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The Galactic Origin of GRB221009A: Evidence Against a Cosmological Source


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GRB221009A, despite being initially classified as a cosmological gamma-ray burst, exhibits several characteristics inconsistent with this origin, suggesting it is instead a giant SGR (soft gamma repeater) located within the Milky Way galaxy.
บทคัดย่อ

This research paper investigates the origin of the exceptionally bright gamma-ray burst, GRB221009A. While initially attributed to a cosmological event, the authors present evidence challenging this interpretation and propose a galactic origin instead.

Bibliographic Information: Navia, C. N., de Oliveira, M. N., Felicio, B. O., & Nepomuseno, A. A. (2024). On the origin of the gamma-ray burst GRB221009A. arXiv preprint arXiv:2410.18131.

Research Objective: To determine the true origin of GRB221009A by analyzing its characteristics and comparing them with known properties of cosmological GRBs and galactic SGRs.

Methodology: The authors analyze data from various sources, including the Fermi Gamma-ray Space Telescope and the NASA/IPAC Extragalactic Database (NED), to examine GRB221009A's energy fluence, angular separation from a potential supernova (SN 2022xiw), gamma-ray emissions beyond TeV energies, and its location relative to the galactic plane and known SGRs.

Key Findings: The analysis reveals several inconsistencies with a cosmological origin for GRB221009A:

  • The angular separation between GRB221009A and SN 2022xiw suggests they are not directly connected.
  • The detection of high-energy gamma rays above 10 TeV is unlikely from a source at the proposed redshift of z=0.151 due to intergalactic absorption.
  • GRB221009A lies within a region of the Milky Way with a high concentration of SGRs.
  • The calculated isotropic energy release (Eiso) for GRB221009A, assuming a galactic origin, aligns with values observed for giant SGRs.

Main Conclusions: The authors conclude that GRB221009A is more likely a giant SGR originating within the Milky Way, possibly in the Perseus or Outer galactic arm, rather than a cosmological GRB. This conclusion is based on the inconsistencies with a cosmological origin and the alignment of its characteristics with known SGR properties.

Significance: This research challenges the initial classification of GRB221009A and highlights the importance of carefully considering alternative explanations for seemingly cosmological events. It also emphasizes the need for further investigation into the nature and behavior of giant SGRs.

Limitations and Future Research: The study acknowledges the limitations of relying on observational data and suggests further research using advanced modeling and simulations to confirm the proposed galactic origin of GRB221009A. Additionally, investigating other potential SGR candidates within the identified region of the Milky Way could provide further insights into the nature of these powerful events.

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สถิติ
The angular separation between GRB221009A and SN 2022xiw is approximately 0.073 arcmin (2.235 × 10−5 rad). The redshift of SN 2022xiw is z=0.151, corresponding to a distance of roughly 647 Mpc. The calculated linear distance between GRB221009A and SN 2022xiw, assuming they are both at z=0.151, is approximately 0.014 Mpc, which is close to the Milky Way's diameter. LHAASO detected over 140 gamma rays with energies up to 18 TeV from GRB221009A. The galactic coordinates of GRB221009A are longitude (l)=52.958 degrees and latitude (b)=4.32 degrees. The analysis of Fermi GRM triggers from 2017 to 2023 reveals an excess of 356 triggers within a 42.3 square degree area around the Vulpecula constellation. Of these excess triggers, 330 are SGRs, 17 are GRBs (including GRB221009A), and 9 are other types. The isotropic energy release (Eiso) of GRB221009A, assuming a cosmological origin at z=0.151, is estimated to be around 1.0×10^55 erg. Assuming a galactic origin at a distance of 0.008 Mpc (the Milky Way's radius), the Eiso of GRB221009A is calculated to be approximately 1.1 × 10^44 erg.
คำพูด
"GRB221009A is the burst with the highest energy fluence ever observed, and together the enormous release of energy Eiso ∼10^55 erg considering the GRB at z=0.151, put GRB221009A out of scale when compared to other long-lasting GRBs." "The fact that two objects, the supernova SN 2022xiw (at z=0.151) and the star (or brown dwarf), WISEA J191303.16+194622.6 (in the galaxy) have angular separations close to GRB221009A (see TABLE 1) indicates that it is more likely that SN 2022xiw has no connection to GRB221009A." "We want to highlight that the extraordinary and rare burst GRB221009A, is within a very active area of magnetars, triggering SGRs, and suggests a giant SGR, as the origin of GRB221009A."

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by Carlos Navia... ที่ arxiv.org 10-25-2024

https://arxiv.org/pdf/2410.18131.pdf
On the origin of the gamma-ray burst GRB221009A

สอบถามเพิ่มเติม

How might future advancements in gamma-ray astronomy technology further refine our understanding of the origins of events like GRB221009A and the characteristics of SGRs?

