Global characteristics of GRBs observed with INTEGRAL and the inferred large population of low-luminosity GRBs

TL;DR

This paper analyzes the properties of GRBs observed with INTEGRAL, revealing a large population of low-luminosity, long-lag GRBs that are associated with local large-scale structures and potentially different progenitors.

Contribution

It provides the first comprehensive spectral and spatial analysis of INTEGRAL-detected GRBs, identifying a significant population of low-luminosity, long-lag GRBs linked to the local universe.

Findings

INTEGRAL detects more weak GRBs than Swift due to higher sensitivity.

Long-lag GRBs are mostly low-redshift and associated with the supergalactic plane.

Low-luminosity GRBs constitute about 25% of Type Ib/c supernovae rate.

Abstract

INTEGRAL has two sensitive gamma-ray instruments that have detected 46 gamma-ray bursts (GRBs) up to July 2007. We present the spectral, spatial, and temporal properties of the bursts in the INTEGRAL GRB catalogue using data from the imager, IBIS, and spectrometer, SPI. Spectral properties of the GRBs are determined using power-law, Band model and quasithermal model fits to the prompt emission. Spectral lags, i.e. the time delay in the arrival of low-energy gamma-rays with respect to high-energy gamma-rays, are measured for 31 of the GRBs. The photon index distribution of power-law fits to the prompt emission spectra is consistent with that obtained by Swift. The peak flux distribution shows that INTEGRAL detects proportionally more weak GRBs than Swift because of its higher sensitivity in a smaller field of view. The all-sky rate of GRBs above ~0.15 ph cm^-2 s^-1 is ~1400 yr^-1 in the fully coded field of view of IBIS. Two groups are identified in the spectral lag distribution, one with short lags <0.75 s (between 25-50 keV and 50-300 keV) and one with long lags >0.75 s. Most of the long-lag GRBs are inferred to have low redshifts because of their long spectral lags, their tendency to have low peak energies and their faint optical and X-ray afterglows. They are mainly observed in the direction of the supergalactic plane with a quadrupole moment of Q=-0.225+/-0.090 and hence reflect the local large-scale structure of the Universe. The rate of long-lag GRBs with inferred low luminosity is ~25% of Type Ib/c supernovae. Some of these bursts could be produced by the collapse of a massive star without a supernova or by a different progenitor, such as the merger of two white dwarfs or a white dwarf with a neutron star or black hole, possibly in the cluster environment without a host galaxy.