Planetary atmosphere observation analysis

Retrieval of H2O abundance in Titan's stratosphere: A (re)analysis of CIRS/Cassini and PACS/Herschel observations

Icarus 311 (2018) 288-305

Authors:

S Bauduin, PGJ Irwin, E Lellouch, V Cottini, R Moreno, CA Nixon, NA Teanby, T Ansty, FM Flasar

Abstract:

© 2018 Elsevier Inc. Since its first measurement 20 years ago by the Infrared Space Observatory (ISO), the water (H 2 O) mole fraction in Titan's stratosphere remains uncertain due to large differences between the determinations from available measurements. More particularly, the recent measurements made from the Herschel observatory (PACS and HIFI) estimated the H 2 O mole fraction to be 0.023 ppb at 12.1 mbar. A mixing ratio of 0.14 ppb at 10.7 mbar was, however, retrieved from nadir spatially-resolved observations of Cassini/CIRS. At the same pressure level (10.7 mbar), this makes a difference of a factor of 5.5 between PACS and CIRS measurements, and this has notably prevented current models from fully constraining the oxygen flux flowing into Titan's atmosphere. In this work, we try to understand the differences between the H 2 O mole fractions estimated from Herschel/PACS and Cassini/CIRS observations. The strategy for this is to 1) analyse recent disc-averaged observations of CIRS to investigate if the observation geometry could explain the previous observed differences, and 2) (re)analyse the three types of observation with the same retrieval scheme to assess if previous differences in retrieval codes/methodology could be responsible for the previous discrepancies. With this analysis, we show that using the same retrieval method better reconcile the previous measurements of these instruments. However, the addition of the disc-averaged CIRS observations, instead of confirming the consistency between the different datasets, reveals discrepancies between one of the CIRS disc-averaged set of observations and PACS measurements. This raises new questions regarding the possibility of latitudinal variations of H 2 O, which could be triggered by seasonal changes of the meridional circulation. As it has already been shown for nitriles and hydrocarbons, this circulation could potentially impact the latitudinal distribution of H 2 O through the subsidence or upwelling of air rich in H 2 O. The possible influence of spatial/time variations of the OH/H 2 O input flux in Titan's atmosphere is also discussed. The analysis of more observations will be needed in future work to address the questions arising from this work and to improve the understanding of the sources of H 2 O in Titan's atmosphere.

The DREAMS Experiment Onboard the Schiaparelli Module of the ExoMars 2016 Mission: Design, Performances and Expected Results

SPACE SCIENCE REVIEWS 214:6 (2018) UNSP 103

Authors:

F Esposito, S Debei, C Bettanini, C Molfese, I Arruego Rodriguez, G Colombatti, A-M Harri, F Montmessin, C Wilson, A Aboudan, P Schipani, L Marty, FJ Alvarez, V Apestigue, G Bellucci, J-J Berthelier, JR Brucato, SB Calcutt, S Chiodini, F Cortecchia, F Cozzolino, F Cucciarre, N Deniskina, G Deprez, G Di Achille, F Ferri, F Forget, G Franzese, E Friso, M Genzer, R Hassen-Kodja, H Haukka, M Hieta, JJ Jimenez, J-L Josset, H Kahanpaa, O Karatekin, G Landis, L Lapauw, R Lorenz, J Martinez-Oter, V Mennella, D Moehlmann, D Moirin, R Molinaro, T Nikkanen, E Palomba, MR Patel, J-P Pommereau, CI Popa, S Rafkin, P Rannou, NO Renno, J Rivas, W Schmidt, E Segato, S Silvestro, A Spiga, D Toledo, R Trautner, F Valero, L Vazquez, F Vivat, O Witasse, M Yela, R Mugnuolo, E Marchetti, S Pirrotta

Detectability of biosignatures in anoxic atmospheres with the James Webb Space Telescope: a TRAPPIST-1e case study

