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1. A case study on the impact of interplanetary coronal mass ejection on the Martian O(1S) 557.7 nm dayglow emission using ExoMars TGO/NOMAD-UVIS observations: First Results

Author

Sharma, Aadarsh Raj, Ram, Lot, Suhaag, Harshaa, Patgiri, Dipjyoti, Soret, Lauriane, Gerard, Jean-Claude, Thomas, Ian R., Vandaele, Ann Carine, and Sarkhel, Sumanta

Subjects
Physics - Space Physics
Abstract

We report, for the first time, the impact of an interplanetary coronal mass ejection (ICME) on the recently discovered O($^1$S) 557.7 nm dayglow emission in the Martian atmosphere. Although there are only a few studies on the seasonal variation are available in the literature, the impact of ICME on 557.7 nm dayglow emission has not been investigated so far. Using the instruments aboard ExoMars-TGO and MAVEN spacecrafts, we show that the primary emission peak (75-80 km) remains unaffected during the ICME event compared to quiet-times. However, a noticeable enhancement has been observed in the brightness of secondary emission peak (110-120 km) and the upper altitude region (140-180 km). The enhancement is attributed to the increased solar electrons and X-ray fluxes, augmenting the electron-impact process and causing the enhancement in the brightness. These analyses have an implication to comprehend the role of intense solar transients like ICME on the Martian dayglow emissions.

Published
2024

2. The Io, Europa and Ganymede auroral footprints at Jupiter in the ultraviolet: positions and equatorial lead angles

Author

Hue, Vincent, Gladstone, Randy, Louis, Corentin K., Greathouse, Thomas K., Bonfond, Bertrand, Szalay, Jamey R., Moirano, Alessandro, Giles, Rohini S., Kammer, Joshua A., Imai, Masafumi, Mura, Alessandro, Versteeg, Maarten H., Clark, George, Gérard, Jean-Claude, Grodent, Denis C., Rabia, Jonas, Sulaiman, Ali H., Bolton, Scott J., and Connerney, John E. P.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Jupiter's satellite auroral footprints are a consequence of the interaction between the Jovian magnetic field with co-rotating iogenic plasma and the Galilean moons. The disturbances created near the moons propagate as Alfv\'en waves along the magnetic field lines. The position of the moons is therefore "Alfv\'enically" connected to their respective auroral footprint. The angular separation from the instantaneous magnetic footprint can be estimated by the so-called lead angle. That lead angle varies periodically as a function of orbital longitude, since the time for the Alfv\'en waves to reach the Jovian ionosphere varies accordingly. Using spectral images of the Main Alfv\'en Wing auroral spots collected by Juno-UVS during the first forty-three orbits, this work provides the first empirical model of the Io, Europa and Ganymede equatorial lead angles for the northern and southern hemispheres. Alfv\'en travel times between the three innermost Galilean moons to Jupiter's northern and southern hemispheres are estimated from the lead angle measurements. We also demonstrate the accuracy of the mapping from the Juno magnetic field reference model (JRM33) at the completion of the prime mission for M-shells extending to at least 15RJ . Finally, we shows how the added knowledge of the lead angle can improve the interpretation of the moon-induced decametric emissions., Comment: 20 pages, 8 figures, Accepted for publication in Journal of Geophysical Research: Space Physics on 20 April 2023

Published
2023
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3. Jupiter Science Enabled by ESA's Jupiter Icy Moons Explorer

Author

Fletcher, Leigh N., Cavalié, Thibault, Grassi, Davide, Hueso, Ricardo, Lara, Luisa M., Kaspi, Yohai, Galanti, Eli, Greathouse, Thomas K., Molyneux, Philippa M., Galand, Marina, Vallat, Claire, Witasse, Olivier, Lorente, Rosario, Hartogh, Paul, Poulet, François, Langevin, Yves, Palumbo, Pasquale, Gladstone, G. Randall, Retherford, Kurt D., Dougherty, Michele K., Wahlund, Jan-Erik, Barabash, Stas, Iess, Luciano, Bruzzone, Lorenzo, Hussmann, Hauke, Gurvits, Leonid I., Santolik, Ondřej, Kolmasova, Ivana, Fischer, Georg, Müller-Wodarg, Ingo, Piccioni, Giuseppe, Fouchet, Thierry, Gérard, Jean-Claude, Sánchez-Lavega, Agustin, Irwin, Patrick G. J., Grodent, Denis, Altieri, Francesca, Mura, Alessandro, Drossart, Pierre, Kammer, Josh, Giles, Rohini, Cazaux, Stéphanie, Jones, Geraint, Smirnova, Maria, Lellouch, Emmanuel, Medvedev, Alexander S., Moreno, Raphael, Rezac, Ladislav, Coustenis, Athena, and Costa, Marc

