伽马射线暴后快速射电暴发射的制约因素

B. Patricelli, M. Bernardini, M. Ferro
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摘要

快速射电暴(FRBs)是一种持续时间约为几毫秒的高能瞬变射电现象。它们的物理起源仍是未知的。许多模型都认为磁星可能是快速射电暴的来源,而观测到的快速射电暴与银河系磁星 SGR 1935+2154 的联系也证明了这一点。磁星也被认为是一部分伽马射线暴(GRBs)的能量来源,这意味着这两种极端现象可能有共同的起源。我们对这一假设进行了限制,利用现有的星表搜索伽马射线暴和 FRB 之间可能存在的联系,并估计是否可以根据缺乏重合探测来排除这种联系。我们将迄今为止探测到的所有 Neil Gehrels Swift 天文台(Swift)GRB 与 FRBSTATS 目录中报告的所有定位良好的 FRB 进行了交叉匹配,并在考虑空间和时间限制的情况下寻找 FRB-GRB 关联。我们还模拟了一个与 Swift GRB 相关的 FRB 合成群,以估计利用当前和未来的射电设施进行联合探测的可能性有多大。我们从星表的比对中恢复了两个低意义的可能关联:GRB 110715A/FRB 20171209A 和 GRB 060502B/FRB 20190309A。然而,我们的研究表明,基于迄今为止 Swift GRB 和 FRB 之间还没有任何明确的联系,我们不能排除这两个族群之间由于当前 GRB 和 FRB 探测器的特性而存在联系。目前可用的观测数据还不足以明确排除或确认 GRB 和 FRB 是否存在物理联系。在未来的十年中,如果有新一代的 GRB 和 FRB 探测器的话,探测到 GRB-FRB 联合事件的概率将会更高:因此,未来的观测将是对 FRB 和 GRB 具有共同祖先这一假说施加更严格限制的关键。
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Constraints on fast radio burst emission in the aftermath of gamma-ray bursts
Fast radio bursts (FRBs) are highly energetic radio transients with a duration of some milliseconds. Their physical origin is still unknown. Many models consider magnetars as possible FRB sources, which is supported by the observational association of FRBs with the galactic magnetar SGR 1935+2154. Magnetars are also thought to be the source of the power of a fraction of gamma-ray bursts (GRBs), which means that the two extreme phenomena might have a common progenitor. We placed constrains on this hypothesis by searching for possible associations between GRBs and FRBs with currently available catalogues and by estimating whether an association can be ruled out based on the lack of a coincident detection. We cross-matched all the Neil Gehrels Swift Observatory (Swift) GRBs detected so far with all the well-localised FRBs reported in the FRBSTATS catalogue, and we looked for FRB-GRB associations considering both spatial and temporal constraints. We also simulated a synthetic population of FRBs associated with Swift GRBs to estimate how likely a joint detection with current and future radio facilities is. We recovered two low-significance possible associations that were reported before from a match of the catalogues: GRB 110715A/FRB 20171209A and GRB 060502B/FRB 20190309A. However, our study shows that based on the absence of any unambiguous association so far between Swift GRBs and FRBs, we cannot exclude that the two populations are connected because of the characteristics of current GRB and FRB detectors. Currently available observational data are not sufficient to clearly exclude or confirm whether GRBs and FRBs are physically associated. In the next decade, the probability of detecting joint GRB-FRB events will be higher with new generations of GRB and FRB detectors, if any: future observations will therefore be key to placing more stringent constraints on the hypothesis that FRBs and GRBs have common progenitors.
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