Some theoretical implications of short-hard gamma-ray burst observations

Ehud Nakar

doi:10.1016/j.asr.2006.12.038

Some theoretical implications of short-hard gamma-ray burst observations

Ehud Nakar^*

^*Corresponding author for this work

California Institute of Technology

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Short-hard and long-soft gamma-ray bursts (GRBs) are two distinct phenomena, but their prompt and afterglow emission show many similarities. This suggests that two different progenitor systems lead to similar physical processes and that the prompt and afterglow observations of short-hard GRBs (SHBs) can be examined using models of long GRBs. Here, I discuss three conclusions that can be drawn from SHB observations. I show that the lower limit on the Lorentz factor of SHBs is typically "only" 10-50, significantly lower than that of long GRBs. SHBs with observed X-ray afterglow after 1 day are found to be roughly as efficient as long GRBs in converting the outflow energy into prompt gamma-rays. Finally, I examine the origin of SHBs with X-ray dark afterglows and find that the most plausible explanation is that these SHBs exploded in extremely low density environment (n ≲ 10 ^-5 cm ^-3 ).

Original language	English
Pages (from-to)	1224-1228
Number of pages	5
Journal	Advances in Space Research
Volume	40
Issue number	8
DOIs	https://doi.org/10.1016/j.asr.2006.12.038
State	Published - 2007
Externally published	Yes

Funding

Funders	Funder number
National Aeronautics and Space Administration	NNH05ZDA001N
Sherman Fairchild Foundation

Keywords

Bursts
Gamma rays

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10.1016/j.asr.2006.12.038

Cite this

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abstract = " Short-hard and long-soft gamma-ray bursts (GRBs) are two distinct phenomena, but their prompt and afterglow emission show many similarities. This suggests that two different progenitor systems lead to similar physical processes and that the prompt and afterglow observations of short-hard GRBs (SHBs) can be examined using models of long GRBs. Here, I discuss three conclusions that can be drawn from SHB observations. I show that the lower limit on the Lorentz factor of SHBs is typically {"}only{"} 10-50, significantly lower than that of long GRBs. SHBs with observed X-ray afterglow after 1 day are found to be roughly as efficient as long GRBs in converting the outflow energy into prompt gamma-rays. Finally, I examine the origin of SHBs with X-ray dark afterglows and find that the most plausible explanation is that these SHBs exploded in extremely low density environment (n ≲ 10 -5 cm -3 ).",

keywords = "Bursts, Gamma rays",

author = "Ehud Nakar",

note = "Funding Information: I am grateful to Avishay Gal-Yam for many helpful discussions and comments. This work was supported by a senior research fellowship from the Sherman Fairchild Foundation and by NASA NNH05ZDA001N grant. ",

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N1 - Funding Information: I am grateful to Avishay Gal-Yam for many helpful discussions and comments. This work was supported by a senior research fellowship from the Sherman Fairchild Foundation and by NASA NNH05ZDA001N grant.

PY - 2007

Y1 - 2007

N2 - Short-hard and long-soft gamma-ray bursts (GRBs) are two distinct phenomena, but their prompt and afterglow emission show many similarities. This suggests that two different progenitor systems lead to similar physical processes and that the prompt and afterglow observations of short-hard GRBs (SHBs) can be examined using models of long GRBs. Here, I discuss three conclusions that can be drawn from SHB observations. I show that the lower limit on the Lorentz factor of SHBs is typically "only" 10-50, significantly lower than that of long GRBs. SHBs with observed X-ray afterglow after 1 day are found to be roughly as efficient as long GRBs in converting the outflow energy into prompt gamma-rays. Finally, I examine the origin of SHBs with X-ray dark afterglows and find that the most plausible explanation is that these SHBs exploded in extremely low density environment (n ≲ 10 -5 cm -3 ).

AB - Short-hard and long-soft gamma-ray bursts (GRBs) are two distinct phenomena, but their prompt and afterglow emission show many similarities. This suggests that two different progenitor systems lead to similar physical processes and that the prompt and afterglow observations of short-hard GRBs (SHBs) can be examined using models of long GRBs. Here, I discuss three conclusions that can be drawn from SHB observations. I show that the lower limit on the Lorentz factor of SHBs is typically "only" 10-50, significantly lower than that of long GRBs. SHBs with observed X-ray afterglow after 1 day are found to be roughly as efficient as long GRBs in converting the outflow energy into prompt gamma-rays. Finally, I examine the origin of SHBs with X-ray dark afterglows and find that the most plausible explanation is that these SHBs exploded in extremely low density environment (n ≲ 10 -5 cm -3 ).

KW - Bursts

KW - Gamma rays

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Some theoretical implications of short-hard gamma-ray burst observations

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Keywords

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