Your search keyword '"González-Galindo, Francisco"' showing total 11 results

1. 3D Global climate model of an exo-Venus: a modern Venus-like atmosphere for the nearby super-Earth LP 890-9 c

Author

Quirino, Diogo, Gilli, Gabriella, Kaltenegger, Lisa, Navarro, Thomas, Fauchez, Thomas J., Turbet, Martin, Leconte, Jérémy, Lebonnois, Sébastien, González-Galindo, Francisco, Quirino, Diogo, Gilli, Gabriella, Kaltenegger, Lisa, Navarro, Thomas, Fauchez, Thomas J., Turbet, Martin, Leconte, Jérémy, Lebonnois, Sébastien, and González-Galindo, Francisco

Abstract

The recently discovered super-Earth LP 890-9 c is an intriguing target for atmospheric studies as it transits a nearby, low-activity late-type M-dwarf star at the inner edge of the Habitable Zone. Its position at the runaway greenhouse limit makes it a natural laboratory to study the climate evolution of hot rocky planets. We present the first 3D-GCM exo-Venus model for a modern Venus-like atmosphere (92 bar surface pressure, realistic composition, H$_2$SO$_4$ radiatively-active clouds), applied to the tidally-locked LP 890-9c to inform observations by JWST and future instruments. If LP 890-9 c has developed into a modern exo-Venus, then the modelled temperatures suggest that H$_2$SO$_4$ clouds are possible even in the substellar region. Like on modern Venus, clouds on LP 890-9 c would create a flat spectrum. The strongest CO$_2$ bands in transmission predicted by our model for LP 890-9 c are about 10 ppm, challenging detection, given JWST estimated noise floor. Estimated phase curve amplitudes are 0.9 and 2.4 ppm for continuum and CO$_2$ bands, respectively. While pointing out the challenge to characterise modern exo-Venus analogues, these results provide new insights for JWST proposals and highlight the influence of clouds in the spectrum of hot rocky exoplanet spectra., Comment: 6 pages, 4 figures, MNRAS letter

Published

2023

2. Cooling of the Martian thermosphere by CO$_2$ radiation and gravity waves: An intercomparison study with two general circulation models

Author

Medvedev, Alexander S., González-Galindo, Francisco, Yiğit, Erdal, Feofilov, Artem G., Forget, François, Hartogh, Paul, Medvedev, Alexander S., González-Galindo, Francisco, Yiğit, Erdal, Feofilov, Artem G., Forget, François, and Hartogh, Paul

Abstract

Observations show that the lower thermosphere of Mars ($\sim$100--140 km) is up to 40 K colder than the current general circulation models (GCMs) can reproduce. Possible candidates for physical processes missing in the models are larger abundances of atomic oxygen facilitating stronger CO$_2$ radiative cooling, and thermal effects of gravity waves. Using two state-of-the-art Martian GCMs, the Laboratoire de M\'et\'eorologie Dynamique and Max Planck Institute models that self-consistently cover the atmosphere from the surface to the thermosphere, these physical mechanisms are investigated. Simulations demonstrate that the CO$_2$ radiative cooling with a sufficiently large atomic oxygen abundance, and the gravity wave-induced cooling can alone result in up to 40 K colder temperature in the lower thermosphere. Accounting for both mechanisms produce stronger cooling at high latitudes. However, radiative cooling effects peak above the mesopause, while gravity wave cooling rates continuously increase with height. Although both mechanisms act simultaneously, these peculiarities could help to further quantify their relative contributions from future observations., Comment: Accepted for publication in Journal of Geophysical Research - Planets

Published

2015

3. Cooling of the Martian thermosphere by CO$_2$ radiation and gravity waves: An intercomparison study with two general circulation models

Author

Medvedev, Alexander S., González-Galindo, Francisco, Yiğit, Erdal, Feofilov, Artem G., Forget, François, Hartogh, Paul, Medvedev, Alexander S., González-Galindo, Francisco, Yiğit, Erdal, Feofilov, Artem G., Forget, François, and Hartogh, Paul

