Your search keyword '"González-Galindo, Francisco"' showing total 12 results

1. The Ionosphere of Mars After 20 Years of Mars Express Contributions.

Author

Peter, Kerstin, Sánchez-Cano, Beatriz, Němec, František, González-Galindo, Francisco, Kopf, Andrew J., Lester, Mark, Pätzold, Martin, Regan, Catherine E., and Holmström, Mats

Subjects

MARTIAN atmosphere, MARTIAN surface, IONOSPHERE, ATMOSPHERIC boundary layer, MARS (Planet), THERMOSPHERE, SOLAR atmosphere, SOLAR activity

Abstract

The Martian ionosphere originates from the ionization of the planetary neutral atmosphere by solar radiation. This conductive layer is embedded within the thermosphere and exosphere of Mars where it forms a highly variable interaction region with the solar wind. The Martian ionosphere has been continuously observed by the three plasma instruments MaRS, MARSIS and ASPERA-3 on Mars Express for the last 20 years (>10 Martian years). Those long-term observations laid a solid foundation for what we know today about the Martian ionosphere, and provided numerous opportunities for collaboration and coordinated observations with other missions. This review describes the most significant achievements of Mars Express for the ionosphere, such as the dynamics and structures of both day and nightside, its variability and couplings with the lower atmosphere, as well as the improvement of atmospheric and ionosphere modelling. Mars Express has also provided a better characterization of the role of several external and internal drivers in controlling the ionosphere, such as the Martian crustal magnetic fields, solar activity, seasons, dust lifting from the surface, and even the direct interaction of the Martian ionosphere with the coma of an Oort-cloud comet (C/2013 A1, Siding Spring). [ABSTRACT FROM AUTHOR]

Published

2024

2. Longitudinal Variations of Mars Thermosphere CO2, Ar, N2, and O Densities From MAVEN: Dependencies on Species Mass, Solar Flux, and Local Time.

Author

Forbes, Jeffrey M., Xiaohua Fang, Xiaoli Zhang, Benna, Mehdi, and González-Galindo, Francisco

Subjects

THERMOSPHERE, ROSSBY waves, STANDING waves, MARTIAN atmosphere, MARS (Planet), ATMOSPHERE

Abstract

Measurements of CO2, Ar, N2, and O densities between 150 and 200 km from the Mars Atmosphere and Volatile Evolution Neutral Gas and Ion Mass Spectrometer during February 2015 to February 2022 are analyzed to provide a comprehensive analysis of their longitudinal wavenumber k = 1, 2, and 3 components. Variations in density amplitudes (Ak) with solar flux are marginally detectable during this period. The Ak binned and averaged in latitude, local solar time and Ls are referenced to diurnal- and zonal-mean backgrounds in accord with how tides and stationary planetary waves (SPWs) are defined in theory and modeling. The resulting global Ak distributions are the interference patterns formed by superposition of diurnal tides, SPWs and/or semidiurnal tides; consequently, a simple dependence on species mass consistent with thermal expansion (diffusive equilibrium) that might exist for some individual wave components is obscured. Additionally, vertical winds likely contribute to deviations from diffusive equilibrium. Complementary analyses of the Mars Climate Database indicate that the major contributors to the Ak are DE2, SE1, DE1, and SPW1, 2, 3; support the absence of significant variability due to solar flux; and indicate a more well-defined sensitivity to species mass. The Ak and their phases (longitudes of maxima) for the whole data set are available as part of Supporting Information S1. [ABSTRACT FROM AUTHOR]

Published

2024

3. Martian Atmospheric Aerosols Composition and Distribution Retrievals During the First Martian Year of NOMAD/TGO Solar Occultation Measurements: 1. Methodology and Application to the MY 34 Global Dust Storm.

