Space instrumentation

Relationships between HCl, H2 O, aerosols, and temperature in the Martian atmosphere Part II: quantitative correlations

University of Oxford (2024)

Abstract:

NB: this dataset has now been SUPERSEDED by the version at https://ora.ox.ac.uk/objects/uuid:31ee4ec6-ad9c-4804-be86-da5aba057fd2.

Data generated for and supporting the Publication: Relationships between HCl, H2 O, aerosols, and temperature in the Martian atmosphere Part I: climatological outlook for the Journal of Geophysics Research.

Relationships between HCl, H2 O, aerosols, and temperature in the Martian atmosphere Part I: climatological outlook

University of Oxford (2024)

Abstract:

Data generated for and supporting the publication: Relationships between HCl, H2 O, aerosols, and temperature in the Martian atmosphere Part I: climatological outlook for the Journal of Geophysical Research

Relationships between HCl, H2 O, aerosols, and temperature in the Martian atmosphere Part II: quantitative correlations

University of Oxford (2024)

Abstract:

Data generated for and supporting the the Publication: Relationships between HCl, H2O, aerosols, and temperature in the Martian atmosphere Part II: quantitative correlations

Possible Effects of Volcanic Eruptions on the Modern Atmosphere of Venus.

Space science reviews 220:3 (2024) 31

Authors:

Colin F Wilson, Emmanuel Marcq, Cédric Gillmann, Thomas Widemann, Oleg Korablev, Nils T Mueller, Maxence Lefèvre, Paul B Rimmer, Séverine Robert, Mikhail Y Zolotov

Abstract:

This work reviews possible signatures and potential detectability of present-day volcanically emitted material in the atmosphere of Venus. We first discuss the expected composition of volcanic gases at present time, addressing how this is related to mantle composition and atmospheric pressure. Sulfur dioxide, often used as a marker of volcanic activity in Earth's atmosphere, has been observed since late 1970s to exhibit variability at the Venus' cloud tops at time scales from hours to decades; however, this variability may be associated with solely atmospheric processes. Water vapor is identified as a particularly valuable tracer for volcanic plumes because it can be mapped from orbit at three different tropospheric altitude ranges, and because of its apparent low background variability. We note that volcanic gas plumes could be either enhanced or depleted in water vapor compared to the background atmosphere, depending on magmatic volatile composition. Non-gaseous components of volcanic plumes, such as ash grains and/or cloud aerosol particles, are another investigation target of orbital and in situ measurements. We discuss expectations of in situ and remote measurements of volcanic plumes in the atmosphere with particular focus on the upcoming DAVINCI, EnVision and VERITAS missions, as well as possible future missions.

Ultraviolet and visible reflectance spectra of Phobos and Deimos as measured by the ExoMars-TGO/Nomad-UVIS spectrometer

Journal of Geophysical Research: Planets Wiley 128:12 (2023) e2023JE008002

Authors:

Jp Mason, Mr Patel, M Pajola, Ed Cloutis, J Alday, Ks Olsen, C Marriner, Ja Holmes, G Sellers, N Thomas, M Almeida, M Read, H Nakagawa, Ir Thomas, B Ristic, Y Willame, C Depiesse, F Daerden, Ac Vandaele, Jj Lopez-Moreno, G Bellucci

Abstract:

Spectroscopic measurements are a powerful tool to investigate the surface composition of airless bodies and provide clues of their origin. The composition and origin of Phobos and Deimos are still unknown and are currently widely debated. We present spectroscopic measurements of Phobos and Deimos at ultraviolet and visible wavelengths (250–650 nm) made by the NOMAD-Ultraviolet and Visible Spectrometer (UVIS) on the ExoMars TGO mission. These new spectra cover multiple areas on Phobos and Deimos, and are of generally higher spectral resolution and signal-to-noise than previous spectra, and extend to lower wavelengths than most previous measurements. The UVIS spectra confirm a red-sloped spectrum lacking any strong absorption features; however, we confirm the presence of a previously identified absorption feature near 0.65 μm and tentative absorption near 0.45 μm. The observed Phobos and Deimos spectra are similar to D- and T-type asteroids, adding weight to the captured asteroid hypothesis for the moons' origins. We also find, however, that the UVIS Phobos reflectance spectra of Phobos' red unit is a relatively close match to the olivine-rich, highly shocked Mars meteorite NWA 2737, with a low overall reflectance, a red-sloped spectrum, and lack of olivine-associated absorption bands in the UVIS spectral range. This meteorite, however, exhibits spectral features at longer wavelengths that not observed in the Martian moon spectra, indicating a need for further investigation at longer wavelengths to interpret whether this material could inform our understanding of Phobos' origin.