Detectability of GRB Iron Lines by Swift, Chandra and XMM

Abstract

The rapid acquisition of positions by the upcoming Swift satellite will allow the monitoring for X-ray lines in GRB afterglows at much earlier epochs than was previously feasible. We calculate the possible significance levels of iron line detections as a function of source redshift and observing time after the trigger, for the Swift XRT, Chandra ACIS and XMM Epic detectors. For standard burst luminosities and decay rates and equivalent widths of 1 keV as previously reported, depending on the source-frame epoch at which the lines appear, Swift may be able to detect lines up to z ~ 1.5 with a significance of better than 3 sigma for times of up to 10^4 s. The same lines would be detectable with no less than 4 sigma significance at z up to 6 by Chandra, and to 8 by XMM, for times of up to 10^5 s. For afterglows in the upper range of initial X-ray luminosites afterglows, which may also be typical of pop. III bursts, similar significance levels are obtained out to substantially higher redshifts. A distinction between broad and narrow lines to better than 3 sigma is possible with Chandra and XMM out to z~2 and ~6.5, respectively, while Swift can do so up to z~1, for standard burst parameters. A distinction between different energy centroid lines of 6.4 keV vs. 6.7 KeV (or 6.7 keV vs. Cobalt 7.2 keV) is possible up to z~0.6, ~1.2, and ~2 (z~ 1, 5, 7.5), with Swift, Chandra, and XMM respectively. For the higher luminosity bursts, Swift is able to distinguish at the 5 sigma level between a broad and a narrow line and between a 6.7 keV vs. a 7.2 keV line center both out to z~5 for times of less than 10^4 s.