Relativistic dust grains: a new subject of research with orbital fluorescence detectors

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021) Pub Date : 2021-08-16 DOI:10.22323/1.395.0315

P. Klimov, B. Khrenov, N. Kalmykov, S. Sharakin, M. Zotov

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引用次数: 2

Abstract

TUS (Tracking Ultraviolet Set-up) was the world’s first orbital detector aimed at testing the principle of observing ultra-high energy cosmic rays (UHECRs) with a space-based fluorescence telescope. TUS was launched into orbit on 28th April 2016 as a part of the scientific payload of the Lomonosov satellite, and itsmission continued for 1.5 years. During this time, its exposure reached ∼ 1550 km2 sr yr for primary energy & 400 EeV, and a number of extensive air showers-like events were registered. The shape and kinematics of the signal in these events closely resembled those expected fromUHECRs but amplitudes of the signal and some other features were in contradiction with this assumption. A detailed analysis of one of EAS-like events (TUS161003) revealed that a primary cosmic ray would need to have an energy & 1 ZeV in order to produce a light curve of the observed amplitude, which is incompatible with the cosmic ray spectrum obtained with ground-based experiments. More than this, the slant depth of the shower maximum be the signal produced by a cosmic particle, was estimated as . 500 g/cm2, which corresponds to cosmic rays around 1 PeV. We present a preliminary discussion of a hypothesis that the TUS161003 event and perhaps some other bright EAS-like events could be produced by relativistic dust grains, which were considered a possible component of the cosmic ray flux beyond the GZK cut-off some time ago.

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相对论尘埃颗粒:轨道荧光探测器研究的新课题

TUS(跟踪紫外线装置)是世界上第一个轨道探测器，旨在测试用天基荧光望远镜观测超高能量宇宙射线(uhecr)的原理。作为罗蒙诺索夫卫星科学有效载荷的一部分，TUS于2016年4月28日发射进入轨道，其任务持续了一年半。在此期间，一次能源和400 EeV的暴露量达到每年约1550平方公里，并且记录了许多广泛的类似空气阵雨的事件。在这些事件中，信号的形状和运动学与muhecr的预期非常相似，但信号的振幅和其他一些特征与这一假设相矛盾。对一个类似easa的事件(TUS161003)的详细分析表明，为了产生观测振幅的光曲线，初级宇宙射线的能量需要为1 ZeV，这与地面实验获得的宇宙射线光谱不相容。不仅如此，据估计，流星雨的倾斜深度最大是由宇宙粒子产生的信号。500克/平方厘米，相当于1 PeV左右的宇宙射线。我们提出了一个假设的初步讨论，即TUS161003事件和其他一些明亮的ea事件可能是由相对论性尘埃颗粒产生的，这些尘埃颗粒被认为是一段时间前超越GZK截止点的宇宙射线通量的可能组成部分。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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