Planetary atmosphere observation analysis

Seasonal exposure of carbon dioxide ice on the nucleus of comet 67P/Churyumov-Gerasimenko.

Science American Association for the Advancement of Science 354:6319 (2016) 1563-1566

Authors:

Gianrico Filacchione, Andrea Raponi, Fabrizio Capaccioni, Mauro Ciarniello, Federico Tosi, Maria T Capria, Maria C De Sanctis, Alessandra Migliorini, Giuseppe Piccioni, Priscilla Cerroni, Maria A Barucci, Sonia Fornasier, Bernard Schmitt, Eric Quirico, Stéphane Erard, Dominique Bockelee-Morvan, Cedric Leyrat, Gabriele Arnold, Vito Mennella, Eleonora Ammannito, Giancarlo Bellucci, Johannes Benkhoff, JP Bibring, Armando Blanco, Maria I Blecka, Robert Carlson, Ulm Carsenty, Luigi Colangeli, Michel Combes, Michael Combi, Jacques Crovisier, Pierre Drossart, Thérèse Encrenaz, Costanzo Federico, Uwe Fink, Sergio Fonti, Marcello Fulchignoni, Wing-Huen Ip, Patrick Irwin, Robert Jaumann, Ekkehard Kuehrt, Yves Langevin, Gianfranco Magni, Thomas McCord, Ljuba Moroz, Stefano Mottola, Ernesto Palomba, Ulrich Schade, Karin Stephan, Fredric Taylor

Abstract:

Carbon dioxide is one of the most abundant species in cometary nuclei, but due to its high volatility CO2 ice is generally only found beneath the surface. We report the infrared spectroscopic identification of a CO2 ice-rich surface area, located in the Anhur region of comet 67P/Churyumov-Gerasimenko. Spectral modeling shows that about 0.1% of the 80×60 m area is CO2 ice. This exposed ice was observed a short time after exiting from local winter; following the increased illumination, the CO2 ice completely disappeared over about three weeks. We estimate the mass of the sublimated CO2 ice and the depth of the surface eroded layer. The presence of CO2 ice is interpreted as the result of the extreme seasonal changes induced by the rotation and orbit of the comet.

Seismic coupling of short-period wind noise through Mars’ regolith for NASA’s InSight Lander

Space Science Reviews Springer 211:1-4 (2016) 485-500

Authors:

NA Teanby, J Stevanović, J Wookey, N Murdoch, J Hurley, R Myhill, Neil E Bowles, Simon B Calcutt, WT Pike

Abstract:

NASA’s InSight lander will deploy a tripod-mounted seismometer package onto the surface of Mars in late 2018. Mars is expected to have lower seismic activity than the Earth, so minimisation of environmental seismic noise will be critical for maximising observations of seismicity and scientific return from the mission. Therefore, the seismometers will be protected by a Wind and Thermal Shield (WTS), also mounted on a tripod. Nevertheless, wind impinging on the WTS will cause vibration noise, which will be transmitted to the seismometers through the regolith (soil). Here we use a 1:1-scale model of the seismometer and WTS, combined with field testing at two analogue sites in Iceland, to determine the transfer coefficient between the two tripods and quantify the proportion of WTS vibration noise transmitted through the regolith to the seismometers. The analogue sites had median grain sizes in the range 0.3–1.0 mm, surface densities of 1.3–1.8gcm−3, and an effective regolith Young’s modulus of 2.5−1.4+1.9MPa. At a seismic frequency of 5 Hz the measured transfer coefficients had values of 0.02–0.04 for the vertical component and 0.01–0.02 for the horizontal component. These values are 3–6 times lower than predicted by elastic theory and imply that at short periods the regolith displays significant anelastic behaviour. This will result in reduced short-period wind noise and increased signal-to-noise. We predict the noise induced by turbulent aerodynamic lift on the WTS at 5 Hz to be ∼2×10−10ms−2Hz−1/2 with a factor of 10 uncertainty. This is at least an order of magnitude lower than the InSight short-period seismometer noise floor of 10−8ms−2Hz−1/2.

