Aaron C. Trigg, Rachel Stewart, Alex van Kooten, Eric Burns, Oliver J. Roberts, Dmitry D. Frederiks, George Younes, Dmitry S. Svinkin, Matthew G. Baring, Zorawar Wadiasingh, Peter Veres, Michael S. Briggs, Lorenzo Scotton, Adam Goldstein, Malte Busmann, Brendan O Connor, Lei Hu, Daniel Gruen, Arno Riffeser, Raphael Zoeller, Antonella Palmese, Daniela Huppenkothen, Chryssa Kouveliotou
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Gamma-ray analyses reveal significant insights\ninto this burst, supporting conclusions already established in the literature:\nour time-resolved spectral studies provide further evidence that GRB 231115A is\nindeed a MGF. Significance calculations also suggest a robust association with\nM82, further supported by a high Bayes factor that minimizes the probability of\nchance alignment with a neutron star merger. Despite extensive follow-up\nefforts, no contemporaneous gravitational wave or radio emissions were\ndetected. The lack of radio emission sets stringent upper limits on possible\nradio luminosity. Constraints from our analysis show no fast radio bursts\n(FRBs) associated with two MGFs. X-ray observations conducted post-burst by\nSwift/XRT and XMM/Newton provided additional data, though no persistent\ncounterparts were identified. Our study underscores the importance of\ncoordinated multi-wavelength follow-up and highlights the potential of MGFs to\nenhance our understanding of short GRBs and magnetar activities in the cosmos.\nCurrent MGF identification and follow-up implementation are insufficient for\ndetecting expected counterparts; however, improvements in these areas may allow\nfor the recovery of follow-up signals with existing instruments. Future\nadvancements in observational technologies and methodologies will be crucial in\nfurthering these studies.","PeriodicalId":501343,"journal":{"name":"arXiv - PHYS - High Energy Astrophysical Phenomena","volume":"71 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-09","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Extragalactic Magnetar Giant Flare GRB 231115A: Insights from Fermi/GBM Observations\",\"authors\":\"Aaron C. 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引用次数: 0
摘要
我们介绍了对 GRB 231115A 的探测和分析,这是一个由 Fermi/GBM 观测到的候选河外星系磁星巨耀斑(MGF),并由INTEGRAL 定位到星爆星系 M82。这个爆发表现出与已知巨型耀斑一致的独特时间和光谱特征,包括持续时间短和峰值能量高。伽马射线分析揭示了对这一爆发的重要见解,支持了文献中已有的结论:我们的时间分辨光谱研究提供了进一步的证据,证明 GRB 231115A 确实是一个 MGF。显著性计算还表明,它与M82有很强的关联,高贝叶斯因子进一步支持了这一结论,该因子最大限度地降低了与中子星合并的概率。尽管进行了广泛的跟踪研究,但没有发现同时代的引力波或射电发射。射电辐射的缺乏为可能的射电光度设定了严格的上限。根据我们的分析,没有发现与两个MGF相关的快速射电暴(FRBs)。Swift/XRT和XMM/Newton在爆发后进行的X射线观测提供了更多数据,但没有发现持续存在的对应天体。我们的研究强调了协调多波长跟踪的重要性,并突出了MGF在增强我们对宇宙中短GRB和磁星活动的了解方面的潜力。目前的MGF识别和跟踪实施不足以探测到预期的对应物;然而,这些领域的改进可能会使我们能够利用现有仪器恢复跟踪信号。未来在观测技术和方法上的进步对进一步开展这些研究至关重要。
Extragalactic Magnetar Giant Flare GRB 231115A: Insights from Fermi/GBM Observations
We present the detection and analysis of GRB 231115A, a candidate
extragalactic magnetar giant flare (MGF) observed by Fermi/GBM and localized by
INTEGRAL to the starburst galaxy M82. This burst exhibits distinctive temporal
and spectral characteristics that align with known MGFs, including a short
duration and a high peak energy. Gamma-ray analyses reveal significant insights
into this burst, supporting conclusions already established in the literature:
our time-resolved spectral studies provide further evidence that GRB 231115A is
indeed a MGF. Significance calculations also suggest a robust association with
M82, further supported by a high Bayes factor that minimizes the probability of
chance alignment with a neutron star merger. Despite extensive follow-up
efforts, no contemporaneous gravitational wave or radio emissions were
detected. The lack of radio emission sets stringent upper limits on possible
radio luminosity. Constraints from our analysis show no fast radio bursts
(FRBs) associated with two MGFs. X-ray observations conducted post-burst by
Swift/XRT and XMM/Newton provided additional data, though no persistent
counterparts were identified. Our study underscores the importance of
coordinated multi-wavelength follow-up and highlights the potential of MGFs to
enhance our understanding of short GRBs and magnetar activities in the cosmos.
Current MGF identification and follow-up implementation are insufficient for
detecting expected counterparts; however, improvements in these areas may allow
for the recovery of follow-up signals with existing instruments. Future
advancements in observational technologies and methodologies will be crucial in
furthering these studies.