Identifying birth places of young isolated neutron stars

TL;DR

This study traces back the origins of four young isolated neutron stars to their potential birth associations using proper motion data, Monte Carlo simulations, and kinematic analysis, providing insights into their ages and progenitors.

Contribution

It introduces a method combining proper motion data and statistical simulations to identify neutron star birthplaces and estimate progenitor masses.

Findings

RX J1856.5-3754 likely from Upper Scorpius about 0.3 Myr ago

RX 0720.4-3125 possibly from TWA or Tr 10 around 0.4-0.5 Myr ago

RBS 1223 may originate from Sco-Cen or Corona-Australis, or Sct OB2

Abstract

Young isolated radio-quiet neutron stars are still hot enough to be detectable at X-ray and optical wavelengths due to their thermal emission and can hence probe cooling curves. An identification of their birth sites can constrain their age. For that reason we try to identify the parent associations for four of the so-called Magnificent Seven neutron stars for which proper motion and distance estimates are available. We are tracing back in time each neutron star and possible birth association centre to find close encounters. The associated time of the encounter expresses the kinematic age of the neutron star which can be compared to its characteristic spin-down age. Owing to observational uncertainties in the input data, we use Monte-Carlo simulations and evaluate the outcome of our calculations statistically. RX J1856.5-3754 most probably originated from the Upper Scorpius association about 0.3 Myr ago. RX 0720.4-3125 was either born in the young local association TWA about 0.4 Myr ago or in Tr 10 0.5 Myr in the past. Also RX J1605.3+3249 and RBS 1223 seem to come from a nearby young association such as the Sco-Cen complex or the extended Corona-Australis association. For RBS 1223 also a birth in Sct OB2 is possible. We also give constraints on the observables as well as on the radial velocity of the neutron star. Given the birth association, its age and the flight time of the neutron star, we estimate the mass of the progenitor star. Some of the potential supernovae were located very nearby (<100pc) and thus should have contributed to the 10Be and 60Fe material found in the Earth's crust. In addition we reinvestigate the previously suggested neutron star/ runaway pair PSR B1929+10/ zeta Ophiuchi and conclude that it is very likely that both objects were ejected during the same supernova event.