Planetary atmosphere observation analysis

Science Goals and Objectives for the Dragonfly Titan Rotorcraft Relocatable Lander

The Planetary Science Journal IOP Publishing 2:4 (2021) 130-130

Authors:

Jason W Barnes, Elizabeth P Turtle, Melissa G Trainer, Ralph D Lorenz, Shannon M MacKenzie, William B Brinckerhoff, Morgan L Cable, Carolyn M Ernst, Caroline Freissinet, Kevin P Hand, Alexander G Hayes, Sarah M Hörst, Jeffrey R Johnson, Erich Karkoschka, David J Lawrence, Alice Le Gall, Juan M Lora, Christopher P McKay, Richard S Miller, Scott L Murchie, Catherine D Neish, Claire E Newman, Jorge Núñez, Mark P Panning, Ann M Parsons, Colin Wilson

Abstract:

Since the beginning of robotic interplanetary exploration nearly six decades ago, successful atmospheric entry has been accomplished at Venus, Earth, Mars, Jupiter, and Titan. More entry probe missions are planned to Venus, Titan, and Uranus in the next decade. Atmospheric entry subjects the vehicle to rapid deceleration and aerothermal loads which the vehicle must be designed for, to deliver the robotic instruments inside the atmosphere. The design of planetary probes and their mission architecture is complex, and involves various engineering constraints such as peak deceleration, heating rate, heating load, and communications which must be satisfied within the budget and schedule of cost constrained mission opportunities. Engineering design data from previous entry probe missions serve as a valuable reference for designing future missions. The present study compiles an augmented version of the blue book entry probe dataset, performs a comparative analysis of the entry conditions, and provides engineering rules of thumb for design of future missions. Using the dataset, the present study proposes a new empirical correlation which aims to more accurately predict the thermal protection system mass fraction for high heat load conditions during entry and aerocapture at Uranus and Neptune.Comment: 15 pages, 15 figure

No evidence of phosphine in the atmosphere of Venus from independent analyses

Nature Astronomy Springer Nature 5:7 (2021) 631-635

Authors:

Geronimo Villanueva, Martin Cordiner, Patrick Irwin, Imke De Pater, B Butler, M Gurwell, SN Milam, Conor Nixon, Statia Luszcz-Cook, Colin Wilson, V Kofman, G Liuzzi, S Faggi, T Fauchez, M Lippi, R Cosentino, A Thelen, A Moullet, P Hartogh, E Molter, S Charnley, G Arney, A Mandell, N Biver, A Vandaele, KR de Kleer, R Kopparapu

Isotopes of chlorine from HCl in the Martian atmosphere

Astronomy and Astrophysics EDP Sciences 651 (2021) A32

Authors:

A Trokhimovskiy, Aa Fedorova, Ks Olsen, J Alday, O Korablev, F Montmessin, F Lefevre, A Patrakeev, D Belyaev, Av Shakun

Abstract:

Hydrogen chloride gas was recently discovered in the atmosphere of Mars during southern summer seasons. Its connection with potential chlorine reservoirs and the related atmospheric chemistry is now of particular interest and actively studied. Measurements by the Atmospheric Chemistry Suite mid-infrared channel (ACS MIR) on the ExoMars Trace Gas Orbiter allow us to measure the ratio of hydrogen chloride two stable isotopologues, H35Cl and H37Cl. This work describes the observation, processing technique, and derived values for the chloride isotope ratio. Unlike other volatiles in the Martian atmosphere, because it is enriched with heavier isotopes, the δ37Cl is measured to be - 7 ± 20°, which is almost indistinguishable from the terrestrial ratio for chlorine. This value agrees with available measurements of the surface materials on Mars. We conclude that chlorine in observed HCl likely originates from dust and is not involved in any long-term, surface-atmosphere cycle.

Instrumental requirements for the study of Venus’ cloud top using the UV imaging spectrometer VeSUV

Advances in Space Research (2021)

Authors:

E Marcq, F Montmessin, J Lasue, B Bézard, KL Jessup, YJ Lee, CF Wilson, B Lustrement, N Rouanet, G Guignan

Abstract:

Ultraviolet spectral imaging has been a powerful tool to investigate the cloud top of Venus, allowing for measurement of several minor gases (especially SO , SO, O ), of cloud top aerosol's microphysical properties and of atmospheric dynamics through tracking of the unevenly distributed UV absorber. After a brief review of recent UV instruments that orbited around Venus, we present the results of a state-of-the-art radiative transfer model from Marcq et al. (2020) to derive the spectral resolution and Signal-to-Noise ratio (SNR) required to derive abundances of these gases, retrieve optical properties of the aerosols beyond our current knowledge. This leads us to propose a two-channel UV hyperspectral push-broom imager called VeSUV (standing for Venusian Spectroscopy in UV) whose technical characteristics will improve on existing measurements by a factor of at least 2, and which is well suited to the integration into the payload of future low Venus orbit platforms such as the proposed EnVision mission to ESA M5 call. 2 3

A Spectral Investigation of Aqueously and Thermally Altered CM, CM‐An, and CY Chondrites Under Simulated Asteroid Conditions for Comparison With OSIRIS‐REx and Hayabusa2 Observations

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:7 (2021)

Authors:

HC Bates, KL Donaldson Hanna, AJ King, NE Bowles, SS Russell