Solar flare observations with the Radio Neutrino Observatory Greenland (RNO-G)

IF 4.2 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Astroparticle Physics Pub Date : 2024-08-03 DOI:10.1016/j.astropartphys.2024.103024

S. Agarwal , J.A. Aguilar , S. Ali , P. Allison , M. Betts , D. Besson , A. Bishop , O. Botner , S. Bouma , S. Buitink , M. Cataldo , B.A. Clark , A. Coleman , K. Couberly , S. de Kockere , K.D. de Vries , C. Deaconu , M.A. DuVernois , C. Glaser , T. Glüsenkamp , A. Zink

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引用次数: 0

Abstract

The Radio Neutrino Observatory – Greenland (RNO-G) seeks discovery of ultra-high energy neutrinos from the cosmos through their interactions in ice. The science program extends beyond particle astrophysics to include radioglaciology and, as we show herein, solar observations, as well. Currently seven of 35 planned radio-receiver stations (24 antennas/station) are operational. These stations are sensitive to impulsive radio signals with frequencies between 80 and 700 MHz and feature a neutrino trigger threshold for recording data close to the thermal floor. RNO-G can also trigger on elevated signals from the Sun, resulting in nanosecond resolution time-domain flare data; such temporal resolution is significantly shorter than from most dedicated solar observatories. In addition to possible RNO-G solar flare polarization measurements, the Sun also represents an extremely useful above-surface calibration source.

Using RNO-G data recorded during the summers of 2022 and 2023, we find signal excesses during solar flares reported by the solar-observing Callisto network and also in coincidence with $\sim$ 2/3 of the brightest excesses recorded by the SWAVES satellite. These observed flares are characterized by significant time-domain impulsivity. Using the known position of the Sun, the flare sample is used to calibrate the RNO-G absolute pointing on the radio signal arrival direction to sub-degree resolution. We thus establish the Sun as a regularly observed astronomical calibration source to provide the accurate absolute pointing required for neutrino astronomy.

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利用格陵兰射电中微子观测台（RNO-G）观测太阳耀斑

格陵兰射电中微子天文台（RNO-G）试图通过中微子在冰中的相互作用发现宇宙中的超高能量中微子。该科学计划不仅包括粒子天体物理学，还包括辐射冰川学，以及我们在此展示的太阳观测。目前，计划中的 35 个无线电接收站（每个站 24 根天线）中的 7 个已经投入运行。这些接收站对频率在 80 到 700 兆赫之间的脉冲无线电信号非常敏感，并具有中微子触发阈值，可记录接近热底面的数据。RNO-G 还可以触发来自太阳的高频信号，从而获得纳秒级分辨率的时域耀斑数据；这种时间分辨率比大多数专用太阳观测站的数据要短得多。除了可能的 RNO-G 太阳耀斑偏振测量之外，太阳也是一个非常有用的地表以上校准源。

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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来源期刊

Astroparticle Physics 地学天文-天文与天体物理

CiteScore

8.00

自引率

2.90%

发文量

审稿时长

79 days

期刊介绍： Astroparticle Physics publishes experimental and theoretical research papers in the interacting fields of Cosmic Ray Physics, Astronomy and Astrophysics, Cosmology and Particle Physics focusing on new developments in the following areas: High-energy cosmic-ray physics and astrophysics; Particle cosmology; Particle astrophysics; Related astrophysics: supernova, AGN, cosmic abundances, dark matter etc.; Gravitational waves; High-energy, VHE and UHE gamma-ray astronomy; High- and low-energy neutrino astronomy; Instrumentation and detector developments related to the above-mentioned fields.