A mini-chemical scheme with net reactions for 3D general circulation models. I. Thermochemical kinetics

Astronomy and Astrophysics EDP Sciences 664 (2022) A82

Authors:

S-M Tsai, Ekh Lee, R Pierrehumbert

Abstract:

Context. Growing evidence has indicated that the global composition distribution plays an indisputable role in interpreting observational data. Three-dimensional general circulation models (GCMs) with a reliable treatment of chemistry and clouds are particularly crucial in preparing for upcoming observations. In attempts to achieve 3D chemistry-climate modeling, the challenge mainly lies in the expensive computing power required for treating a large number of chemical species and reactions.
Aims. Motivated by the need for a robust and computationally efficient chemical scheme, we devise a mini-chemical network with a minimal number of species and reactions for H2-dominated atmospheres.
Methods. We apply a novel technique to simplify the chemical network from a full kinetics model, VULCAN, by replacing a large number of intermediate reactions with net reactions. The number of chemical species is cut down from 67 to 12, with the major species of thermal and observational importance retained, including H2O, CH4, CO, CO2, C2H2, NH3, and HCN. The size of the total reactions is also greatly reduced, from ~800 to 20. We validated the mini-chemical scheme by verifying the temporal evolution and benchmarking the predicted compositions in four exoplanet atmospheres (GJ 1214b, GJ 436b, HD 189733b, and HD 209458b) against the full kinetics of VULCAN.
Results. The mini-network reproduces the chemical timescales and composition distributions of the full kinetics well within an order of magnitude for the major species in the pressure range of 1 bar–0.1 mbar across various metallicities and carbon-to-oxygen (C/O) ratios.
Conclusions. We have developed and validated a mini-chemical scheme using net reactions to significantly simplify a large chemical network. The small scale of the mini-chemical scheme permits simple use and fast computation, which is optimal for implementation in a 3D GCM or a retrieval framework. We focus on the thermochemical kinetics of net reactions in this paper and address photochemistry in a follow-up paper.

Modeling Thermal Emission under Lunar Surface Environmental Conditions

The Planetary Science Journal IOP Publishing 3:7 (2022) 180-180

Authors:

Parvathy Prem, Benjamin T Greenhagen, Kerri L Donaldson Hanna, Katherine A Shirley, Timothy D Glotch

Abstract:

We studied a series of hermean lava analogs in the mid-infrared (2.5 μm–18 μm) to provide characteristic spectra for enstatite basalt, the Northern Volcanic Plains and Na-rich Northern Volcanic Plains. Our aim is to provide spectra for the interpretation of the data expected from Mercury from the MERTIS (MErcury Radiometer and Thermal Infrared Spectrometer) instrument on the ESA/JAXA BepiColombo mission. Bulk powder spectra show bands of glass with a dominating broad Si-O-Si stretching feature around 10 μm. Crystalline components are mainly enstatite and forsterite with Reststrahlen Bands (RBs) around 9.3 μm, 9.6–9.9 μm, 10.0 μm, and 10.3–10.7 μm. Increasing intensity of crystalline features in the spectra reflect the increase in the crystallites in glass with decreasing temperature of equilibration and quenching. Micro-FTIR data allowed to extract spectral of individual components and glass. The position of the Christiansen Feature (CF) has only a weak correlation with the degree of crystallinity. Correlations are observed between the Christiansen Feature (CF) and the bulk SiO2 content of the materials, as does the correlation of this feature with the compositional index SCFM = SiO2/(SiO2 + CaO + FeO + MgO) on an atomic basis. This study also confirms the correlation line of glass-rich, irradiated Mercury analogs in these systems (Weber et al.,2023), indicating a similar spectral response of the glass rich materials expected for the surface of Mercury. The position of the strongest silicate main band (MB) compared to the SiO2 content, confirms a trend for samples formed in experiments simulating high velocity impacts fall on a different trend line than analog samples formed in magmatic processes. A comparison of the results to an Earth-based hermean surface spectrum showed similarities to spectra obtained for NVP samples

Visible and infrared spectral analysis of the Winchcombe Meteorite for comparison with planetary Surfaces

Proceedings of the 85th Annual Meeting of the Meteoritical Society (MetSoc 2022) Wiley 57:S1 (2022)

Authors:

Ka Shirley, Rj Curtis, Hc Bates, Aj King, Ne Bowles

Three-dimensional structure of thermal waves in Venus’ mesosphere from ground-based observations

Icarus Elsevier 387 (2022) 115187

Authors:

Rohini S Giles, Thomas K Greathouse, Patrick Irwin, Thérèse Encrenaz, Amanda Brecht

Abstract:

High spectral resolution observations of Venus were obtained with the TEXES instrument at NASA’s Infrared Telescope Facility. These observations focus on a CO2 absorption feature at 791.4 cm-1 as the shape of this absorption feature can be used to retrieve the vertical temperature profile in Venus’ mesosphere. By scan-mapping the planet, we are able to build up three-dimensional temperature maps of Venus’ atmosphere, covering one Earth-facing hemisphere and an altitude range of 60–83 km. A temperature map from February 12, 2019 clearly shows the three-dimensional structure of a planetary-scale thermal wave. This wave pattern appears strongest in the mid-latitudes of Venus, has a zonal wavenumber of 2–4 and the wave fronts tilt eastward with altitude at an angle of 8–15 degrees per km. This is consistent with a thermal tide propagating upwards from Venus’ upper cloud decks. Ground-based observations provide the opportunity to study Venus’ temperature structure on an ongoing basis.

Variability in the Uranian atmosphere: Uranus' north polar hood

Copernicus Publications (2022)

Authors:

Arjuna James, Patrick Irwin, Jack Dobinson, Mike Wong, Amy Simon, Erich Karkoschka, Martin Tomasko, Lawrence Sromovsky