A photochemical model for the carbon-rich planet WASP-12b

Abstract

The hot Jupiter WASP-12b is a heavily irradiated exoplanet in a short period orbit around a G0-star with twice the metallicity of the Sun. A recent thermochemical equilibrium analysis based on Spitzer and ground-based infrared observations suggests that the presence of 4 in its atmosphere and the lack of 2o features can only be explained if the carbon-to-oxygen ratio in the planet's atmosphere is much greater than the solar ratio ( = 0.54). Here, we use a 1-D photochemical model to study the effect of disequilibrium chemistry on the observed abundances of 2o, , 2 and 4 in the WASP-12b atmosphere. We consider two cases: one with solar and another with = 1.08. The solar case predicts that 2o and are more abundant than 2 and 4, as expected, whereas the high model shows that , C2H2 and HCN are more abundant. This indicates that the extra carbon from the high model is in hydrocarbon species. 2o photolysis is the dominant disequilibrium mechanism that alters the chemistry at higher altitudes in the solar case, whereas photodissociation of C2H2 and HCN is significant in the super-solar case. Furthermore, our analysis indicates that 2h2 is the major absorber in the atmosphere of WASP-12b and the absorption features detected near 1.6 and 8 micron may be arising from C2H2 rather than 4. The Hubble Space Telescope's WFC3 can resolve this discrepancy, as 2h2 has absorption between 1.51 - 1.54 microns, while 4 does not.