Future advancements in gamma-ray astronomy technology hold immense potential to revolutionize our understanding of GRBs like GRB221009A and SGRs. Here are some key areas where technological advancements can make a significant impact: Increased Sensitivity and Energy Range: Next-generation gamma-ray telescopes with enhanced sensitivity and broader energy coverage, extending into the very-high-energy (VHE) gamma-ray regime, will be crucial. These advancements will enable the detection of fainter and more distant GRBs, providing a more comprehensive view of their distribution and characteristics. Additionally, observing GRBs across a wider energy range can reveal crucial details about the emission mechanisms at play, helping to differentiate between various theoretical models. Improved Temporal Resolution: Studying the rapid variability observed in GRBs and SGRs requires instruments with exceptional temporal resolution. Future telescopes capable of capturing events on even shorter timescales could provide unprecedented insights into the dynamics of these extreme objects. This could involve advancements in detector technology, faster data readout systems, and sophisticated data analysis techniques. Multi-messenger Astronomy: Combining gamma-ray observations with other messengers, such as neutrinos, cosmic rays, and gravitational waves, offers a powerful approach to unraveling the mysteries of GRBs and SGRs. Future advancements in multi-messenger astronomy, including the development of more sophisticated detectors and improved coordination between observatories, will be essential for detecting these elusive signals and correlating them with gamma-ray bursts. Larger Field of View: Expanding the field of view of gamma-ray telescopes will significantly increase the chances of capturing rare and unexpected events like GRB221009A. This could involve innovative telescope designs, such as wide-field gamma-ray monitors, or constellations of smaller telescopes working in unison. Advanced Data Analysis and Modeling: The vast amounts of data generated by future gamma-ray observatories will necessitate sophisticated data analysis techniques and theoretical models. Machine learning algorithms and other advanced computational tools will play a crucial role in identifying patterns, extracting meaningful information, and testing theoretical predictions against observations. By pursuing these technological advancements, astronomers can hope to address fundamental questions about the origins of GRBs, the nature of SGRs, and the extreme environments in which these events occur.

Could there be a yet-undiscovered mechanism related to cosmological GRBs that might explain the observations of GRB221009A without requiring a galactic origin?

While the paper presents compelling arguments for a galactic origin of GRB221009A, the possibility of a yet-undiscovered cosmological mechanism cannot be entirely ruled out. Here are a few speculative ideas that could potentially bridge the gap between observations and a cosmological origin: Exotic EBL Variations: The paper relies on standard models of the extragalactic background light (EBL) to argue against the detection of high-energy gamma rays from a cosmological GRB. However, it's conceivable that our understanding of the EBL is incomplete. Perhaps there are unforeseen variations or structures in the EBL that could create "transparency windows," allowing high-energy gamma rays from distant sources to arrive at Earth relatively unattenuated. Unconventional Jet Structures: The standard model of GRB jets assumes a relatively simple geometry. However, more complex jet structures, such as jets with multiple components or time-varying properties, could potentially explain the unusual characteristics of GRB221009A. For example, a highly collimated, ultra-energetic jet core embedded within a wider, less energetic outflow could explain both the extreme brightness and the detection of high-energy gamma rays. New Physics in GRB Central Engines: Our current understanding of the physical processes powering GRB central engines is still evolving. It's conceivable that new physics, beyond the standard model of particle physics, could play a role in these extreme environments. Such new physics could potentially lead to the production of ultra-high-energy cosmic rays or other exotic particles that could contribute to the observed gamma-ray emission from GRB221009A. It's important to emphasize that these are highly speculative ideas, and further observations and theoretical modeling are needed to explore their viability.

If GRB221009A indeed originated within our galaxy, what are the implications for our understanding of the potential impact of giant SGRs on the Milky Way and its inhabitants?

If GRB221009A is confirmed as a giant SGR within our galaxy, it has significant implications for our understanding of these powerful events and their potential impact on the Milky Way: Reconsidering SGR Energy Scales: The extraordinary energy output of GRB221009A, even if scaled down for a galactic origin, challenges our current understanding of SGR energy budgets. It suggests that magnetars, the likely sources of SGRs, can release far more energy in a single burst than previously thought possible. This could necessitate revisiting theoretical models of magnetar formation, evolution, and energy release mechanisms. Increased Risk Assessment: The proximity of a giant SGR like GRB221009A raises concerns about the potential risks posed by these events. While the probability of a direct hit on Earth remains low, the intense radiation from a nearby giant SGR burst could have devastating consequences for our planet's atmosphere, climate, and technological infrastructure. A galactic origin for GRB221009A underscores the importance of identifying and monitoring potentially hazardous SGRs within the Milky Way. Impact on Astrobiology: The intense radiation from giant SGR bursts could have profound implications for the habitability of planets within their vicinity. While a single burst might not sterilize an entire planet, repeated exposure to such events could significantly impact the evolution of life. Understanding the frequency and distribution of giant SGR bursts within the Milky Way is crucial for assessing the long-term habitability of our galaxy. New Insights into Galactic Magnetism: The detection of a giant SGR within our galaxy provides a unique opportunity to study the properties of extremely strong magnetic fields. By analyzing the polarization of the emitted radiation, astronomers can gain insights into the structure and strength of the magnetar's magnetic field, shedding light on the fundamental physics of these extreme objects. Confirming a galactic origin for GRB221009A would be a major discovery, prompting a reassessment of our understanding of SGRs, their potential impact on the Milky Way, and the broader implications for astrobiology and fundamental physics.
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