Abstract

Abstract. The emerging field of high-energy atmospheric physics studies how high-energy particles are produced in thunderstorms, in the form of terrestrial γ-ray flashes and γ-ray glows (also referred to as thunderstorm ground enhancements). Understanding these phenomena requires appropriate models of the interaction of electrons, positrons and photons with air molecules and electric fields. We investigated the results of three codes used in the community – Geant4, GRanada Relativistic Runaway simulator (GRRR) and Runaway Electron Avalanche Model (REAM) – to simulate relativistic runaway electron avalanches (RREAs). This work continues the study of Rutjes et al. (2016), now also including the effects of uniform electric fields, up to the classical breakdown field, which is about 3.0 MV m−1 at standard temperature and pressure. We first present our theoretical description of the RREA process, which is based on and incremented over previous published works. This analysis confirmed that the avalanche is mainly driven by electric fields and the ionisation and scattering processes determining the minimum energy of electrons that can run away, which was found to be above ≈10 keV for any fields up to the classical breakdown field. To investigate this point further, we then evaluated the probability to produce a RREA as a function of the initial electron energy and of the magnitude of the electric field. We found that the stepping methodology in the particle simulation has to be set up very carefully in Geant4. For example, a too-large step size can lead to an avalanche probability reduced by a factor of 10 or to a 40 % overestimation of the average electron energy. When properly set up, both Geant4 models show an overall good agreement (within ≈10 %) with REAM and GRRR. Furthermore, the probability that particles below 10 keV accelerate and participate in the high-energy radiation is found to be negligible for electric fields below the classical breakdown value. The added value of accurately tracking low-energy particles (<10 keV) is minor and mainly visible for fields above 2 MV m−1. In a second simulation set-up, we compared the physical characteristics of the avalanches produced by the four models: avalanche (time and length) scales, convergence time to a self-similar state and energy spectra of photons and electrons. The two Geant4 models and REAM showed good agreement on all parameters we tested. GRRR was also found to be consistent with the other codes, except for the electron energy spectra. That is probably because GRRR does not include straggling for the radiative and ionisation energy losses; hence, implementing these two processes is of primary importance to produce accurate RREA spectra. Including precise modelling of the interactions of particles below 10 keV (e.g. by taking into account molecular binding energy of secondary electrons for impact ionisation) also produced only small differences in the recorded spectra.

Highlights

  • 1.1 Phenomena and observations in high-energy atmospheric physicsIn 1925, Charles to self-similar state (Ts)

  • The data we discuss were produced by the general purpose code Geant4 and two custom-made codes – GRanada Relativistic Runaway simulator (GRRR) and Runaway Electron Avalanche Model (REAM) – which we describe below

  • There seems to be a consensus between Geant4 (O1 and Option 4 physics list (O4)) and REAM, which gives mean energy that is between 8 and 9 MeV and can vary up to 10 % depending on the electric field

Read more

Summary

Introduction

1.1 Phenomena and observations in high-energy atmospheric physicsIn 1925, Charles T. R. Wilson proposed that thunderstorms could emit a “measurable amount of extremely penetrating radiation of β or γ type” (Wilson, 1925), about 60 years before such radiation was observed from the atmosphere and from space (Parks et al, 1981; Fishman et al, 1994; Williams, 2010). Wilson proposed that thunderstorms could emit a “measurable amount of extremely penetrating radiation of β or γ type” (Wilson, 1925), about 60 years before such radiation was observed from the atmosphere and from space (Parks et al, 1981; Fishman et al, 1994; Williams, 2010) This and subsequent observations and modelling are being investigated within the field of highenergy atmospheric physics (HEAP). Two space missions designed to study TGFs and related phenomena will provide new observations in the near future: ASIM (Atmosphere-Space Interaction Monitor) (Neubert et al, 2006), successfully launched in April 2018, and TARANIS (Tool for the Analysis of Radiation from lightning and Sprites) (Lefeuvre et al, 2009; Sarria et al, 2017), which is to be launched at the end of 2019

Objectives
Methods
Findings
Conclusion

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.