22 research outputs found
Assimilation of Temperatures and Column Dust Opacities Measured by ExoMars TGO-ACS-TIRVIM During the MY34 Global Dust Storm
Funding Information: ExoMars is a space mission of ESA and Roscosmos. The Atmospheric Chemistry Suite (ACS) experiment is led by IKI, the Space Research Institute in Moscow, Russia, assisted by LATMOS in France. This work, exploiting ACS/TIRVIM data, acknowledges funding by the CNES. The science operations of ACS are funded by Roscosmos and ESA. The ACS/TIRVIM team at IKI acknowledges the subsidy of the Ministry of Science and Higher Education of Russia. The authors acknowledge Sandrine Guerlet and the ACS/TGO team for supplying the data and the data center ESPRI/IPSL for their help in accessing the data. R. M. B. Young acknowledges funding from the UAE University grants G00003322 and G00003407. Supercomputing resources were provided by the UAE University High Performance Computing, with technical support from Anil Thomas and Asma Alneyadi, and at LMD by the IPSL mesocentre. The authors thank Luca Montabone for access to processed versions of Mars Climate Sounder temperature and dust observations, and Thomas Navarro and Claus Gebhardt for useful discussions.Peer reviewe
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Water Vapor Vertical Profiles on Mars in Dust Storms Observed by TGO/NOMAD
It has been suggested that dust storms efficiently transport water vapor from the near‐surface to the middle atmosphere on Mars. Knowledge of the water vapor vertical profile during dust storms is important to understand water escape. During Martian Year 34, two dust storms occurred on Mars: a global dust storm (June to mid‐September 2018) and a regional storm (January 2019). Here we present water vapor vertical profiles in the periods of the two dust storms (Ls = 162–260° and Ls = 298–345°) from the solar occultation measurements by Nadir and Occultation for Mars Discovery (NOMAD) onboard ExoMars Trace Gas Orbiter (TGO). We show a significant increase of water vapor abundance in the middle atmosphere (40–100 km) during the global dust storm. The water enhancement rapidly occurs following the onset of the storm (Ls~190°) and has a peak at the most active period (Ls~200°). Water vapor reaches very high altitudes (up to 100 km) with a volume mixing ratio of ~50 ppm. The water vapor abundance in the middle atmosphere shows high values consistently at 60°S‐60°N at the growth phase of the dust storm (Ls = 195°–220°), and peaks at latitudes greater than 60°S at the decay phase (Ls = 220°–260°). This is explained by the seasonal change of meridional circulation: from equinoctial Hadley circulation (two cells) to the solstitial one (a single pole‐to‐pole cell). We also find a conspicuous increase of water vapor density in the middle atmosphere at the period of the regional dust storm (Ls = 322–327°), in particular at latitudes greater than 60°S
Water vapor near Venus cloud tops from VIRTIS-H/Venus express observations 2006–2011
International audienc
Geologic interpretation of the near-infrared images of area SW of Beta Regio taken by the Venus Monitoring Camera
We analyze night-time near-infrared (NIR) images of Beta-Phoebe region obtained with the 1-μm channel of the
Venus Monitoring Camera (VMC) onboard Venus Express. Comparisons with the results of the Magellan radar
survey and the model NIR images show that the night-time VMC images provide reliable information on spatial
variations of the NIR surface emission.
Here we consider if tessera terrain has the different NIR emissivity (and thus mineralogical composition) in com-
parison to the surrounding basaltic plains. This is done through the study of an area SW of Beta Regio where
there is a massif of tessera terrain, Chimon-mana Tessera, surrounded by supposedly basaltic plains. Our analysis
showed that 1-μm emissivity of tessera surface material is by 15 – 35 % lower than that of relatively fresh suppos-
edly basaltic lavas of plains and volcanic edifices. This is consistent with hypothesis that the tessera material is not
basaltic, maybe felsic, that is in agreement with the results of analyses of VEX VIRTIS and Galileo NIMS data. If
the felsic nature of venusian tesserae will be confirmed in further studies this may have important implications on
geochemical environments in early history of Venus.
We have found that the surface materials of plains in the study area are very variegated in their 1-μm emissivity,
which probably reflects variability of degree of their chemical weathering.
