Signatures of Nitrogen Chemistry in Hot Jupiter Atmospheres

TL;DR

This paper investigates the detectability of nitrogen-bearing molecules like NH3 and HCN in hot Jupiter atmospheres using current and future infrared observations, highlighting their significance for understanding disequilibrium chemistry and planetary formation.

Contribution

It predicts spectral features of nitrogen chemistry in the 1-5μm range and reports weak detections in existing spectra, emphasizing the potential of upcoming telescopes for definitive identification.

Findings

Weak detections of NH3 and HCN in some hot Jupiters.

Predicted strong spectral features at 2.2μm, 3.1μm, and 4.0μm.

Potential for future JWST observations to confirm nitrogen chemistry.

Abstract

Inferences of molecular compositions of exoplanetary atmospheres have generally focused on C, H, and O-bearing molecules. Recently, additional absorption in HST WFC3 transmission spectra around 1.55$\mu$m has been attributed to nitrogen-bearing chemical species: NH$_3$ or HCN. These species, if present in significant abundance, would be strong indicators of disequilibrium chemical processes -- e.g. vertical mixing and photochemistry. The derived N abundance, in turn, could also place important constraints on planetary formation mechanisms. Here, we examine the detectability of nitrogen chemistry in exoplanetary atmospheres. In addition to the WFC3 bandpass (1.1-1.7$\mu$m), we find that observations in K-band at $\sim$2.2$\mu$m, achievable with present ground-based telescopes, sample a strong NH$_3$ feature, whilst observations at $\sim$3.1$\mu$m and $\sim$4.0$\mu$m sample strong HCN features. In anticipation of such observations, we predict absorption feature amplitudes due to nitrogen chemistry in the 1-5$\mu$m spectral range possible for a typical hot Jupiter. Finally, we conduct atmospheric retrievals of 9 hot Jupiter transmission spectra in search of near-infrared absorption features suggestive of nitrogen chemistry. We report weak detections of NH$_3$ in WASP-31b (2.2$\sigma$), HCN in WASP-63b (2.3$\sigma$), and excess absorption that could be attributed to NH$_3$ in HD 209458b. High-precision observations from 1-5$\mu$m (e.g., with the James Webb Space Telescope), will enable definitive detections of nitrogen chemistry, in turn serving as powerful diagnostics of disequilibrium atmospheric chemistry and planetary formation processes.