The first outburst of the new magnetar candidate SGR 0501+4516

TL;DR

This paper documents the first observed outburst of the new magnetar candidate SGR 0501+4516, analyzing its X-ray and hard X-ray emission, spectral and timing evolution over 160 days, and comparing it to quiescent data.

Contribution

It provides the first detailed multi-instrument observational analysis of SGR 0501+4516's outburst, including flux decay, spectral changes, and timing behavior, revealing new insights into magnetar outburst dynamics.

Findings

Flux decayed exponentially with a 23.8-day timescale.

Detected a variable hard X-ray component fading in less than 10 days.

Observed a strong second derivative in the period, indicating complex timing behavior.

Abstract

We report here on the outburst onset and evolution of the new Soft Gamma Repeater SGR 0501+4516. We monitored the new SGR with XMM-Newton starting on 2008 August 23, one day after the source became burst-active, and continuing with 4 more observations, with the last one on 2008 September 30. Combining the data with the Swift-XRT and Suzaku data, we modelled the outburst decay over 160 days, and we found that the source flux decreased exponentially with a timescale of t_c=23.8 days. In the first XMM-Newton observation a large number of short X-ray bursts were observed, the rate of which decayed drastically in the following observations. We found large changes in the spectral and timing behavior of the source during the outburst, with softening emission as the flux decayed, and the non-thermal soft X-ray spectral component fading faster than the thermal one. Almost simultaneously to our XMM-Newton observations (on 2008 August 29 and September 2), we observed the source in the hard X-ray range with INTEGRAL, which clearly detected the source up to ~100keV in the first pointing, while giving only upper limits during the second pointing, discovering a variable hard X-ray component fading in less than 10 days after the bursting activation. We performed a phase-coherent X-ray timing analysis over about 160 days starting with the burst activation and found evidence of a strong second derivative period component (\ddot{P} = -1.6(4)x10^{-19} s/s^{-2}). Thanks to the phase-connection, we were able to study the the phase-resolved spectral evolution of SGR 0501+4516 in great detail. We also report on the ROSAT quiescent source data, taken back in 1992 when the source exhibits a flux ~80 times lower than that measured during the outburst, and a rather soft, thermal spectrum.