both vacuum and plasma-filled magnetospheres. We find that the magnetar evolution is dependent on both spin and magnetic field, but seems to be insensitive to inclination evolution and magnetospheric environment for the ``high-$\dot{P}$ short-P'' sub-class. In comparison for the case of ``high-$\dot{P}$ short-P'', the magnetar evolution is dependent on spin, magnetic field, and inclination evolution, as well as the magnetospheric environment. The best evolution model should be the case of inclination evolution in vacuum with a small value of $\overline{\mathrm{FOM}}$. The differences in the best-fit parameters also suggest that the ``high-$\dot{P}$ short-P'' and ``low-$\dot{P}$ short-P'' magnetar subclasses may be tracking with different evolution channels.