Abstract

Observations show that the lower thermosphere of Mars ($\sim$100--140 km) is up to 40 K colder than the current general circulation models (GCMs) can reproduce. Possible candidates for physical processes missing in the models are larger abundances of atomic oxygen facilitating stronger CO$_2$ radiative cooling, and thermal effects of gravity waves. Using two state-of-the-art Martian GCMs, the Laboratoire de M\'et\'eorologie Dynamique and Max Planck Institute models that self-consistently cover the atmosphere from the surface to the thermosphere, these physical mechanisms are investigated. Simulations demonstrate that the CO$_2$ radiative cooling with a sufficiently large atomic oxygen abundance, and the gravity wave-induced cooling can alone result in up to 40 K colder temperature in the lower thermosphere. Accounting for both mechanisms produce stronger cooling at high latitudes. However, radiative cooling effects peak above the mesopause, while gravity wave cooling rates continuously increase with height. Although both mechanisms act simultaneously, these peculiarities could help to further quantify their relative contributions from future observations., Comment: Accepted for publication in Journal of Geophysical Research - Planets

Published

2015

4. Investigations of the Mars Upper Atmosphere with ExoMars Trace Gas Orbiter

Author

López-Valverde, Miguel A., Gerard, Jean-Claude, González-Galindo, Francisco, Vandaele, Ann-Carine, Thomas, Ian, Korablev, Oleg, Ignatiev, Nikolai, Fedorova, Anna, Montmessin, Franck, Määttänen, Anni, Guilbon, Sabrina, Lefevre, Franck, Patel, Manish R., Jiménez-Monferrer, Sergio, García-Comas, Maya, Cardesin, Alejandro, Wilson, Colin F., Clancy, R. T., Kleinböhl, Armin, McCleese, Daniel J., Kass, David M., Schneider, Nick M., Chaffin, Michael S., López-Moreno, José Juan, Rodríguez, Julio, López-Valverde, Miguel A., Gerard, Jean-Claude, González-Galindo, Francisco, Vandaele, Ann-Carine, Thomas, Ian, Korablev, Oleg, Ignatiev, Nikolai, Fedorova, Anna, Montmessin, Franck, Määttänen, Anni, Guilbon, Sabrina, Lefevre, Franck, Patel, Manish R., Jiménez-Monferrer, Sergio, García-Comas, Maya, Cardesin, Alejandro, Wilson, Colin F., Clancy, R. T., Kleinböhl, Armin, McCleese, Daniel J., Kass, David M., Schneider, Nick M., Chaffin, Michael S., López-Moreno, José Juan, and Rodríguez, Julio

Abstract

The Martian mesosphere and thermosphere, the region above about 60 km, is not the primary target of the ExoMars 2016 mission but its Trace Gas Orbiter (TGO) can explore it and address many interesting issues, either in-situ during the aerobraking period or remotely during the regular mission. In the aerobraking phase TGO peeks into thermospheric densities and temperatures, in a broad range of latitudes and during a long continuous period. TGO carries two instruments designed for the detection of trace species, NOMAD and ACS, which will use the solar occultation technique. Their regular sounding at the terminator up to very high altitudes in many different molecular bands will represent the first time that an extensive and precise dataset of densities and hopefully temperatures are obtained at those altitudes and local times on Mars. But there are additional capabilities in TGO for studying the upper atmosphere of Mars, and we review them briefly. Our simulations suggest that airglow emissions from the UV to the IR might be observed outside the terminator. If eventually confirmed from orbit, they would supply new information about atmospheric dynamics and variability. However, their optimal exploitation requires a special spacecraft pointing, currently not considered in the regular operations but feasible in our opinion. We discuss the synergy between the TGO instruments, specially the wide spectral range achieved by combining them. We also encourage coordinated operations with other Mars-observing missions capable of supplying simultaneous measurements of its upper atmosphere.

5. The Latest Mars Climate Database (MCD v5.1)

Author

Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizée, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Montmessin, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, Read, Peter, Huot, Jean-Paul, Desjean, Marie-Christine, MCD/GCM, Development Team, Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizée, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Montmessin, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, Read, Peter, Huot, Jean-Paul, Desjean, Marie-Christine, and MCD/GCM, Development Team

Abstract

For many years, several teams around the world have developed GCMs (General Circulation Model or Global Climate Model) to simulate the environment on Mars. The GCM developed at the Laboratoire de Météorologie Dynamique in 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 and CNES is currently used for many applications. Its outputs have also regularly been 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 150 teams around the world. Following the recent improvements in the GCM, a new series of reference simulations have been run and compiled into a new version (version5.1) of the Mars Climate Database, released in the first half of 2014. To summarize, MCD v5.1 provides: - Climatologies over a series of dust scenarios: standard 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 differ from those of previous versions of the MCD (version 4.x) as they have been derived from home-made, instrument-derived (TES, THEMIS, MCS, MERs), dust climatology of the last 8 Martian 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