We have also found a possible decrease of the calculated emissivity at the top of Tuulikki Mons volcano which, if
real, may be due to different (more felsic?) composition of volcanic products on the volcano summit
Water vapor near the cloud tops of Venus from Venus Express/VIRTIS dayside data
International audienc
The martian atmosphere in the region of Hellas basin as observed by the planetary Fourier spectrometer (PFS-MEX)
This work presents a review of the observations acquired by the planetary Fourier spectrometer (PFS) in the region of the Hellas basin.
Taking advantage of the high spectral resolution of PFS, the vertical air temperature profile can be investigated with a previously unexperienced vertical resolution. Extensive comparisons with the expectations of EMCD 4.0 database highlight moderate discrepancies, strongly dependant on season. Namely, the morning observations acquired around Ls=45° show a series of temperature deficiencies with recurrent spatial patterns in different observations, correlated with the topography profile.
Trends of integrated dust loads as a function of the field of view (FOV) elevation are also described. Values are consistent with the retrieval hypothesis of a dust scale height equal to the gas one, even far from the season of main dust storms
Focal lengths of Venus Monitoring Camera from limb locations
The Venus Monitoring Camera (VMC) carried by European Space Agency’s Venus Express orbiter
(Svedhem et al., 2007) consists of four optical units, each with a separate filter casting an image on a
single CCD (Markiewicz et al., 2007a, 2007b). The desire to capture as much of the planet in a single
frame during the spacecraft’s 24 h, 0.84 eccentricity orbit led to optics with 181 field of view. Analysis of
Venus images obtained by the VMC indicated that the computed limb radius and altitude of haze layers
were somewhat inconsistent with prior knowledge and expectations. Possible causes include errors in
the knowledge of image geometry, misalignment of the optic axis from the pointing direction, and
optical distortion. These were explored and eliminated, leaving only deviations from the ground and pre-
solar damage estimate of the focal length lengths as the most likely reason. We use the location of
planet’s limb to estimate the focal length of each camera using images of the planet when the orbiter
was more than 20,000 km from planet center. The method relies on the limb radius to be constant at
least over a small range of solar zenith angles. We were able to achieve better estimates for the focal
lengths for all four cameras and also estimate small offsets to the boresight alignment.
An outcome of this analysis is the finding that the slant unit optical depth varies more rapidly with
solar zenith angle in the afternoon as compared to morning, with lowest values at local noon. A variation
of this level is also observed with latitude. Both are indicative of the presence of overlying haze above
the clouds, and the morning afternoon asymmetry suggests different photochemical processes in
destruction and production of the haze
Glory on Venus cloud tops and the unknown UV absorber
We report on the implications of the observations of the glory phenomenon made recently by Venus Express orbiter. Glory is an optical phenomenon that poses stringent constraints on the cloud properties. These observations thus enable us to constrain two properties of the particles at the cloud tops (about 70 km altitude) which are responsible for a large fraction of the solar energy absorbed by Venus. Firstly we obtain a very accurate estimate of the cloud particles size to be 1.2 lm with a very narrow size distribution. We also find that for the two observations presented here the clouds are homogenous, as far as
Venus cloud particles sizes are concerned, on scale of at least 1200 km. This is in contrast to previous estimates Atmosphere that were either local, from entry probes data, or averaged over space and time from polarization data.Secondly we find that the refractive index for the data discussed here is higher than that of sulfuric acid previously proposed for the clouds composition (Hansen, J.E., Hovenier, J.W. [1974]. J. Atmos. Sci. 31,1137–1160; Ragent, B. et al. [1985]. Adv. Space Res. 5, 85–115). Assuming that the species contributing to the increase of the refractive index is the same as the unknown UV absorber, we are able to constrain
the list of candidates. We investigated several possibilities and argue that either small ferric chloride (FeCl3) cores inside sulfuric acid particles or elemental sulfur coating their surface are good explanations
of the observation. Both ferric chloride and elemental sulfur have been suggested in the past as candidates for the as yet unknown UV absorber (Krasnopolsky, V.A. [2006]. Planet. Space Sci. 54, 1352–1359; Mills, F.P. et al. [2007]. In: Esposito, L.W., Stofan, E.R., Cravens, T.E. (Eds.), Exploring Venus as a Terrestrial Planet, vol. 176. AGU Monogr. Ser., Washington, DC, pp. 73–100)