Space instrumentation

Venus: key to understanding the evolution of terrestrial planets

Experimental Astronomy Springer Science and Business Media LLC (2021)

Authors:

Colin F Wilson, Thomas Widemann, Richard Ghail

Abstract:

<jats:title>Abstract</jats:title><jats:p>In this paper, originally submitted in answer to ESA’s “Voyage 2050” call to shape the agency’s space science missions in the 2035–2050 timeframe, we emphasize the importance of a Venus exploration programme for the wider goal of understanding the diversity and evolution of habitable planets. Comparing the interior, surface, and atmosphere evolution of Earth, Mars, and Venus is essential to understanding what processes determined habitability of our own planet and Earth-like planets everywhere. This is particularly true in an era where we expect thousands, and then millions, of terrestrial exoplanets to be discovered. Earth and Mars have already dedicated exploration programmes, but our understanding of Venus, particularly of its geology and its history, lags behind. Multiple exploration vehicles will be needed to characterize Venus’ richly varied interior, surface, atmosphere and magnetosphere environments. Between now and 2050 we recommend that ESA launch at least two M-class missions to Venus (in order of priority): a geophysics-focussed orbiter (the currently proposed M5 EnVision orbiter – [1] – or equivalent); and an in situ atmospheric mission (such as the M3 EVE balloon mission – [2]). An in situ and orbital mission could be combined in a single L-class mission, as was argued in responses to the call for L2/L3 themes [3–5]. After these two missions, further priorities include a surface lander demonstrating the high-temperature technologies needed for extended surface missions; and/or a further orbiter with follow-up high-resolution surface radar imaging, and atmospheric and/or ionospheric investigations.</jats:p>

Redox hysteresis of super-Earth exoplanets from magma ocean circulation

Astrophysical Journal Letters American Astronomical Society 914:1 (2021) L4

Abstract:

Internal redox reactions may irreversibly alter the mantle composition and volatile inventory of terrestrial and super-Earth exoplanets and affect the prospects for atmospheric observations. The global efficacy of these mechanisms, however, hinges on the transfer of reduced iron from the molten silicate mantle to the metal core. Scaling analysis indicates that turbulent diffusion in the internal magma oceans of sub-Neptunes can kinetically entrain liquid iron droplets and quench core formation. This suggests that the chemical equilibration between core, mantle, and atmosphere may be energetically limited by convective overturn in the magma flow. Hence, molten super-Earths possibly retain a compositional memory of their accretion path. Redox control by magma ocean circulation is positively correlated with planetary heat flow, internal gravity, and planet size. The presence and speciation of remanent atmospheres, surface mineralogy, and core mass fraction of primary envelope-stripped exoplanets may thus constrain magma ocean dynamics.

Annual appearance of hydrogen chloride on Mars and a striking similarity with the water vapor vertical distribution observed by TGO/NOMAD

Geophysical Research Letters Wiley 48:11 (2021) e2021GL092506

Authors:

S Aoki, F Daerden, S Viscardy, Ir Thomas, Jt Erwin, S Robert, L Trompet, L Neary, Gl Villanueva, G Liuzzi, Mmj Crismani, Rt Clancy, J Whiteway, F Schmidt, Ma Lopez-Valverde, B Ristic, Mr Patel, G Bellucci, Jj Lopez-Moreno, Ks Olsen, F Lefevre, F Montmessin, A Trokhimovskiy, Aa Fedorova, O Korablev, Ac Vandaele

Abstract:

Hydrogen chloride (HCl) was recently discovered in the atmosphere of Mars by two spectrometers onboard the ExoMars Trace Gas Orbiter. The reported detection made in Martian Year 34 was transient, present several months after the global dust storm during the southern summer season. Here, we present the full data set of vertically resolved HCl detections obtained by the NOMAD instrument, which covers also Martian year 35. We show that the particular increase of HCl abundances in the southern summer season is annually repeated, and that the formation of HCl is independent from a global dust storm event. We also find that the vertical distribution of HCl is strikingly similar to that of water vapor, which suggests that the uptake by water ice clouds plays an important role. The observed rapid decrease of HCl abundances at the end of the southern summer would require a strong sink independent of photochemical loss.

Christiansen Feature Map From the Lunar Reconnaissance Orbiter Diviner Lunar Radiometer Experiment: Improved Corrections and Derived Mineralogy

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:6 (2021)

Authors:

Paul G Lucey, Benjamin Greenhagen, Kerri Donaldson Hanna, Neil Bowles, Abigail Flom, David A Paige

Integral Field Techniques

Chapter in , World Scientific Publishing (2021) 257-283

Authors:

Fraser Clarke, Matthias Tecza