Author

Stolzenbach, Aurélien, López Valverde, Miguel‐Angel, Brines, Adrian, Modak, Ashimananda, Funke, Bernd, González‐Galindo, Francisco, Thomas, Ian, Liuzzi, Giuliano, Villanueva, Gerónimo, Luginin, Mikhail, Aoki, Shohei, Grabowski, Udo, Lopez Moreno, José Juan, Rodrìguez Gòmez, Julio, Wolff, Mike, Ristic, Bojan, Daerden, Frank, Bellucci, Giancarlo, Patel, Manish, and Vandaele, Ann‐Carine

Subjects

ATMOSPHERIC aerosols, DUST storms, ATMOSPHERIC composition, MARTIAN atmosphere, MARS (Planet), TRACE gases

Abstract

Since the beginning of the Trace Gas Orbiter (TGO) science operations in April 2018, its instrument "Nadir and Occultation for MArs Discovery" (NOMAD) supplies detailed observations of the IR spectrums of the Martian atmosphere. We developed a procedure that allows us to evaluate the composition and distribution's parameters of the atmospheric Martian aerosols. We use a retrieval program (RCP) in conjunction with a radiative forward model (KOPRA) to evaluate the vertical profile of aerosol extinction from NOMAD measurements. We then apply a model/data fitting strategy of the aerosol extinction. In this first article, we describe the method used to evaluate the parameters representing the Martian aerosol composition and size distribution. MY 34 GDS showed a peak intensity from LS 190° to 210°. During this period, the aerosol content rises multiple scale height, reaching altitudes up to 100 km. The lowermost altitude of aerosol's detection during NOMAD observation rises up to 30 km. Dust aerosols reff were observed to be close to 1 μm and its νeff lower than 0.2. Water ice aerosols reff were observed to be submicron with a νeff lower than 0.2. The vertical aerosol structure can be divided in two parts. The lower layers are represented by higher reff than the upper layers. The change between the lower and upper layers is very steep, taking only few kilometers. The decaying phase of the GDS, LS 210°–260°, shows a decrease in altitude of the aerosol content but no meaningful difference in the observed aerosol's size distribution parameters. Plain Language Summary: Mars' atmosphere is filled with dust and water ice particles carried by the winds. These aerosols affect the way sunlight is distributed in the atmosphere and on the surface, and this directly affects temperature. In addition, approximately every three Martian years, Mars experiences what is known as a "global dust storm." This type of dust storm covers the entire red planet in dust. It affects the temperature and water vapor content of the Martian atmosphere. Determining and assessing aerosol properties, number, size and mass during and after a global dust storm is of crucial importance to understanding its underlying mechanisms. Here, we develop an analysis scheme to study the size, nature, number and distribution of Martian aerosols. Our study confirms that, overall, dust and water ice particles are quite small, close to 1 μm or even smaller, and that a global dust storm affects the intensity of other storms that follow. Key Points: Retrieval of Martian aerosols key properties from NOMAD‐SO data during the MY 34 GDSMesospheric dust and water ice reff are mainly ∼1 μm and ≤0.5 μm respectively during the MY 34 GDS and its decay phaseDuring the MY 34 GDS, the effective variance shows a slight N/S asymmetry and values mainly ≤0.2 [ABSTRACT FROM AUTHOR]

Published

2023

4. Solar‐Synchronous Tides in Mars Thermosphere CO2, Ar, and N2 Densities From MAVEN.

Author

Forbes, Jeffrey M., Zhang, Xiaoli, Fang, Xiaohua, Benna, Mehdi, González‐Galindo, Francisco, Forget, Francois, and Millour, Ehouarn

Subjects

MARTIAN atmosphere, MARS (Planet), THERMOSPHERE, SOLAR oscillations, THERMAL expansion, MASS spectrometers

Abstract

Measurements of CO2, Ar and N2 densities from the Neutral Gas and Ion Mass Spectrometer on the Mars Atmosphere and Volatile Evolution Mission (MAVEN) between 150 and 200 km altitude during 2015–2022 are analyzed to reveal diurnal (DW1), semidiurnal (SW2) and terdiurnal (TW3) solar‐synchronous tides in Mars thermosphere. Multi‐year‐mean tidal perturbations on a diurnal‐ and zonal‐mean background, corrected for solar flux variations, are reported as a function of latitude (48°S–48°N), altitude and solar longitude (Ls). The DW1, SW2 and TW3 amplitudes at for example, 180 km altitude are of order 90%–120%, 15%–20%, and ≲10% for CO2 and Ar, and roughly 2/3 these values for N2, the latter presumably due to the difference in molecular weight from the other species. Through examination of vertical phase progressions, DW1 is concluded to be mainly excited in situ, but SW2 and TW3 contain significant contributions from tides propagating upward from lower altitudes. By analogy with studies for Earth's thermosphere, the DW1 amplitudes and phases are thought to reflect the combined influences of thermal expansion and vertical winds. Points of agreement and disagreement with DW1, SW2, and TW3 amplitudes and phases derived from the Mars Climate Database are noted and interpreted. Key Points: Global‐scale solar‐synchronous tides are derived from Mars Atmosphere and Volatile Evolution Mission/Neutral Gas and Ion Mass Spectrometer measurements of CO2, Ar, and N2 at Mars, 150–200 kmThe diurnal tide originates mainly in situ; semidiurnal and terdiurnal tides show evidence of upward propagation from belowPoints of agreement and disagreement with the Mars Climate Database are noted and interpreted [ABSTRACT FROM AUTHOR]