Latitudinal variability in Jupiter's tropospheric disequilibrium species: GeH4, AsH3 and PH3

Icarus Elsevier 289 (2016) 254-269

Authors:

Rohini Giles, L Fletcher, Patrick G Irwin

Abstract:

Jupiter's tropospheric composition is studied using high resolution spatially-resolved 5-mm observation from the CRIRES instrument at the Very Large Telescope. The high resolving power (R=96,000) allows us to spectrally resolve the line shapes of individual molecular species in Jupiter's troposphere and, by aligning the slit north-south along Jupiter's central meridian, we are able to search for any latitudinal variability. Despite the high spectral resolution, we find that there are significant degeneracies between the cloud structure and aerosol scattering properties that complicate the retrievals of tropospheric gaseous abundances and limit conclusions on any belt-zone variability. However, we do find evidence for variability between the equatorial regions of the planet and the polar regions. Arsine (AsH3) and phosphine (PH3) both show an enhancement at high latitudes, while the abundance of germane (GeH4) remains approximately constant. These observations contrast with the theoretical predictions from Wang et al. (2016) and we discuss the possible explanations for this difierence.

A consistent retrieval analysis of 10 Hot Jupiters observed in transmission

(2016)

Authors:

Joanna K Barstow, Suzanne Aigrain, Patrick GJ Irwin, David K Sing

Jupiter's para-H2 distribution from SOFIA/FORCAST and Voyager/IRIS 17-37 μm spectroscopy

Icarus Elsevier 286 (2016) 223-240

Authors:

Leigh N Fletcher, Imke de Pater, William T Reach, Michael H Wong, Glenn S Orton, Patrick Irwin, Robert D Gehrz

Abstract:

Spatially resolved maps of Jupiter’s far-infrared 17-37 μm hydrogen-helium collision-induced spectrum were acquired by the FORCAST instrument on the Stratospheric Observatory for Infrared Astronomy (SOFIA) in May 2014. Spectral scans in two grisms covered the broad S(0) and S(1) absorption lines, in addition to contextual imaging in eight broad-band filters (5-37 μm) with spatial resolutions of 2-4”. The spectra were inverted to map the zonal-mean temperature and para-H2 distribution (fp, the fraction of the para spin isomer with respect to the ortho spin isomer) in Jupiter’s upper troposphere (the 100-700 mbar range). We compared these to a reanalysis of Voyager-1 and -2 IRIS spectra covering the same spectral range. Tropospheric temperature contrasts match those identified by Voyager in 1979, within the limits of temporal variability consistent with previous investigations. Para-H2 increases from equator to pole, with low- fp air at the equator representing sub-equilibrium conditions (i.e., less para-H2 than expected from thermal equilibration), and high- fp air and possible super-equilibrium at higher latitudes. In particular, we confirm the continued presence of a region of high-fp air at high northern latitudes discovered by Voyager/IRIS, and an asymmetry with generally higher fp in the north than in the south. Far-IR aerosol opacity is not required to fit the data, but cannot be completely ruled out. We note that existing collision-induced absorption databases lack opacity from (H2)2 dimers, leading to under-prediction of the absorption near the S(0) and S(1) peaks. There appears to be no spatial correlation between para-H2 and tropospheric ammonia, phosphine and cloud opacity derived from Voyager/IRIS at mid-infrared wavelengths (7-15 μm). We note, however, that para-H2 tracks the similar latitudinal distribution of aerosols within Jupiter’s upper tropospheric and stratospheric hazes observed in reflected sunlight, suggesting that catalysis of hydrogen equilibration within the hazes (and not the main clouds) may govern the equator-to-pole gradient, with conditions closer to equilibrium at higher latitudes. This gradient is superimposed onto smaller-scale variations associated with regional advection of para-H2 at the equator and poles.