On mapping exoplanet atmospheres with high-dispersion spectro-polarimetry. Some model predictions

TL;DR

This paper proposes a method using high-dispersion spectro-polarimetry and Doppler shifts to detect and characterize exoplanet atmospheres, especially cloud coverage and composition, by analyzing polarized light signals.

Contribution

It introduces a novel technique combining high-dispersion spectro-polarimetry with Doppler shift analysis to extract atmospheric information from unresolved exoplanets.

Findings

Polarization signals can be detected via cross-correlation of spectra.

Optimal observation phases depend on unknown atmospheric properties.

Future large telescopes will enable detailed polarization studies of smaller, fainter exoplanets.

Abstract

Planets reflect and linearly polarize the radiation that they receive from their host stars. The emergent polarization is sensitive to aspects of the planet atmosphere such as the gas composition and the occurrence of condensates and their optical properties. Extracting this information will represent a major step in the characterization of exoplanets. The numerical simulations presented here show that the polarization of a spatially-unresolved exoplanet may be detected by cross-correlating high-dispersion linear polarization and intensity (brightness) spectra of the planet-star system. The Doppler shift of the planet-reflected starlight facilitates the separation of this signal from the polarization introduced by the interstellar medium and the terrestrial atmosphere. The selection of the orbital phases and wavelengths at which to study the planet is critical. An optimal choice however will partly depend on information about the atmosphere that is a priori unknown. We elaborate on the cases of close-in giant exoplanets with non-uniform cloud coverage, an outcome of recent brightness phase curve surveys from space, and for which the hemispheres east and west of the sub-stellar point will produce different polarizations. With integration times on the order of hours at a 10-m telescope, the technique might distinguish amongst some proposed asymmetric cloud scenarios with fractional polarizations of 10 parts per million for one such planet orbiting a V-mag=5.5 host star. Future 30-40-m telescopes equipped with high-dispersion spectro-polarimeters will be able to investigate the linear polarization of smaller planets orbiting fainter stars and look for molecular features in their polarization spectra.