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

ESA's Jupiter Icy Moons Explorer (JUICE) will provide a detailed investigation of the Jovian system in the 2030s, combining a suite of state-of-the-art instruments with an orbital tour tailored to maximise observing opportunities. We review the Jupiter science enabled by the JUICE mission, building on the legacy of discoveries from the Galileo, Cassini, and Juno missions, alongside ground- and space-based observatories. We focus on remote sensing of the climate, meteorology, and chemistry of the atmosphere and auroras from the cloud-forming weather layer, through the upper troposphere, into the stratosphere and ionosphere. The Jupiter orbital tour provides a wealth of opportunities for atmospheric and auroral science: global perspectives with its near-equatorial and inclined phases, sampling all phase angles from dayside to nightside, and investigating phenomena evolving on timescales from minutes to months. The remote sensing payload spans far-UV spectroscopy (50-210 nm), visible imaging (340-1080 nm), visible/near-infrared spectroscopy (0.49-5.56 $\mu$m), and sub-millimetre sounding (near 530-625\,GHz and 1067-1275\,GHz). This is coupled to radio, stellar, and solar occultation opportunities to explore the atmosphere at high vertical resolution; and radio and plasma wave measurements of electric discharges in the Jovian atmosphere and auroras. Cross-disciplinary scientific investigations enable JUICE to explore coupling processes in giant planet atmospheres, to show how the atmosphere is connected to (i) the deep circulation and composition of the hydrogen-dominated interior; and (ii) to the currents and charged particle environments of the external magnetosphere. JUICE will provide a comprehensive characterisation of the atmosphere and auroras of this archetypal giant planet., Comment: 83 pages, 24 figures, accepted to Space Science Reviews special issue on ESA's JUICE mission

Published
2023
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5. Enhanced C$_2$H$_2$ absorption within Jupiter's southern auroral oval from Juno UVS observations

Author

Giles, Rohini S., Hue, Vincent, Greathouse, Thomas K., Gladstone, G. Randall, Kammer, Joshua A., Versteeg, Maarten H., Bonfond, Bertrand, Grodent, Denis G., Gérard, Jean-Claude, Sinclair, James A., Bolton, Scott J., and Levin, Steven M.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics
Abstract

Reflected sunlight observations from the Ultraviolet Spectrograph (UVS) on the Juno spacecraft were used to study the distribution of acetylene (C$_2$H$_2$) at Jupiter's south pole. We find that the shape of the C$_2$H$_2$ absorption feature varies significantly across the polar region, and this can be used to infer spatial variability in the C$_2$H$_2$ abundance. There is a localized region of enhanced C$_2$H$_2$ absorption which coincides with the location of Jupiter's southern polar aurora; the C$_2$H$_2$ abundance poleward of the auroral oval is a factor of 3 higher than adjacent quiescent, non-auroral longitudes. This builds on previous infrared studies which found enhanced C$_2$H$_2$ abundances within the northern auroral oval. This suggests that Jupiter's upper-atmosphere chemistry is being strongly influenced by the influx of charged auroral particles and demonstrates the necessity of developing ion-neutral photochemical models of Jupiter's polar regions., Comment: Accepted in JGR: Planets

Published
2023
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6. Detection of a bolide in Jupiter's atmosphere with Juno UVS

Author

Giles, Rohini S., Greathouse, Thomas K., Kammer, Joshua A., Gladstone, G. Randall, Bonfond, Bertrand, Hue, Vincent, Grodent, Denis C., Gérard, Jean-Claude, Versteeg, Maarten H., Bolton, Scott J., Connerney, John E. P., and Levin, Steven M.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The UVS instrument on the Juno mission recorded transient bright emission from a point source in Jupiter's atmosphere. The spectrum shows that the emission is consistent with a 9600-K blackbody located 225 km above the 1-bar level and the duration of the emission was between 17 ms and 150 s. These characteristics are consistent with a bolide in Jupiter's atmosphere. Based on the energy emitted, we estimate that the impactor had a mass of 250-5000 kg, which corresponds to a diameter of 1-4 m. By considering all observations made with Juno UVS over the first 27 perijoves of the mission, we estimate an impact flux rate of 24,000 per year for impactors with masses greater than 250-5000 kg., Comment: Accepted in GRL. 21 pages, 3 figures

