Modelling of radio emission in the SLAC T-510 Experiment using microscopic Geant4 simulations

Zilles, Anne; Bechtol, K.; Belov, K.; Borch, Kyle; Chen, Pisin; Clem, J.; Gorham, P. W.; Hast, C.; Huege, T.; Hyneman, R.; Jobe, K.; Kuwatani, Kyle; Lam, J.; Liu, Tsung-Che; Mulrey, Katharine; Nam, J. W.; Naudet, C. J.; Nichol, R. J.; Rauch, B. F.; Romero-Wolf, Andrés; Rotter, B.; Saltzberg, D.; Schoorlemmer, H.; Seckel, D.; Strutt, Benjamin; Vieregg, A. G.; Williams, Christopher S.; Wissel, S.

doi:10.22323/1.236.0313

Cited by 5 publications

(5 citation statements)

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“…Cross-checks between the ZHS and endpoints formalisms have been made in the context of the SLAC T-510 experiment [55], indicating that the formalisms produce results agreeing within ≈ 5% of each other [56]. It is thus likely that deviations between CoREAS and ZHAireS are related mostly to the underlying air shower simulation between AIRES and CORSIKA, possibly related to hadronic interaction models and/or the choice of energy cuts for the simulation of the particle cascade.…”

Section: Agreement Between Different Approachesmentioning

confidence: 99%

Radio detection of cosmic ray air showers in the digital era

2016

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In 1965 it was discovered that cosmic ray air showers emit impulsive radio signals at frequencies below 100 MHz. After a period of intense research in the 1960s and 1970s, however, interest in the detection technique faded almost completely. With the availability of powerful digital signal processing techniques, new attempts at measuring cosmic ray air showers via their radio emission were started at the beginning of the new millennium. Starting with modest, small-scale digital prototype setups, the field has evolved, matured and grown very significantly in the past decade. Today's second-generation digital radio detection experiments consist of up to hundreds of radio antennas or cover areas of up to 17 km$^{2}$. We understand the physics of the radio emission in extensive air showers in detail and have developed analysis strategies to accurately derive from radio signals parameters which are related to the astrophysics of the primary cosmic ray particles, in particular their energy, arrival direction and estimators for their mass. In parallel to these successes, limitations inherent in the physics of the radio signals have also become increasingly clear. In this article, we review the progress of the past decade and the current state of the field, discuss the current paradigm of the radio emission physics and present the experimental evidence supporting it. Finally, we discuss the potential for future applications of the radio detection technique to advance the field of cosmic ray physics.Comment: Accepted for publication in Physics Report

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Section: Agreement Between Different Approachesmentioning

confidence: 99%

Radio detection of cosmic ray air showers in the digital era

2016

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“…The simulations are described in details in Ref. [2]. The systematic uncertainty between the models does not exceed 3% in the peak-to-peak amplitudes or in the frequency spectra in the 30-1400 MHz range.…”

Section: Radio Emission Modelsmentioning

confidence: 99%

SLAC T-510: A beam-line experiment for radio emission from particle cascades in the presence of a magnetic field

Belov¹,

Bechtol²,

Borch³

et al. 2016

Proceedings of the 34th International Cosmic Ray Conference — PoS(ICRC2015)

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We report on the first observations of radio emission from transverse currents induced in a secondary cascade by a magnetic field in dense media. Only the Askaryan effect has been observed in previous experiments in ice, silica sand and in rock salt. These measurements are important because the radio detection of ultra-high energy cosmic rays (UHECRs) relies on models of radio emission from extensive air showers. In order to validate the models we performed an experiment at SLAC National Accelerator Laboratory in 2014 using a high density polyethylene (HDPE) target placed in a magnetic field, yielding results within 36% of the model predictions.

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“…Combined with the GEANT 4.10 toolkit, they provide the predictions for the radio emission in the SLAC T-510 experiemnt. are discussed in more detail in [7]. We describe here the experimental data and system calibration used for such comparisons.For a discussion of the simulations developed for this experiment, see Zilles et al in these proceedings [7].…”

Section: Overviewmentioning

confidence: 99%

“…Because the vertical (B z ) field falls off near the edges of the coils, we placed the edge of the target in the middle of the first coil. Along the beam position, the average magnetic field in the vertical direction is -845 G, and the root-mean-squared variation is 72 G. In our simulations of the T-510 experiment, we included the measured, three-dimensional magnetic field [7].…”

Section: Magnetic Fieldmentioning

confidence: 99%

“…5 shows power spectral densities measured at several positions (1.30 m, 6.52 m,11.29 m) above the beam height and 13.47 m from the point where the beam enters the target. The spectra are compared with simulations following the ZHS and Endpoints formalisms [7] that are convolved with the effective height and system response shown in Fig. 4.…”

Section: Antenna and System Responsementioning

confidence: 99%

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