The NICER View of the 2020 Burst Storm and Persistent Emission of SGR 1935+2154

George Younes, Tolga Guver, Chryssa Kouveliotou, Matthew G. Baring, Zorawar Wadiasingh, Beste Begicarslan, Teruaki Enoto, Ersin Gogus, Lin Lin, Alice K. Harding, Alexander J. van der Horst, Walid A. Majid, Sebastien Guillot

Published 2020-09-16Version 1

We report NICER observations of the most intense bursting period yet from the magnetar SGR 1935+2154, focusing on 2020 April 28 from 00:40:58 to 16:21:19 UTC, an interval that ends <2 hours after the fast radio burst (FRB) associated with the source. During the first 1120 seconds we detect over 217 bursts, corresponding to a burst rate of >0.2 bursts/s. Three hours later the rate is at 0.008 bursts/s, remaining at a comparatively low level thereafter. The $T_{90}$ duration distribution of the bursts peaks at 840 ms; the distribution of waiting times to the next burst is fit with a log-normal with an average of 2.1 s. The 1-10 keV spectra of the bursts are well fit by a single blackbody, with an average temperature and area of kT=1.7 keV and $R^2=53$ km$^2$. The differential burst fluence distribution over ~3 orders of magnitude is well modeled with a power-law form $dN/dF\propto F^{-1.5\pm0.1}$. Our timing analysis of the source persistent emission, after the initial burst storm, retrieves the magnetar spin period and derives a double-peaked pulse profile. There is no discernible correlation of the 217 burst peak times with pulse phase. However, we find that the arrival time of the FRB aligns in phase with the brightest peak of the pulse profile. Finally, we present the persistent emission spectral evolution up to 2020 July 26; its flux and blackbody temperature decrease rapidly in the early stages of the outburst, reaching quiescence 40 days later, while the size of the emitting area remains unchanged.