6. Modeling the martian atmosphere with the LMD global climate model

Author

Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizee, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, MCD/GCM team, Millour, E., Forget, F., Spiga, A., Montabone, L, Colaitis, A., Navarro, T., Lebonnois, S., Madeleine, J.-B., Meslin, P.-Y., Chauffray, J.-Y., Lefèvre, F., Montmessin, F., González-Galindo, F., Lopez-Valverde, A., Gilli, G., Lewis, S. R., Read, P. L., Desjean, M.-C., Huot, J.-P., Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizee, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, MCD/GCM team, Millour, E., Forget, F., Spiga, A., Montabone, L, Colaitis, A., Navarro, T., Lebonnois, S., Madeleine, J.-B., Meslin, P.-Y., Chauffray, J.-Y., Lefèvre, F., Montmessin, F., González-Galindo, F., Lopez-Valverde, A., Gilli, G., Lewis, S. R., Read, P. L., Desjean, M.-C., and Huot, J.-P.

Abstract

Our Global Climate Model (GCM) of the Martian atmosphere is the result of twenty years of ongoing collaboration between our teams and has matured to the point of enabling to study the main cycles (dust, CO2, water) of present-day and past Martian climates. At the 2014 scientific assembly, we will report on the latest developments and improvements of our GCM, and also present the latest version of the Mars Climate Database (version 5.1) that is derived from GCM outputs, along with comparisons with available measurements (from TES, MCS, Viking, Phoenix, Curiosity, etc.).

7. Retrieval of Martian atmospheric CO vertical profiles from NOMAD observations during the 1st year of TGO operations

Author

Modak, Ashimananda, López‐Valverde, Miguel Angel, Brines, Adrian, Stolzenbach, Aurélien, Funke, Bernd, González‐Galindo, Francisco, Hill, Brittany, Aoki, Shohei, Thomas, Ian, Liuzzi, Giuliano, Villanueva, Gerónimo, Erwin, Justin, Lopez Moreno, José Juan, Yoshida, Nao, Grabowski, Udo, Forget, Francois, Daerden, Frank, Ristic, Bojan, Bellucci, Giancarlo, Patel, Manish, Trompet, Loic, Vandaele, Ann‐Carine, Modak, Ashimananda, López‐Valverde, Miguel Angel, Brines, Adrian, Stolzenbach, Aurélien, Funke, Bernd, González‐Galindo, Francisco, Hill, Brittany, Aoki, Shohei, Thomas, Ian, Liuzzi, Giuliano, Villanueva, Gerónimo, Erwin, Justin, Lopez Moreno, José Juan, Yoshida, Nao, Grabowski, Udo, Forget, Francois, Daerden, Frank, Ristic, Bojan, Bellucci, Giancarlo, Patel, Manish, Trompet, Loic, and Vandaele, Ann‐Carine

Abstract

We present CO density profiles up to about 100 km in the Martian atmosphere obtained for the first time from retrievals of solar occultation measurements by the Nadir and Occultation for Mars Discovery (NOMAD) onboard ExoMars Trace Gas Orbiter (TGO). CO is an important trace gas on Mars, as it is controlled by CO2 photolysis, chemical reaction with the OH radicals, and the global dynamics. However, the measurements of CO vertical profiles have been elusive until the arrival of TGO. We show how the NOMAD CO variations describe very well the Mars general circulation. We observe a depletion of CO in the upper troposphere and mesosphere during the peak period, LS = 190°–200°, more pronounced over the northern latitudes, confirming a similar result recently reported by ACS onboard TGO. However, in the lower troposphere around 20 km, and at least at high latitudes of the S. hemisphere, NOMAD CO mixing ratios increase over 1500 ppmv during the GDS (Global Dust Storm) onset. This might be related to the downwelling branch of the Hadley circulation. A subsequent increase in tropospheric CO is observed during the decay phase of the GDS around LS = 210° − −250° when the dust loading is still high. This could be associated with a reduction in the amount of OH radicals in the lower atmosphere due to lack of solar insolation. Once the GDS is over, CO steadily decreases globally during the southern summer season. A couple of distinct CO patterns associated with the Summer solstice and equinox circulation are reported and discussed.