Published

2023

5. The martian mesosphere as revealed by CO2 cloud observations and General Circulation Modeling

Author

González-Galindo, Francisco, Määttänen, Anni, Forget, François, and Spiga, Aymeric

Subjects

*MESOSPHERE, *CARBON dioxide, *CLOUDS, *METEOROLOGICAL observations, *ATMOSPHERIC temperature, *MARS (Planet)

Abstract

Abstract: Different missions have observed mesospheric clouds on Mars in the last years. The presence of these clouds implies, among other conditions, mesospheric temperatures below CO2 condensation temperature. We use a General Circulation Model to study the mesospheric temperatures and compare the observed distribution of the mesospheric clouds and the predicted climatology of mesospheric temperatures. Although the model does not usually predict temperatures below condensation for daytime conditions, in some regions the predicted temperatures are close enough to condensation that perturbations caused by small scale processes could produce local excursions below condensation. The location and time of the lowest temperatures predicted by the GCM correspond to a first order with the two observed populations of mesospheric clouds: equatorial clouds observed before and after the Northern summer solstice, and mid-latitude clouds observed around the Northern winter solstice. For the equatorial clouds season, the model predicts temperatures close to condensation at the longitude, latitude, altitude and local time where they have been observed. We find that the diurnal migrating thermal tide and non-migrating tides are at the root of the spatial confinement of the equatorial clouds. For the mid-latitude clouds season, the temperatures predicted by the model at the location of the observed clouds is too high. Stereo observations by two different instruments allow for the determination of the zonal speed of these clouds producing a rare dataset of mesospheric winds. We compare the mesospheric zonal winds predicted by the model with these observations, finding a good agreement, although in some cases the observed variability exceeds that predicted by the model. [Copyright &y& Elsevier]

Published

2011

6. On the derivation of thermospheric temperatures from dayglow emissions on Mars.

Author

González-Galindo, Francisco, Jiménez-Monferrer, Sergio, López-Valverde, Miguel Ángel, García-Comas, Maya, and Forget, François

Subjects

*AIRGLOW, *MARS (Planet), *ZENITH distance, *MARTIAN atmosphere, *TEMPERATURE, *ALTITUDES

Abstract

The Cameron bands and the UV doublet are two of the most prominent emission systems in the UV in Mars dayside. Their altitude variation has been exploited in the past to derive thermospheric temperatures from measurements obtained by the Mariner 6, 7, and 9 missions, the SPICAM instrument on board Mars Express, and the IUVS instrument on board MAVEN. Here we identify and quantify possible biases in these temperature determinations. For this purpose, we use a global model able to simulate these two emission systems, and we compare the temperature derived from the simulated emission with that predicted by the model at the same location and time. We find that an exponential fit to the scale height of the UV doublet can be used to derive temperatures with an error less than 10 K at altitudes above about 170 km and for low and moderate values of the Solar Zenith Angle. The temperature derived from the Cameron bands is biased towards higher values due to the non-negligible contribution of CO to the emission. We find that, at 170 km, the difference between the temperature derived from the Cameron bands and the UV doublet can be related to the CO abundance. Our results have implications for previous temperature determinations from the Mariners, SPICAM/MEx and IUVS/MAVEN, some of them being biased by about 25 K. • Temperature derived from Cameron bands biased to high values due to CO contribution. • Temperature derived from UV doublet accurate in optically thin region, above ∼ 170 km. • The temperature difference between Cameron bands and UV doublet is linked to the CO abundance. [ABSTRACT FROM AUTHOR]

