Glory revealed in disk-integrated photometry of Venus

TL;DR

This study presents the first evidence of a glory phenomenon in the disk-integrated photometry of Venus, revealing insights into its cloud properties and suggesting potential for detecting liquid clouds on exoplanets.

Contribution

It demonstrates the detection of a planetary glory in Venus's phase curves, linking optical features to atmospheric droplet properties and advancing exoplanet cloud characterization methods.

Findings

Glory observed at phase angles of 11-13 degrees in Venus.

Planet brightness varies by up to 10% due to the glory.

Model predictions align with observed scattering properties.

Abstract

Context. Reflected light from a spatially unresolved planet yields unique insight into the overall optical properties of the planet cover. Glories are optical phenomena caused by light that is backscattered within spherical droplets following a narrow distribution of sizes; they are well known on Earth as localised features above liquid clouds. Aims. Here we report the first evidence for a glory in the disk-integrated photometry of Venus and, in turn, of any planet. Methods. We used previously published phase curves of the planet that were reproduced over the full range of phase angles with model predictions based on a realistic description of the Venus atmosphere. We assumed that the optical properties of the planet as a whole can be described by a uniform and stable cloud cover, an assumption that agrees well with observational evidence. Results. We specifically show that the measured phase curves mimic the scattering properties of the Venus upper-cloud micron-sized aerosols, also at the small phase angles at which the glory occurs, and that the glory contrast is consistent with what is expected after multiple scattering of photons. In the optical, the planet appears to be brighter at phase angles of 11-13 deg than at full illumination; it undergoes a maximum dimming of up to 10 percent at phases in between. Conclusions. Glories might potentially indicate spherical droplets and, thus, extant liquid clouds in the atmospheres of exoplanets. A prospective detection will require exquisite photometry at the small planet-star separations of the glory phase angles.