par Schlüter, Felix 
;Huege, Tim
Référence (7 June 2022 through 10 June 2022: Santiago de Compostela), th International Workshop on Acoustic and Radio EeV Neutrino Detection Activities, ARENA 2022, Pos proceedings of science (424), 034
Publication Publié, 2023-03-01
;Huege, TimRéférence (7 June 2022 through 10 June 2022: Santiago de Compostela), th International Workshop on Acoustic and Radio EeV Neutrino Detection Activities, ARENA 2022, Pos proceedings of science (424), 034
Publication Publié, 2023-03-01
Publication dans des actes
| Résumé : | Inclined air showers open the window for the radio detection of ultra-high-energy cosmic rays with km-sparse radio-antenna arrays. The potential of those measurements would improve greatly with an accurate reconstruction of the depth of the shower maximum Xmax. However, traditional methods using the lateral energy fluence distribution at the ground to reconstruct Xmax with radio antennas developed for vertical air showers lose their sensitivity. A recently proposed interferometric technique promises measurements of the depth of the shower maximum Xmax with an intrinsic accuracy of 3 g cm−2 for very inclined air showers, however, without considering instrumental uncertainties. In this contribution, we evaluate the potential of interferometric Xmax measurements of (simulated) inclined air showers with realistically dimensioned, sparse antenna arrays and account for imperfect time synchronization between individual antennas. We find a strong correlation between the antenna multiplicity (per event) and the maximum acceptable inaccuracy in the time synchronization of individual antennas. We formulate prerequisites for the design of antenna arrays for the application of interferometric measurements: For data recorded with a time synchronization accurate to 1 ns within the commonly used frequency band of 30 MHz to 80 MHz, an antenna multiplicity of >∼ 50 is needed to achieve an Xmax reconstruction with an accuracy of 20 g cm−2. This multiplicity is achieved by measuring inclined air showers with zenith angles θ ≥ 77.5◦ with 1 km spaced antenna arrays, while vertical air showers with zenith angles θ ≤ 40◦ require an antenna spacing below 100 m. Furthermore, we find no improvement in the Xmax resolution applying the interferometric reconstruction to simulated radio signals at higher frequencies, i.e., up to several hundred MHz. |