Published

2021

7. Tidal Wave-Driven Variability in the Mars Ionosphere-Thermosphere System.

Author

Thaller, Scott A., Andersson, Laila, Pilinski, Marcin Dominik, Thiemann, Edward, Withers, Paul, Elrod, Meredith, Fang, Xiaohua, González-Galindo, Francisco, Bougher, Stephen, and Jenkins, Geoffrey

Subjects

THERMOSPHERE, IONOSPHERE, MARTIAN atmosphere, MARS (Planet), TSUNAMIS, ELECTRON density, ALTITUDES

Abstract

In order to further evaluate the behavior of ionospheric variations at Mars, we investigate the Martian ionosphere-thermosphere (IT) perturbations associated with non-migrating thermal tides using over four years of Mars Atmosphere and Volatile Evolution (MAVEN) in situ measurements of the IT electron and neutral densities. The results are consistent with those of previous studies, namely strong correlation between the tidal perturbations in electron and neutral densities on the dayside at altitudes ~150–185 km, as expected from photochemical theory. In addition, there are intervals during which this correlation extends to higher altitudes, up to ~270 km, where diffusive transport of plasma plays a dominant role over photochemical processes. This is significant because at these altitudes the thermosphere and ionosphere are only weakly coupled through collisions. The identified non-migrating tidal wave variations in the neutral thermosphere are predominantly wave-1, wave-2, and wave-3. Wave-1 is often the dominant wavenumber for electron density tidal variations, particularly at high altitudes over crustal fields. The Mars Climate Database (MCD) neutral densities (below 300 km along the MAVEN orbit) shows clear tidal variations which are predominantly wave-2 and wave-3, and have similar wave amplitudes to those observed. [ABSTRACT FROM AUTHOR]

Published

2020

8. UV dayglow variability on Mars: simulation with a Global Climate Model and comparison with SPICAM/MEx data.

Author

González-Galindo, Francisco, Chauffray, Jean-Yves, Forget, Francois, García-Comas, Maya, Montmessin, Franck, and Jain, Sonal

Subjects

*ATMOSPHERIC models, *MARS (Planet)

Published

2018

9. The lower dayside ionosphere of Mars from 14 years of MaRS radio science observations.

Author

Peter, Kerstin, Pätzold, Martin, Molina-Cuberos, Gregorio J., González-Galindo, Francisco, Witasse, Olivier, Tellmann, Silvia, Häusler, Bernd, and Bird, Michael K.

Subjects

*SOLAR atmosphere, *ELECTRON distribution, *ELECTRON density, *CORONAL mass ejections, *EXCESS electrons, *MARS (Planet), *IONOSPHERE

Abstract

This work uses a subset of "quiet" MaRS ionospheric dayside observations (MaRS quiet , 2004–2017) and a 1-D photochemical model (IonA-2) to investigate the potential formation processes of the excess electron densities merged with the base of the main ionosphere (Mm). 42% of the investigated MaRS observations contain identified Mm, which occur in a large variety of shapes ranging from smoothly decreasing electron densities to peak structures below the base of M1. The Mm appear over the full range of accessible solar zenith angles (50° - 90°) and are found between approximately 70 and 110 km altitude. Their base is found on average deeper in the atmosphere than the base of the averaged undisturbed MaRS electron density profiles. This indicates a dependence of the Mm formation on energy sources that penetrate deep into the atmosphere. This is supported by a strong positive correlation with increasing solar activity when solar flares, coronal mass ejections, and enhanced short solar X-ray and Ly-α intensities are more common. No relationship is found between the Mm occurrence rate and the magnitude/inclination of the weak crustal crustal magnetic field in MaRS quiet. Investigations with the IonA-2 photochemical model for undisturbed and flare conditions show that the ionization of the local neutral atmosphere by solar X-ray radiation <2 nm provides a satisfying explanation for detected Mm features with smoothly decreasing electron densities below the M1 base in combination with moderate slopes of the lower Mm region α Mm and altitudes of the lower boundary h L , S. While sufficient ionization energy reaches the region of interest during flares, no Mm features with peaks below the M1 base occur in any of the model electron density profiles. This supports the conclusion that the subgroup of merged excess electron densities with peaks or intermediate features (Mi) below the M1 base must have an origin different from the sole variability of solar X-ray radiation during undisturbed and solar flare conditions. The size of the identified Mm makes an exclusive meteoric origin of the Mm peak structures unlikely. It is indicative from the IonA-2 model results that the general increase/decrease of solar X-ray <2 nm leads to a correlated response of the Mm region. The sporadic occurrence of the merged excess electron densities in the MaRS observations is therefore assumed to be a combination of observational (increased observation noise level compared to the available amount of X-ray radiation <2 nm, shift of the lower baseline by ionospheric deviations from radial symmetry) and environmental (e.g. variations in solar X-ray) factors. [ABSTRACT FROM AUTHOR]

