The X-ray outburst of the Galactic Centre magnetar SGR J1745-2900 during the first 1.5 year

TL;DR

This study presents a detailed long-term X-ray monitoring of the Galactic Centre magnetar SGR J1745-2900 over 1.5 years, revealing changes in its spin-down rate, spectral evolution, and insights into its outburst cooling mechanisms.

Contribution

It provides the first extensive dataset tracking the magnetar's outburst evolution, refining timing properties and challenging existing cooling models with new observational evidence.

Findings

Spin period derivative increased by a factor of ~5 over 1.5 years.

The magnetar exhibits a slow flux decay and inefficient surface cooling.

Additional heating from magnetic currents likely influences outburst evolution.

Abstract

In 2013 April a new magnetar, SGR 1745-2900, was discovered as it entered an outburst, at only 2.4 arcsec angular distance from the supermassive black hole at the Centre of the Milky Way, Sagittarius A*. SGR 1745-2900 has a surface dipolar magnetic field of ~ 2x10^{14} G, and it is the neutron star closest to a black hole ever observed. The new source was detected both in the radio and X-ray bands, with a peak X-ray luminosity L_X ~ 5x10^{35} erg s^{-1}. Here we report on the long-term Chandra (25 observations) and XMM-Newton (8 observations) X-ray monitoring campaign of SGR 1745-2900, from the onset of the outburst in April 2013 until September 2014. This unprecedented dataset allows us to refine the timing properties of the source, as well as to study the outburst spectral evolution as a function of time and rotational phase. Our timing analysis confirms the increase in the spin period derivative by a factor of ~2 around June 2013, and reveals that a further increase occurred between 2013 Oct 30 and 2014 Feb 21. We find that the period derivative changed from 6.6x10^{-12} s s^{-1} to 3.3x10^{-11} s s^{-1} in 1.5 yr. On the other hand, this magnetar shows a slow flux decay compared to other magnetars and a rather inefficient surface cooling. In particular, starquake-induced crustal cooling models alone have difficulty in explaining the high luminosity of the source for the first ~200 days of its outburst, and additional heating of the star surface from currents flowing in a twisted magnetic bundle is probably playing an important role in the outburst evolution.