Astronomical Journal American Astronomical Society 156:3 (2018) 114

Authors:

J Krissansen-Totton, Ryan Garland, Patrick Irwin, D Catling

Abstract:

The James Webb Space Telescope (JWST) may be capable of finding biogenic gases in the atmospheres of habitable exoplanets around low-mass stars. Considerable attention has been given to the detectability of biogenic oxygen, which could be found using an ozone proxy, but ozone detection with JWST will be extremely challenging, even for the most favorable targets. Here, we investigate the detectability of biosignatures in anoxic atmospheres analogous to those that likely existed on the early Earth. Arguably, such anoxic biosignatures could be more prevalent than oxygen biosignatures if life exists elsewhere. Specifically, we simulate JWST retrievals of TRAPPIST-1e to determine whether the methane plus carbon dioxide disequilibrium biosignature pair is detectable in transit transmission. We find that ~10 transits using the Near InfraRed Spectrograph prism instrument may be sufficient to detect carbon dioxide and constrain methane abundances sufficiently well to rule out known, nonbiological CH4 production scenarios to ~90% confidence. Furthermore, it might be possible to put an upper limit on carbon monoxide abundances that would help rule out nonbiological methane-production scenarios, assuming the surface biosphere would efficiently draw down atmospheric CO. Our results are relatively insensitive to high-altitude clouds and instrument noise floor assumptions, although stellar heterogeneity and variability may present challenges.

The DREAMS experiment onboard the Schiaparelli module of the ExoMars 2016 mission: Design, performances and expected results

Space Science Reviews Springer Verlag 214:103 (2018)

Authors:

F Esposito, S Debei, C Bettanini, C Molfese, I Arruego Rodriguez, G Colombatti, A-M Harri, F Montmessin, Colin Wilson, A Aboudan, P Schipani, L Marty, FJ Alvarez, V Apestigue, G Bellucci, J-J Berthelier, Simon Calcutt, S Chiodini, F Cortecchia, F Cozzolino, F Cucciarre, N Deniskina, G Deprez, G Di Achille, F Ferri, F Forget, G Franzese, E Friso, M Genzer, R Hassen-Kodja, H Haukka, M Hieta, JJ Jimenez, J-L Josset, H Kahanpaa, O Karatekin, G Landis, L Lapauw, R Lorenz, J Martinez-Oter, V Mennella, D Moehlmann, D Moirin, R Molinaro, T Nikkanen, E Palomba, J-P Pommereau, CI Popa

Abstract:

The first of the two missions foreseen in the ExoMars program was successfully launched on 14th March 2016. It included the Trace Gas Orbiter and the Schiaparelli Entry descent and landing Demonstrator Module. Schiaparelli hosted the DREAMS instrument suite that was the only scientific payload designed to operate after the touchdown. DREAMS is a meteorological station with the capability of measuring the electric properties of the Martian atmosphere. It was a completely autonomous instrument, relying on its internal battery for the power supply. Even with low resources (mass, energy), DREAMS would be able to perform novel measurements on Mars (atmospheric electric field) and further our understanding of the Martian environment, including the dust cycle. DREAMS sensors were designed to operate in a very dusty environment, because the experiment was designed to operate on Mars during the dust storm season (October 2016 in Meridiani Planum). Unfortunately, the Schiaparelli module failed part of the descent and the landing and crashed onto the surface of Mars. Nevertheless, several seconds before the crash, the module central computer switched the DREAMS instrument on, and sent back housekeeping data indicating that the DREAMS sensors were performing nominally. This article describes the instrument in terms of scientific goals, design, working principle and performances, as well as the results of calibration and field tests. The spare model is mature and available to fly in a future mission.

Future of Venus Research and Exploration

SPACE SCIENCE REVIEWS 214:5 (2018) UNSP 89

Authors:

Lori S Glaze, Colin F Wilson, Liudmila V Zasova, Masato Nakamura, Sanjay Limaye