Published

2021

10. CO2 retrievals in the Mars daylight thermosphere from its 4.3 μm limb emission measured by OMEGA/MEx.

Author

Jiménez-Monferrer, Sergio, López-Valverde, Miguel Ángel, Funke, Bernd, González-Galindo, Francisco, Piccialli, Arianna, García-Comas, Maya, López-Puertas, Manuel, Gondet, Brigitte, and Bibring, Jean-Pierre

Subjects

*THERMOSPHERE, *MARS (Planet), *DAYLIGHT, *HYDROSTATIC equilibrium, *ATMOSPHERIC composition, *THERMODYNAMIC equilibrium

Abstract

We present a non-local thermodynamic equilibrium retrieval scheme for atmospheric composition and its application to Mars CO 2 infrared limb emissions as measured by the OMEGA instrument on board Mars Express (MEx). These emissions are caused by CO 2 fluorescence of solar radiation, and thus the retrieval scheme accounts for non-LTE processes. We analyzed the dayside limb observations from a selection of three OMEGA orbits or data qubes. Before the retrieval was applied, we performed a radiometric calibration, cleaned the spectra (including clustering techniques) and generated radiance vertical profiles for each dataset. We also present information on the inversion set up, results on the retrieved CO 2 density profiles, as well as the temperature profiles derived from the CO 2 densities by assuming hydrostatic equilibrium. An extensive sensitivity study of the retrieval scheme was carried out, including its application to the OMEGA spectra taken at different MEx orbital configurations, to conclude on its performance and to offer recommendations for its systematic use with MEx datasets. The uncertainty due to the instrumental Gain calibration and that caused by the retrieval noise error itself are of large importance for the inversion, but a comparable component of the total error comes from the uncertainties of the temperature provided by the GCM. We demonstrated that, between 120 and 160 km, CO 2 profiles can be derived with a precision around 30% and a vertical resolution of about 15 km. • OMEGA limb observations with high spatial resolution • Non-LTE model for CO 2 limb observations in the Mars thermosphere • Retrieval scheme applied to three interesting OMEGA data qubes • CO 2 profiles can be derived with a precision of around 20% between 120 and 160 km. • A vertical resolution of around 15 km is possible with the OMEGA spatial resolution. [ABSTRACT FROM AUTHOR]

Published

2021

11. Mars Express science highlights and future plans.

Author

Titov, Dmitrij, Bibring, Jean-Pierre, Cardesin, Alejandro, Duxbury, Thomas, Forget, Francois, Giuranna, Marco, González-Galindo, Francisco, Holmström, Mats, Jaumann, Ralf, Määttänen, Anni, Martin, Patrick, Montmessin, Franck, Orosei, Roberto, Pätzold, Martin, Plaut, Jeffrey, and Team, Mexsgs

Subjects

*MARTIAN atmosphere, *MARS (Planet), *SOLAR activity, *SOLAR system, *SOLAR cycle, *SOLAR wind, *IONOSPHERE, *EROSION