Published
2021
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7. Possible Transient Luminous Events observed in Jupiter's upper atmosphere

Author

Giles, Rohini S., Greathouse, Thomas K., Bonfond, Bertrand, Gladstone, G. Randall, Kammer, Joshua A., Hue, Vincent, Grodent, Denis C., Gérard, Jean-Claude, Versteeg, Maarten H., Wong, Michael H., Bolton, Scott J., Connerney, John E. P., and Levin, Steven M.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

11 transient bright flashes were detected in Jupiter's atmosphere using the UVS instrument on the Juno spacecraft. These bright flashes are only observed in a single spin of the spacecraft and their brightness decays exponentially with time, with a duration of ~1.4 ms. The spectra are dominated by H2 Lyman band emission and based on the level of atmospheric absorption, we estimate a source altitude of 260 km above the 1-bar level. Based on these characteristics, we suggest that these are observations of Transient Luminous Events (TLEs) in Jupiter's upper atmosphere. In particular, we suggest that these are elves, sprites or sprite halos, three types of TLEs that occur in the Earth's upper atmosphere in response to tropospheric lightning strikes. This is supported by visible light imaging, which shows cloud features typical of lightning source regions at the locations of several of the bright flashes. TLEs have previously only been observed on Earth, although theoretical and experimental work has predicted that they should also be present on Jupiter., Comment: Accepted in JGR: Planets. 28 pages, 8 figures

Published
2020
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10. Mars Aurora: A Comparison of MAVEN/IUVS and EMM/EMUS Observations

Author

Schneider, Nicholas, primary, Lillis, Robert, additional, Jain, Sonal, additional, Deighan, Justin, additional, Cessna, Julianna, additional, Chaffin, Michael, additional, Hughes, Andrea, additional, Chirakkil, Krishnaprasad, additional, Gérard, Jean-Claude, additional, and Soret, Lauriane, additional

Published
2024
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11. The crucial role of HST during the NASA Juno mission: a 'Juno initiative'

Author

Grodent, Denis, Bonfond, Bertrand, Gérard, Jean-Claude, Gladstone, G. Randall, Nichols, Jonathan D., Clarke, John T., Bagenal, Fran, and Adriani, Alberto

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

In 2016, the NASA Juno spacecraft will initiate its one-year mission around Jupiter and become the first probe to explore the polar regions of Jupiter. The HST UV instruments (STIS and ACS) can greatly contribute to the success of the Juno mission by providing key complementary views of Jupiter's UV aurora from Earth orbit. Juno carries an ultraviolet Spectrograph (UVS) and an infrared spectral mapper (JIRAM) that will obtain high-resolution spectral images providing the auroral counterpart to Juno's in situ particles and fields measurements with the plasma JADE and JEDI particle detectors. The Juno mission will be the first opportunity to measure simultaneously the energetic particles at high latitude and the auroral emissions they produce. Following programmatic and technical limitations, the amount of UVS data transmitted to Earth will be severely restricted. Therefore, it is of extreme importance that HST captures as much additional information as possible on Jupiter's UV aurora during the one-year life of the Juno mission. This white paper is a plea for a "Juno initiative" that will ensure that a sufficient number of orbits is allocated to this unique solar system mission., Comment: Paper submitted to the Space Telescope Science Institute in response to the call for HST White Papers for Hubble's 2020 Vision

