AA
Advances in Astronomy
1687-7977
1687-7969
Hindawi
10.1155/2018/2730676
2730676
Editorial
Gamma-Ray Burst in the Swift/Fermi Era and Beyond
http://orcid.org/0000-0002-2636-6508
Zheng
WeiKang
1
http://orcid.org/0000-0001-6276-6616
Sakamoto
Takanori
2
Urata
Yuji
3
http://orcid.org/0000-0002-1474-1980
Pandey
Shashi B.
4
1
Department of Astronomy
University of California
Berkeley
CA 94720-3411
USA
berkeley.edu
2
Department of Physics and Mathematics
Aoyama Gakuin University
Sagamihara
Kanagawa 252-5258
Japan
aoyama.ac.jp
3
Institute of Astronomy
National Central University
Chung-Li 32054
Taiwan
ncu.edu.tw
4
Aryabhatta Research Institute of Observational Sciences
Manora Peak
Nainital 263002
India
aries.res.in
2018
122018
2018
20
12
2016
20
12
2016
122018
2018
Copyright © 2018 WeiKang Zheng et al.
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
The Swift and Fermi satellites have been observing gamma-ray bursts (GRBs), which are short-lived and intense flashes of gamma-rays associated with the death/explosion of massive stars and/or compact binary mergers, for nearly a decade in space since their launch in 2004 and 2008, respectively. Our understanding of GRB physics, though still far from complete, has been revolutionized thanks to their outstanding observations, as well as the ongoing ground follow-up observations. In addition to a previously published special issue, “Gamma-Ray Bursts in the Swift and Fermi Era,” which discussed GRB work related to the Swift and Fermi missions, here we continue collecting reviews and research articles on GRBs and their afterglows.
In total, five reviews and one research article are published in this special issue. The review article by M. Tanaka summarizes the current understanding of kilonovae/macronovae related to the GRBs. In comparison, Z. Cano et al. present an up-to-date review of progress on the connection between supernovae and long-duration GRBs. Next, the review article by M. Dainotti et al. discusses various GRB correlations during the prompt phase and their use as redshift estimators and possibly as cosmological tools. In contrast, the review by J. J. Geng and Y. F. Huang focuses on the GRB afterglow phase, discussing the diverse features of the multiwavelength afterglows of GRBs. One other article by M. Jelinek et al. presents a decade of optical follow-up observations of GRBs by the BOOTES telescope in Spain. Lastly, P. Chandra discusses GRBs from the radio perspective, which is very important for studies of GRBs related to their calorimetry, reverse-shock emission, and circumburst environments.
Overall, this volume extends the discussions of the previously published special issue, “Gamma-Ray Bursts in the Swift and Fermi Era,” and covers more topics about GRBs from gamma-ray to radio wavelengths. These are the most updated summaries of progress on GRB studies during the Swift and Fermi mission periods. We hope these two special issues provide useful information for GRB researchers, helping to lead to new results and progress even beyond the Swift and Fermi era.
Acknowledgments
We sincerely thank the authors and referees for all of their efforts.
WeiKang Zheng
Takanori Sakamoto
Yuji Urata
Shashi B. Pandey