Macroscopic parameterization of positive streamer heads in air

TL;DR

This paper develops a macroscopic model relating key properties of positive streamer heads in air, enabling better understanding and evaluation of streamer dynamics and electric fields in discharge phenomena.

Contribution

It introduces a simplified, steady-state model based on three differential equations that accurately predicts streamer head profiles from measurable parameters.

Findings

Model agrees well with classical fluid solutions

Enables estimation of maximal electric field from streamer properties

Applicable to accelerating streamers and collective discharge phenomena

Abstract

The growth of streamer discharges is determined at their heads, for individual streamers as well as in collective phenomena, such as streamer trees or coronas or streamer bursts ahead of lightning leaders. Some properties of the streamer heads, such as velocity $v$ and radius $R$ now can be measured quite well, but this is very challenging for others such as the maximal electric field, the charge content of the streamer head and the degree of chemical excitation and ionization in the streamer channel. Here we develop, test and evaluate a macroscopic approximation for positive streamer heads in air that relates macroscopic streamer head properties to each other. In particular, we find that velocity $v$, radius $R$ and background field $E_{\rm bg}$ determine the complete profile of streamer heads with photoionization, if they propagate steadily. We also review Naidis' approximate relation between $v$, $R$ and the maximal field $E_{\rm max}$. The approximate head model developed in the present paper consists of three first-order ordinary differential equations along the streamer axis. It is derived from the classical fluid model for streamer discharges by assuming axisymmetry, steady streamer propagation (i.e. with constant velocity and shape), and a spherical shape of the charge layer around the streamer head. The new reduced model agrees well with full solutions of the classical fluid model, even when it is applied to accelerating streamers. Therefore the model can be used for evaluations of experiments, like for the determination of the maximal electric field from radius and velocity of the streamer. It is also a step towards constructing reduced models for the collective dynamics of multi-streamer discharges.