CONSTRAINING GAMMA-RAY BURST INITIAL LORENTZ FACTOR WITH THE AFTERGLOW ONSET FEATURE AND DISCOVERY OF A TIGHT {Gamma}{sub 0}-E{sub {gamma},iso} CORRELATION
- Department of Physics, Guangxi University, Nanning 530004 (China)
- GXU-NAOC Center for Astrophysics and Space Sciences, Nanning, Guangxi 530004 (China)
The onset of gamma-ray burst (GRB) afterglow is characterized by a smooth bump in the early afterglow light curve as the GRB fireball is decelerated by the circumburst medium. We extensively search for GRBs with such an onset feature in their optical and X-ray light curves from the literature and from the catalog established with the Swift/XRT. Twenty optically selected GRBs and 12 X-ray-selected GRBs are obtained, among which 17 optically selected and 2 X-ray-selected GRBs have redshift measurements. We fit these light curves with a smooth broken power law and measure the width (w), rising timescale (t{sub r}), and decaying timescale (t{sub d}) at full width at half-maximum. Strong mutual correlations among these timescales and with the peak time (t{sub p}) are found. The ratio t{sub r}/t{sub d} is almost universal among bursts, but the ratio t{sub r}/t{sub p} varies from 0.3 to {approx}1. The optical peak luminosity in the R band (L{sub R,p}) is anti-correlated with t{sub p} and w in the burst frame, indicating a dimmer and broader bump peaking at a later time. The isotropic prompt gamma-ray energy (E{sub {gamma},iso}) is also tightly correlated with L{sub R,p} and t{sub p} in the burst frame. Assuming that the bumps signal the deceleration of the GRB fireballs in a constant density medium, we calculate the initial Lorentz factor ({Gamma}{sub 0}) and the deceleration radius (R{sub d}) of the GRBs with redshift measurements. The derived {Gamma}{sub 0} is typically a few hundreds, and the deceleration radius is R{sub dec} {approx} 2 x 10{sup 17} cm. More intriguingly, a tight correlation between {Gamma}{sub 0} and E{sub {gamma},iso} is found, namely {Gamma}{sub 0} {approx_equal} 182(E{sub {gamma},iso}/10{sup 52} erg){sup 0.25}. This correlation also applies to the small sample of GRBs which show the signature of the afterglow onset in their X-ray afterglow, and to two bursts (GRBs 990123 and 080319B) whose early optical emission is dominated by a reverse shock. The lower limits of {Gamma}{sub 0} derived from a sample of optical afterglow light curves showing a decaying feature from the beginning of the observation are also generally consistent with such a correlation. The tight lower limits of {Gamma}{sub 0} of GRBs 080916C and 090902B derived from the opacity constraints with Fermi/LAT observations are also consistent with the correlation at the 2{sigma} confidence level, but the short GRB 090510 is a clear outlier of this relation. This correlation may give insight to GRB physics and could serve as an indicator of {Gamma}{sub 0} for long GRBs without early afterglow detections. A comparison of the early X-ray and optical afterglow light curves shows that the early bright X-ray emission is usually dominated by a non-forward-shock component, but occasionally (for one case) the forward shock emission is observable, and an achromatic deceleration feature is observed. The superposition of the internal and external components in X-rays causes the diversity of the observed X-ray light curves.
- OSTI ID:
- 21476641
- Journal Information:
- Astrophysical Journal, Vol. 725, Issue 2; Other Information: DOI: 10.1088/0004-637X/725/2/2209; ISSN 0004-637X
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
COSMOLOGY AND ASTRONOMY
AFTERGLOW
COSMIC GAMMA BURSTS
COSMIC GAMMA SOURCES
GAMMA RADIATION
LUMINOSITY
PHOTON EMISSION
RED SHIFT
X RADIATION
COSMIC RADIATION
COSMIC RAY SOURCES
ELECTROMAGNETIC RADIATION
EMISSION
IONIZING RADIATIONS
OPTICAL PROPERTIES
PHYSICAL PROPERTIES
PRIMARY COSMIC RADIATION
RADIATIONS