The influence of forward-scattered light in transmission measurements of (exo)planetary atmospheres

TL;DR

This study demonstrates that forward-scattering by particles in planetary atmospheres significantly affects transmission spectra and planetary radius estimates, highlighting the need to include scattering effects in atmospheric retrievals.

Contribution

The paper introduces a 3D Monte Carlo simulation approach to quantify the impact of forward-scattering on transmission measurements of planetary atmospheres, especially for exoplanets.

Findings

Forward-scattering increases transmitted flux in atmospheres with strongly forward-scattering particles.

Ignoring forward-scattering can lead to underestimating atmospheric gas and haze abundances by up to 8% or more.

Modeling the atmosphere as a plane-parallel slab effectively captures the contribution of forward-scattering.

Abstract

[Abridged] The transmission of light through a planetary atmosphere can be studied as a function of altitude and wavelength using stellar or solar occultations, giving often unique constraints on the atmospheric composition. For exoplanets, a transit yields a limb-integrated, wavelength-dependent transmission spectrum of an atmosphere. When scattering haze and/or cloud particles are present in the planetary atmosphere, the amount of transmitted flux not only depends on the total optical thickness of the slant light path that is probed, but also on the amount of forward-scattering by the scattering particles. Here, we present results of calculations with a three-dimensional Monte Carlo code that simulates the transmitted flux during occultations or transits. For isotropically scattering particles, like gas molecules, the transmitted flux appears to be well-described by the total atmospheric optical thickness. Strongly forward-scattering particles, however, such as commonly found in atmospheres of Solar System planets, can increase the transmitted flux significantly. For exoplanets, such added flux can decrease the apparent radius of the planet by several scale heights, which is comparable to predicted and measured features in exoplanet transit spectra. We performed detailed calculations for Titan's atmosphere between 2.0 and 2.8 micron and show that haze and gas abundances will be underestimated by about 8% if forward-scattering is ignored in the retrievals. At shorter wavelengths, errors in the gas and haze abundances and in the spectral slope of the haze particles can be several tens of percent, also for other Solar System planetary atmospheres. We also find that the contribution of forward-scattering can be fairly well described by modelling the atmosphere as a plane-parallel slab.