Constraining the radius and atmospheric properties of directly imaged exoplanets through multi-phase observations

Abstract

The theory of remote sensing shows that observing a planet at multiple phase angles (α) is a powerful strategy to characterize its atmosphere. Here, we analyse how the information contained in reflected-starlight spectra of exoplanets depends on the phase angle, and the potential of multi-phase measurements to better constrain the atmospheric properties and the planet radius (Rp). We simulate spectra (500-900 nm) at α=37, 85 and 123 with spectral resolution R~125-225 and signal-to-noise ratio S/N=10. Assuming a H2-He atmosphere, we use a seven-parameter model that includes the atmospheric methane abundance (fCH4), the optical properties of a cloud layer and Rp. All these parameters are assumed unknown a priori and explored with an MCMC retrieval method. We find that no single-phase observation can robustly identify whether the atmosphere has clouds or not. A single-phase observation at α=123 and S/N=10 can constrain Rp with a maximum error of 35%, regardless of the cloud coverage. Combining small (37) and large (123) phase angles is a generally effective strategy to break multiple parameter degeneracies. This enables to determine the presence or absence of a cloud and its main properties, fCH4 and Rp in all the explored scenarios. Other strategies, such as doubling S/N to 20 for a single-phase observation or combining small (37) and moderate (85) phase angles, fail to achieve this. We show that the improvements in multi-phase retrievals are associated with the shape of the scattering phase function of the cloud aerosols and that the improvement is more modest for isotropically-scattering aerosols. We finally discuss that misidentifying the background gas in the retrievals of super-Earth observations leads to a systematic underestimate of the absorbing gas abundance.