Lightning climatology of exoplanets and brown dwarfs guided by Solar System data

TL;DR

This paper analyzes lightning patterns on Solar System planets and estimates lightning activity on exoplanets and brown dwarfs, highlighting the influence of atmospheric and stellar factors on lightning occurrence.

Contribution

It introduces a framework for estimating lightning activity on exoplanets based on Solar System data and categorizes exoplanets by potential lightning occurrence.

Findings

Lightning distribution maps for Earth, Jupiter, and Saturn are presented.

Lightning rates are estimated for various exoplanet categories.

Volcanic activity may significantly increase lightning flash densities.

Abstract

Clouds form on extrasolar planets and brown dwarfs where lightning could occur. Lightning is a tracer of atmospheric convection, cloud formation and ionization processes as known from the Solar System, and may be significant for the formation of prebiotic molecules. We study lightning climatology for the different atmospheric environments of Earth, Venus, Jupiter and Saturn. We present lightning distribution maps for Earth, Jupiter and Saturn, and flash densities for these planets and Venus, based on optical and/or radio measurements from the WWLLN and STARNET radio networks, the LIS/OTD satellite instruments, the Galileo, Cassini, New Horizons and Venus Express spacecraft. We also present flash densities calculated for several phases of two volcano eruptions, Eyjafjallaj\"okull's (2010) and Mt Redoubt's (2009). We estimate lightning rates for sample, transiting and directly imaged extrasolar planets and brown dwarfs. Based on the large variety of exoplanets, six categories are suggested for which we use the lightning occurrence information from the Solar System. We examine lightning energy distributions for Earth, Jupiter and Saturn. We discuss how strong stellar activity may support lightning activity. We provide a lower limit of the total number of flashes that might occur on transiting planets during their full transit as input for future studies. We find that volcanically very active planets might show the largest lightning flash densities. When applying flash densities of the large Saturnian storm from 2010/11, we find that the exoplanet HD 189733b would produce high lightning occurrence even during its short transit.