8. The Latest Mars Climate Database (MCD v5.1)

Author

Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizée, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Montmessin, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, Read, Peter, Huot, Jean-Paul, Desjean, Marie-Christine, MCD/GCM, Development Team, Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizée, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Montmessin, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, Read, Peter, Huot, Jean-Paul, Desjean, Marie-Christine, and MCD/GCM, Development Team

Abstract

For many years, several teams around the world have developed GCMs (General Circulation Model or Global Climate Model) to simulate the environment on Mars. The GCM developed at the Laboratoire de Météorologie Dynamique in 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 and CNES is currently used for many applications. Its outputs have also regularly been 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 150 teams around the world. Following the recent improvements in the GCM, a new series of reference simulations have been run and compiled into a new version (version5.1) of the Mars Climate Database, released in the first half of 2014. To summarize, MCD v5.1 provides: - Climatologies over a series of dust scenarios: standard 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 differ from those of previous versions of the MCD (version 4.x) as they have been derived from home-made, instrument-derived (TES, THEMIS, MCS, MERs), dust climatology of the last 8 Martian 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

9. Modeling the martian atmosphere with the LMD global climate model

Author

Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizee, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, MCD/GCM team, Millour, E., Forget, F., Spiga, A., Montabone, L, Colaitis, A., Navarro, T., Lebonnois, S., Madeleine, J.-B., Meslin, P.-Y., Chauffray, J.-Y., Lefèvre, F., Montmessin, F., González-Galindo, F., Lopez-Valverde, A., Gilli, G., Lewis, S. R., Read, P. L., Desjean, M.-C., Huot, J.-P., Millour, Ehouarn, Forget, Francois, Spiga, Aymeric, Navarro, Thomas, Madeleine, Jean-Baptiste, Pottier, Alizee, Montabone, Luca, Kerber, Laura, Lefèvre, Franck, Chaufray, Jean-Yves, López-Valverde, Miguel, González-Galindo, Francisco, Lewis, Stephen, MCD/GCM team, Millour, E., Forget, F., Spiga, A., Montabone, L, Colaitis, A., Navarro, T., Lebonnois, S., Madeleine, J.-B., Meslin, P.-Y., Chauffray, J.-Y., Lefèvre, F., Montmessin, F., González-Galindo, F., Lopez-Valverde, A., Gilli, G., Lewis, S. R., Read, P. L., Desjean, M.-C., and Huot, J.-P.

Abstract

Our Global Climate Model (GCM) of the Martian atmosphere is the result of twenty years of ongoing collaboration between our teams and has matured to the point of enabling to study the main cycles (dust, CO2, water) of present-day and past Martian climates. At the 2014 scientific assembly, we will report on the latest developments and improvements of our GCM, and also present the latest version of the Mars Climate Database (version 5.1) that is derived from GCM outputs, along with comparisons with available measurements (from TES, MCS, Viking, Phoenix, Curiosity, etc.).

10. Martian atmospheric temperature and density profiles during the 1st year of NOMAD/TGO solar occultation measurements

Author

López Valverde, Miguel‐Angel, Funke, Bernd, Brines, Adrian, Stolzenbach, Aurèlien, Modak, Ashimananda, Hill, Brittany, González‐Galindo, Francisco, Thomas, Ian, Trompet, Loic, Aoki, Shohei, Villanueva, Gerónimo, Liuzzi, Giuliano, Erwin, Justin, Grabowski, Udo, Forget, Francois, Lopez Moreno, José Juan, Rodriguez‐Gómez, Julio, Ristic, Bojan, Daerden, Frank, Bellucci, Giancarlo, Patel, Manish, Vandaele, Ann‐Carine, the NOMAD team, López Valverde, Miguel‐Angel, Funke, Bernd, Brines, Adrian, Stolzenbach, Aurèlien, Modak, Ashimananda, Hill, Brittany, González‐Galindo, Francisco, Thomas, Ian, Trompet, Loic, Aoki, Shohei, Villanueva, Gerónimo, Liuzzi, Giuliano, Erwin, Justin, Grabowski, Udo, Forget, Francois, Lopez Moreno, José Juan, Rodriguez‐Gómez, Julio, Ristic, Bojan, Daerden, Frank, Bellucci, Giancarlo, Patel, Manish, Vandaele, Ann‐Carine, and the NOMAD team

