Study of solar activity with AERA at the Pierre Auger Observatory

TL;DR

This study analyzes 11 years of AERA data at the Pierre Auger Observatory to understand how solar activity impacts radio wave propagation, revealing correlations with solar radio bursts and effects on cosmic-ray detection.

Contribution

It provides the first long-term analysis linking solar activity, radio bursts, and AERA measurements, highlighting the impact on radio-based cosmic-ray detection.

Findings

Detected various solar radio bursts in AERA data.

Found correlation between MUF and broadband noise in 30-40 MHz.

Observed radio blackouts coinciding with NOAA reports.

Abstract

Solar activity events release vast amounts of energy, including radio waves, X-rays, ultraviolet radiation, and energetic particles, which interact with the ionosphere of the Earth and can disrupt radio wave propagation, affecting radio communications. They can either enhance reflections, improving long-distance terrestrial communications, or cause signal degradation and absorption, respectively, depending on whether the increased ionization affects the upper or lower layers of the ionosphere. In the first case, the solar cycle modulates the Maximum Usable Frequency (MUF), the highest frequency usable for radio communication between two Earth-based points. The Auger Engineering Radio Array (AERA) of the Pierre Auger Observatory was developed to measure the radio emission from extensive air showers in the $30-80$ MHz band. We examine the impact of solar activity on AERA data collected over approximately 11 years. We report the detection of different types of solar radio bursts and we investigate how increased solar radiation - particularly in the X-ray and extreme ultraviolet bands - also affects measurements in the AERA energy band. Our results show a remarkable correlation between the MUF and the broadband noise observed in the $30-40$ MHz frequency range. Radio blackouts are also observed in AERA spectrograms in coincidence with those reported by the National Oceanic and Atmospheric Administration (NOAA). Additionally, we performed a search for temporal coincidences between AERA data and independent observations of solar radio burst events from the e-CALLISTO network and the SWAVES instrument. These findings highlight the complex interplay between solar activity and radio wave propagation, which is also relevant for cosmic-ray detection.