Improved Constraints on the Vertical Profile of CH4 at Jupiter's Mid- to High Latitudes, Using IRTF-TEXES and SOFIA-EXES Spectroscopy
journal contribution
posted on 2025-02-06, 10:30 authored by James A Sinclair, Thomas K Greathouse, Rohini S Giles, Matthew Richter, Maisie Rashman, Curtis de Witt, Julianne Moses, Vincent Hue, Pablo Rodríguez-Ovalle, Thierry Fouchet, Ananyo Bhattacharya, Bilal Benmahi, Glenn S Orton, Leigh FletcherLeigh Fletcher, Patrick GJ IrwinAbstract
We present radiative transfer analyses of IRTF-TEXES and SOFIA-EXES mid-infrared spectra of Jupiter's mid- to high latitudes recorded between 2019 April 16 and 2023 July 20. The spectra were inverted across a photochemical model grid of varying eddy diffusion coefficient profiles, and the quality of fit of the synthetic spectra to the observed was used to constrain the CH4 homopause level. For a subset of latitudes/dates, we find that the CH4 homopause level is elevated in the region enclosed inside of, or magnetospherically poleward of, the northern ultraviolet main auroral emissions (MAEs) in comparison to the region outside or equatorward of the MAE. For example, using SOFIA-EXES results on 2021 June 10, we derived a CH4 homopause level of log(p
H(nbar)) = 1.54
−
0.69
+
0.51
or z
H = 453
−
76
+
128
km above 1 bar poleward of the northern MAE at 68∘N compared to a lower limit of log(p
H) > 2.43 and upper limit of z
H < 322 km derived equatorward of the northern MAE. We therefore conclude that the region poleward of the northern MAE is, at times, subject to enhanced vertical transport resulting from auroral energy deposition. The exact mechanisms responsible for the enhanced vertical transport in Jupiter's auroral regions are uncertain: time-dependent circulation modeling of Jupiter's polar atmosphere is required to better understand this phenomenon. Poleward of the southern MAE, derived homopause levels agreed within uncertainty with those at equatorward locations. However, we consider this result a spatial sampling artifact rather than concluding that the southern auroral region is not subject to enhanced vertical transport.
Funding
The research was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration (80NM0018D0004). The material is based on work supported by NASA under grants NNH17ZDA001N and NNH20ZDA001N issued through the Solar System Observations Planetary Astronomy program. A subset of the observations presented in this work were recorded at NASA's Infrared Telescope Facility (IRTF). The IRTF is operated by the University of Hawaii under contract 80HQTR19D0030 with NASA. A subset of the observations presented in this work were recorded with the NASA/DLR Stratospheric Observatory for Infrared Astronomy (SOFIA) during Cycles 7 and 8. SOFIA is jointly operated by the Universities Space Research Association, Inc. (USRA), under NASA contract NNA17BF53C, and the Deutsches SOFIA Institut (DSI) under DLR contract 50 OK 2002 to the University of Stuttgart. Financial support for this work was provided by NASA through award nos. 07_0222 and 08_219 issued by USRA. The radiative transfer analyses presented in this work were performed efficiently using JPL's High Performance Computing (HPC) resources, which were provided by funding from the JPL Information and Technology Solutions Directorate
History
Author affiliation
College of Science & Engineering Physics & AstronomyVersion
- VoR (Version of Record)