Abstract

We present vertical profiles of temperature and density from solar occultation (SO) observations by the “Nadir and Occultation for Mars Discovery” (NOMAD) spectrometer on board the Trace Gas Orbiter (TGO) during its first operational year, which covered the second half of Mars Year 34. We used calibrated transmittance spectra in 380 scans, and apply an in-house pre-processing to clean data systematics. Temperature and CO2 profiles up to about 90 km, with consistent hydrostatic adjustment, are obtained, after adapting an Earth-tested retrieval scheme to Mars conditions. Both pre-processing and retrieval are discussed to illustrate their performance and robustness. Our results reveal the large impact of the MY34 Global Dust Storm (GDS), which warmed the atmosphere at all altitudes. The large GDS aerosols opacity limited the sounding of tropospheric layers. The retrieved temperatures agree well with global climate models (GCM) at tropospheric altitudes, but NOMAD mesospheric temperatures are wavier and globally colder by 10 K in the perihelion season, particularly during the GDS and its decay phase. We observe a warm layer around 80 km during the Southern Spring, especially in the Northern Hemisphere morning terminator, associated to large thermal tides, significantly stronger than in the GCM. Cold mesospheric pockets, close to CO2 condensation temperatures, are more frequently observed than in the GCM. NOMAD CO2 densities show oscillations upon a seasonal trend that track well the latitudinal variations expected. Results uncertainties and suggestions to improve future data re-analysis are briefly discussed.

11. Investigations of the Mars Upper Atmosphere with ExoMars Trace Gas Orbiter

Author

López-Valverde, Miguel A., Gerard, Jean-Claude, González-Galindo, Francisco, Vandaele, Ann-Carine, Thomas, Ian, Korablev, Oleg, Ignatiev, Nikolai, Fedorova, Anna, Montmessin, Franck, Määttänen, Anni, Guilbon, Sabrina, Lefevre, Franck, Patel, Manish R., Jiménez-Monferrer, Sergio, García-Comas, Maya, Cardesin, Alejandro, Wilson, Colin F., Clancy, R. T., Kleinböhl, Armin, McCleese, Daniel J., Kass, David M., Schneider, Nick M., Chaffin, Michael S., López-Moreno, José Juan, Rodríguez, Julio, López-Valverde, Miguel A., Gerard, Jean-Claude, González-Galindo, Francisco, Vandaele, Ann-Carine, Thomas, Ian, Korablev, Oleg, Ignatiev, Nikolai, Fedorova, Anna, Montmessin, Franck, Määttänen, Anni, Guilbon, Sabrina, Lefevre, Franck, Patel, Manish R., Jiménez-Monferrer, Sergio, García-Comas, Maya, Cardesin, Alejandro, Wilson, Colin F., Clancy, R. T., Kleinböhl, Armin, McCleese, Daniel J., Kass, David M., Schneider, Nick M., Chaffin, Michael S., López-Moreno, José Juan, and Rodríguez, Julio

Abstract

The Martian mesosphere and thermosphere, the region above about 60 km, is not the primary target of the ExoMars 2016 mission but its Trace Gas Orbiter (TGO) can explore it and address many interesting issues, either in-situ during the aerobraking period or remotely during the regular mission. In the aerobraking phase TGO peeks into thermospheric densities and temperatures, in a broad range of latitudes and during a long continuous period. TGO carries two instruments designed for the detection of trace species, NOMAD and ACS, which will use the solar occultation technique. Their regular sounding at the terminator up to very high altitudes in many different molecular bands will represent the first time that an extensive and precise dataset of densities and hopefully temperatures are obtained at those altitudes and local times on Mars. But there are additional capabilities in TGO for studying the upper atmosphere of Mars, and we review them briefly. Our simulations suggest that airglow emissions from the UV to the IR might be observed outside the terminator. If eventually confirmed from orbit, they would supply new information about atmospheric dynamics and variability. However, their optimal exploitation requires a special spacecraft pointing, currently not considered in the regular operations but feasible in our opinion. We discuss the synergy between the TGO instruments, specially the wide spectral range achieved by combining them. We also encourage coordinated operations with other Mars-observing missions capable of supplying simultaneous measurements of its upper atmosphere.