Multi-messenger astronomy with INTEGRAL

IF 11.7 2区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS New Astronomy Reviews Pub Date : 2021-06-01 DOI:10.1016/j.newar.2020.101595
Carlo Ferrigno , Volodymyr Savchenko , Alexis Coleiro , Francesca Panessa , Angela Bazzano , Enrico Bozzo , Jérôme Chenevez , Albert Domingo , Maeve Doyle , Andrea Goldwurm , Diego Götz , Elisabeth Jourdain , Andreas von Kienlin , Erik Kuulkers , Sandro Mereghetti , Antonio Martin-Carrillo , Lorenzo Natalucci , Francesca Onori , James Rodi , Jean-Pierre Roques , Pietro Ubertini
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引用次数: 3

Abstract

At the time of defining the science objectives of the INTernational Gamma-Ray Astrophysics Laboratory (INTEGRAL), such a rapid and spectacular development of multi-messenger astronomy could not have been predicted, with new impulsive phenomena becoming accessible through different channels. Neutrino telescopes have routinely detected energetic neutrino events coming from unknown cosmic sources since 2013. Gravitational wave detectors opened a novel window on the sky in 2015 with the detection of the merging of two black holes and in 2017 with the merging of two neutron stars, followed by signals in the full electromagnetic range. Finally, since 2007, radio telescopes detected extremely intense and short burst of radio waves, known as Fast Radio Bursts (FRBs) whose origin is for most cases extragalactic, but enigmatic. The exceptionally robust and versatile design of the INTEGRAL mission has allowed researchers to exploit data collected not only with the pointed instruments, but also with the active cosmic-ray shields of the main instruments to detect impulses of gamma-rays in coincidence with unpredictable phenomena. The full-sky coverage, mostly unocculted by the Earth, the large effective area, the stable background, and the high duty cycle (85%) put INTEGRAL in a privileged position to give a major contribution to multi-messenger astronomy. In this review, we describe how INTEGRAL has provided upper limits on the gamma-ray emission from black-hole binary mergers, detected a short gamma-ray burst in coincidence with a binary neutron star merger, contributed to define the spectral energy distribution of a blazar associated with a neutrino event, set upper limits on impulsive and steady gamma-ray emission from cosmological FRBs, and detected a magnetar flare associated with fast radio bursting emission.

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多信使天文学与积分
在确定国际伽玛射线天体物理实验室(INTEGRAL)的科学目标时,由于新的脉冲现象可以通过不同的渠道获得,多信使天文学的如此迅速和壮观的发展是无法预测的。自2013年以来,中微子望远镜经常探测到来自未知宇宙源的高能中微子事件。引力波探测器在2015年探测到两个黑洞的合并,在2017年探测到两颗中子星的合并,随后在全电磁范围内发出信号,为天空打开了一扇新的窗口。最后,自2007年以来,射电望远镜探测到极其强烈和短暂的无线电波爆发,被称为快速射电暴(frb),其起源在大多数情况下是银河系外的,但却很神秘。INTEGRAL任务的异常坚固和多功能设计使研究人员不仅可以利用尖锐仪器收集的数据,还可以利用主仪器的主动宇宙射线屏蔽来探测与不可预测现象相一致的伽马射线脉冲。全天空覆盖,大部分不被地球覆盖,大的有效面积,稳定的背景和高占空比(85%)使INTEGRAL处于有利地位,为多信使天文学做出了重大贡献。在这篇综述中,我们描述了INTEGRAL如何提供了黑洞双星合并的伽马射线发射上限,探测到与双中子星合并同时发生的短伽马射线暴,帮助定义了与中微子事件相关的blazar的光谱能量分布,为宇宙快速射电暴的脉冲和稳定伽马射线发射设定了上限,并探测到与快速射电暴发射相关的磁星耀斑。
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来源期刊
New Astronomy Reviews
New Astronomy Reviews 地学天文-天文与天体物理
CiteScore
18.60
自引率
1.70%
发文量
7
审稿时长
11.3 weeks
期刊介绍: New Astronomy Reviews publishes review articles in all fields of astronomy and astrophysics: theoretical, observational and instrumental. This international review journal is written for a broad audience of professional astronomers and astrophysicists. The journal covers solar physics, planetary systems, stellar, galactic and extra-galactic astronomy and astrophysics, as well as cosmology. New Astronomy Reviews is also open for proposals covering interdisciplinary and emerging topics such as astrobiology, astroparticle physics, and astrochemistry.
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