Abstract

After 15 years in orbit Mars Express remains one of ESA's most scientifically productive Solar System missions whose publication record now exceeds 1200 papers. Characterization of the geological processes on a local-to-regional scale by HRSC, OMEGA and partner experiments on NASA spacecraft has allowed constraining land-forming processes in space and time. Recent results suggest episodic geological activity as well as the presence of large bodies of liquid water in several provinces (e.g. Eridania Planum, Terra Chimeria) in the early and middle Amazonian epoch and formation of vast sedimentary plains north of the Hellas basin. Mars Express observations and experimental teams provided essential contribution to the selection of the Mars-2020 landing sites. Recent discovery of subglacial liquid water underneath the Southern polar cap has proven that the mission science potential is still not exhausted. More than a decade-long record of the atmospheric parameters such as temperature, dust loading, water vapor and ozone abundance, water ice and CO2 clouds distribution, collected by SPICAM, PFS, OMEGA, HRSC and VMC together with subsequent modeling have provided key contributions to our understanding of the martian climate. Recent spectroscopic monitoring of the 2018 dust storm revealed dust properties, their spatial and temporal variations and atmospheric circulation.More than 10,000 crossings of the bow shock by Mars Express allowed ASPERA-3 to characterize complex behavior of the magnetic boundary topology as function of the solar EUV flux. Observations of the ion escape during complete solar cycle revealed important dependencies of the atmospheric erosion rate on parameters of the solar wind and EUV flux and established global energy balance between the solar wind and escaping ion flow. The observations showed that ion escape can be responsible for removal of about 10 mbar over the Mars history that implies existence of other more effective escape channels. The structure of the ionosphere sounded by the MARSIS radar and the MaRS radio science experiment was found to be significantly affected by the solar activity, the crustal magnetic field, as well as by the influx of meteorite and cometary dust. MARSIS and ASPERA-3 observations suggest that the sunlit ionosphere over the regions with strong crustal fields is denser and extends to higher altitudes as compared to the regions with no crustal anomalies. Several models of the upper atmosphere and plasma environment are being developed based on and in support of the collected experimental data. The models aim at creating user-friendly data base of plasma parameters similar to the Mars Climate Database that would be of great service to the planetary community.A significant recent achievement was the flawless transition to the "gyroless" attitude control and operations mode on the spacecraft, that would allow mitigating the onboard gyros aging and extending the mission lifetime. In November 2018 ESA's Science Programme Committee (SPC) confirmed the mission operations till the end of 2020 and notionally approved its extension till the end of 2022. The talk will give the Mars Express status, review the recent science highlights, and outline future plans focusing on synergistic science with TGO. [ABSTRACT FROM AUTHOR]

Published

2019

12. The Mars Climate Database (MCD version 5.3).

Author

Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Vals, Margaux, Zakharov, Vladimir, Montabone, Luca, Lefèvre, Franck, Montmessin, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, Read, Peter, Desjean, Marie-Christine, and Cipriani, Fabrice

Subjects

*ATMOSPHERIC carbon dioxide, *GENERAL circulation model, *ATMOSPHERIC temperature, *DUST storms, *MARS (Planet), *SURFACE pressure

Abstract

Our Global Circulation Model (GCM) simulates the atmospheric environment of Mars. It is developped at LMD (Laboratoire de Meteorologie Dynamique, Paris, France) in close collaboration with several teams in Europe (LATMOS, France, University of Oxford, The Open University, the Instituto de Astrofisica de Andalucia), and with the support of ESA (European Space Agency) and CNES (French Space Agency). GCM outputs are compiled to build a Mars Climate Database, a freely available tool useful for the scientific and engineering communities. The Mars Climate Database (MCD) has over the years been distributed to more than 350 teams around the world. The latest series of reference simulations have been compiled in version 5.3 of the MCD which was released in 2017.To summarize, MCD v5.3 provides:- Climatologies over a series of synthetic dust scenarios: standard (climatology) year, cold (ie: low dust), warm (ie: dusty atmosphere) and dust storm, all topped by various cases of Extreme UV solar inputs (low, mean or maximum). These scenarios have been derived from home-made, instrument-derived (TES, THEMIS, MCS, MERs), dust climatology of the last 8 Martian years. The MCD also provides simulation outputs (MY24-33) representative of these actual years.- Mean values and statistics of main meteorological variables (atmospheric temperature, density, pressure and winds), as well as surface pressure and temperature, CO2 ice cover, thermal and solar radiative fluxes, dust column opacity and mixing ratio, [H20] vapor and ice columns, concentrations of many species: [CO], [O2], [O], [N2], [H2], [O3],...- A high resolution mode which combines high resolution (32 pixel/degree) MOLA topography records and Viking Lander 1 pressure records with raw lower resolution GCM results to yield, within the restriction of the procedure, high resolution values of atmospheric variables.- The possibility to reconstruct realistic conditions by combining the provided climatology with additional large scale and small scale perturbations schemes.At EGU, we will report on the latest improvements in the Mars Climate Database, with comparisons with available measurements from orbit (e.g.: TES, MCS, TGO) and landers (Viking, Phoenix, Curiosity). [ABSTRACT FROM AUTHOR]

Published

2019