Planetary surfaces

Revealing a high water abundance in the upper mesosphere of Mars with ACS onboard TGO

Geophysical Research Letters Wiley 48:10 (2021) e2021GL093411

Authors:

Denis A Belyaev, Anna A Fedorova, Alexander Trokhimovskiy, Juan Alday, Franck Montmessin, Oleg I Korablev, Franck Lefevre, Andrey S Patrakeev, Kevin S Olsen, Alexey V Shakun

Abstract:

We present the first water vapor profiles encompassing the upper mesosphere of Mars, 100–120 km, far exceeding the maximum altitudes where remote sensing has been able to observe water to date. Our results are based on solar occultation measurements by Atmospheric Chemistry Suite (ACS) onboard the ExoMars Trace Gas Orbiter (TGO). The observed wavelength range around 2.7 μm possesses strong CO2 and H2O absorption lines allowing sensitive temperature and density retrievals. We report a maximum H2O mixing ratio varying from 10 to 50 ppmv at 100–120 km during the global dust storm (GDS) of Martian Year (MY) 34 and around southern summer solstice of MY 34 and 35. During other seasons water remains persistently below ∼2 ppmv. We claim that contributions of the MY34 GDS and perihelion periods into the projected hydrogen escape from Mars are nearly equivalent.

Ariel planetary interiors white paper

Experimental Astronomy Springer 53:2 (2021) 323-356

Authors:

Ravit Helled, Stephanie Werner, Caroline Dorn, Tristan Guillot, Masahiro Ikoma, Yuichi Ito, Mihkel Kama, Tim Lichtenberg, Yamila Miguel, Oliver Shorttle, Paul J Tackley, Diana Valencia, Allona Vazan

Abstract:

The recently adopted Ariel ESA mission will measure the atmospheric composition of a large number of exoplanets. This information will then be used to better constrain planetary bulk compositions. While the connection between the composition of a planetary atmosphere and the bulk interior is still being investigated, the combination of the atmospheric composition with the measured mass and radius of exoplanets will push the field of exoplanet characterisation to the next level, and provide new insights of the nature of planets in our galaxy. In this white paper, we outline the ongoing activities of the interior working group of the Ariel mission, and list the desirable theoretical developments as well as the challenges in linking planetary atmospheres, bulk composition and interior structure.

The Deployment of the Seismometer to Investigate Ice and Ocean Structure (SIIOS) in Northwest Greenland: An Analog Experiment for Icy Ocean World Seismic Deployments

Seismological Research Letters Seismological Society of America (SSA) 92:3 (2021) 2036-2049

Authors:

Angela G Marusiak, Nicholas C Schmerr, Daniella N DellaGiustina, Brad Avenson, S Hop Bailey, Veronica J Bray, Juliette I Brodbeck, Chris G Carr, Peter H Dahl, Namrah Habib, Erin C Pettit, Natalie Wagner, Renee C Weber

Dynamics of Subsurface Migration of Water on the Moon

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:5 (2021)

Authors:

P Reiss, T Warren, E Sefton‐Nash, R Trautner

Investigation of Venus Cloud Aerosol and Gas Composition Including Potential Biogenic Materials via an Aerosol-Sampling Instrument Package.

Astrobiology (2021)

Authors:

Kevin H Baines, Dragan Nikolić, James A Cutts, Mona L Delitsky, Jean-Baptiste Renard, Stojan M Madzunkov, Laura M Barge, Olivier Mousis, Colin Wilson, Sanjay S Limaye, Nicolas Verdier

Abstract:

A lightweight, low-power instrument package to measure, <i>in situ,</i> both (1) the local gaseous environment and (2) the composition and microphysical properties of attendant venusian aerosols is presented. This Aerosol-Sampling Instrument Package (ASIP) would be used to explore cloud chemical and possibly biotic processes on future aerial missions such as multiweek balloon missions and on short-duration (<1 h) probes on Venus and potentially on other cloudy worlds such as Titan, the Ice Giants, and Saturn. A quadrupole ion-trap mass spectrometer (QITMS; Madzunkov and Nikolić, <i>J Am Soc Mass Spectrom</i> 25:1841-1852, 2014) fed alternately by (1) an aerosol separator that injects only aerosols into a vaporizer and mass spectrometer and (2) the pure aerosol-filtered atmosphere, achieves the compositional measurements. Aerosols vaporized <600°C are measured over atomic mass ranges from 2 to 300 AMU at <0.02 AMU resolution, sufficient to measure trace materials, their isotopic ratios, and potential biogenic materials embedded within H₂SO₄ aerosols, to better than 20% in <300 s for H₂SO₄ -relative abundances of 2 × 10^-9. An integrated lightweight, compact nephelometer/particle-counter determines the number density and particle sizes of the sampled aerosols.