Published
2015

12. The EChO science case

Author

Tinetti, Giovanna, Drossart, Pierre, Eccleston, Paul, Hartogh, Paul, Isaak, Kate, Linder, Martin, Lovis, Christophe, Micela, Giusi, Ollivier, Marc, Puig, Ludovic, Ribas, Ignasi, Snellen, Ignas, Allard, Bruce Swinyard. France, Barstow, Joanna, Cho, James, Coustenis, Athena, Cockell, Charles, Correia, Alexandre, Decin, Leen, de Kok, Remco, Deroo, Pieter, Encrenaz, Therese, Forget, Francois, Glasse, Alistair, Griffith, Caitlin, Guillot, Tristan, Koskinen, Tommi, Lammer, Helmut, Leconte, Jeremy, Maxted, Pierre, Mueller-Wodarg, Ingo, Nelson, Richard, North, Chris, Pallé, Enric, Pagano, Isabella, Piccioni, Guseppe, Pinfield, David, Selsis, Franck, Sozzetti, Alessandro, Stixrude, Lars, Tennyson, Jonathan, Turrini, Diego, Beaulieu, Mariarosa Zapatero-Osorio. Jean-Philippe, Grodent, Denis, Guedel, Manuel, Luz, David, Nørgaard-Nielsen, Hans Ulrik, Ray, Tom, Rickman, Hans, Selig, Avri, Banaszkiewicz, Mark Swain. Marek, Barlow, Mike, Bowles, Neil, Branduardi-Raymont, Graziella, Foresto, Vincent Coudé du, Gerard, Jean-Claude, Gizon, Laurent, Hornstrup, Allan, Jarchow, Christopher, Kerschbaum, Franz, Kovacs, Géza, Lagage, Pierre-Olivier, Lim, Tanya, Lopez-Morales, Mercedes, Malaguti, Giuseppe, Pace, Emanuele, Pascale, Enzo, Vandenbussche, Bart, Wright, Gillian, Adriani, Gonzalo Ramos Zapata. Alberto, Azzollini, Ruymán, Balado, Ana, Bryson, Ian, Burston, Raymond, Colomé, Josep, Crook, Martin, Di Giorgio, Anna, Griffin, Matt, Hoogeveen, Ruud, Ottensamer, Roland, Irshad, Ranah, Middleton, Kevin, Morgante, Gianluca, Pinsard, Frederic, Rataj, Mirek, Reess, Jean-Michel, Savini, Giorgio, Schrader, Jan-Rutger, Stamper, Richard, Abe, Berend Winter. L., Abreu, M., Achilleos, N., Ade, P., Adybekian, V., Affer, L., Agnor, C., Agundez, M., Alard, C., Alcala, J., Prieto, C. Allende, Floriano, F. J. Alonso, Altieri, F., Iglesias, C. A. Alvarez, Amado, P., Andersen, A., Aylward, A., Baffa, C., Bakos, G., Ballerini, P., Banaszkiewicz, M., Barber, R. J., Barrado, D., Barton, E. J., Batista, V., Bellucci, G., Avilés, J. A. Belmonte, Berry, D., Bézard, B., Biondi, D., Błęcka, M., Boisse, I., Bonfond, B., Bordé, P., Börner, P., Bouy, H., Brown, L., Buchhave, L., Budaj, J., Bulgarelli, A., Burleigh, M., Cabral, A., Capria, M. T., Cassan, A., Cavarroc, C., Cecchi-Pestellini, C., Cerulli, R., Chadney, J., Chamberlain, S., Charnoz, S., Jessen, N. Christian, Ciaravella, A., Claret, A., Claudi, R., Coates, A., Cole, R., Collura, A., Cordier, D., Covino, E., Danielski, C., Damasso, M., Deeg, H. J., Delgado-Mena, E., Del Vecchio, C., Demangeon, O., De Sio, A., De Wit, J., Dobrijévic, M., Doel, P., Dominic, C., Dorfi, E., Eales, S., Eiroa, C., Contreras, M. Espinoza, Esposito, M., Eymet, V., Fabrizio, N., Fernández, M., Castella, B. Femenía, Figueira, P., Filacchione, G., Fletcher, L., Focardi, M., Fossey, S., Fouqué, P., Frith, J., Galand, M., Gambicorti, L., Gaulme, P., López, R. J. García, Garcia-Piquer, A., Gear, W., Gerard, J. -C., Gesa, L., Giani, E., Gianotti, F., Gillon, M., Giro, E., Giuranna, M., Gomez, H., Gomez-Leal, I., Hernandez, J. Gonzalez, Merino, B. González, Graczyk, R., Grassi, D., Guardia, J., Guio, P., Gustin, J., Hargrave, P., Haigh, J., Hébrard, E., Heiter, U., Heredero, R. L., Herrero, E., Hersant, F., Heyrovsky, D., Hollis, M., Hubert, B., Hueso, R., Israelian, G., Iro, N., Irwin, P., Jacquemoud, S., Jones, G., Jones, H., Justtanont, K., Kehoe, T., Kerschbaum, F., Kerins, E., Kervella, P., Kipping, D., Koskinen, T., Krupp, N., Lahav, O., Laken, B., Lanza, N., Lellouch, E., Leto, G., Goldaracena, J. Licandro, Lithgow-Bertelloni, C., Liu, S. J., Cicero, U. Lo, Lodieu, N., Lognonné, P., Lopez-Puertas, M., Lopez-Valverde, M. A., Rasmussen, I. Lundgaard, Luntzer, A., Machado, P., MacTavish, C., Maggio, A., Maillard, J. -P., Magnes, W., Maldonado, J., Mall, U., Marquette, J. -B., Mauskopf, P., Massi, F., Maurin, A. -S., Medvedev, A., Michaut, C., Miles-Paez, P., Montalto, M., Rodríguez, P. Montañés, Monteiro, M., Montes, D., Morais, H., Morales, J. C., Morales-Calderón, M., Morello, G., Martín, A. Moro, Moses, J., Bedon, A. Moya, Alcaino, F. Murgas, Oliva, E., Orton, G., Palla, F., Pancrazzi, M., Pantin, E., Parmentier, V., Parviainen, H., Ramírez, K. Y. Peña, Peralta, J., Perez-Hoyos, S., Petrov, R., Pezzuto, S., Pietrzak, R., Pilat-Lohinger, E., Piskunov, N., Prinja, R., Prisinzano, L., Polichtchouk, I., Poretti, E., Radioti, A., Ramos, A. A., Rank-Lüftinger, T., Read, P., Readorn, K., López, R. Rebolo, Rebordão, J., Rengel, M., Rezac, L., Rocchetto, M., Rodler, F., Béjar, V. J. Sánchez, Lavega, A. Sanchez, Sanromá, E., Santos, N., Forcada, J. Sanz, Scandariato, G., Schmider, F. -X., Scholz, A., Scuderi, S., Sethenadh, J., Shore, S., Showman, A., Sicardy, B., Sitek, P., Smith, A., Soret, L., Sousa, S., Stiepen, A., Stolarski, M., Strazzulla, G., Tabernero, H. M, Tanga, P., Tecsa, M., Temple, J., Terenzi, L., Tessenyi, M., Testi, L., Thompson, S., Thrastarson, H., Tingley, B. W., Trifoglio, M., Torres, J. Martín, Tozzi, A., Turrini, D., Varley, R., Vakili, F., de Val-Borro, M., Valdivieso, M. L., Venot, O., Villaver, E., Vinatier, S., Viti, S., Waldmann, I., Waltham, D., Ward-Thompson, D., Waters, R., Watkins, C., Watson, D., Wawer, P., Wawrzaszk, A., White, G., Widemann, T., Winek, W., Wiśniowski, T., Yelle, R., Yung, Y., and Yurchenko, S. N.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The discovery of almost 2000 exoplanets has revealed an unexpectedly diverse planet population. Observations to date have shown that our Solar System is certainly not representative of the general population of planets in our Milky Way. The key science questions that urgently need addressing are therefore: What are exoplanets made of? Why are planets as they are? What causes the exceptional diversity observed as compared to the Solar System? EChO (Exoplanet Characterisation Observatory) has been designed as a dedicated survey mission for transit and eclipse spectroscopy capable of observing a large and diverse planet sample within its four-year mission lifetime. EChO can target the atmospheres of super-Earths, Neptune-like, and Jupiter-like planets, in the very hot to temperate zones (planet temperatures of 300K-3000K) of F to M-type host stars. Over the next ten years, several new ground- and space-based transit surveys will come on-line (e.g. NGTS, CHEOPS, TESS, PLATO), which will specifically focus on finding bright, nearby systems. The current rapid rate of discovery would allow the target list to be further optimised in the years prior to EChO's launch and enable the atmospheric characterisation of hundreds of planets. Placing the satellite at L2 provides a cold and stable thermal environment, as well as a large field of regard to allow efficient time-critical observation of targets randomly distributed over the sky. A 1m class telescope is sufficiently large to achieve the necessary spectro-photometric precision. The spectral coverage (0.5-11 micron, goal 16 micron) and SNR to be achieved by EChO, thanks to its high stability and dedicated design, would enable a very accurate measurement of the atmospheric composition and structure of hundreds of exoplanets., Comment: 50 pages, 30 figures. Experimental Astronomy

Published
2015
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13. HST/ACS Observations of Europa's Atmospheric UV Emission at Eastern Elongation

Author

Saur, Joachim, Feldman, Paul D., Roth, Lorenz, Nimmo, Francis, Strobel, Darrell F., Retherford, Kurt D., McGrath, Melissa A., Schilling, Nico, Gérard, Jean-Claude, and Grodent, Denis

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

We report results of a Hubble Space Telescope (HST) campaign with the Advanced Camera for Surveys to observe Europa at eastern elongation, i.e. Europa's leading side, on 2008 June 29. With five consecutive HST orbits, we constrain Europa's atmospheric \ion{O}{1} 1304 \A and \ion{O}{1} 1356 \A emissions using the prism PR130L. The total emissions of both oxygen multiplets range between 132 $\pm$ 14 and 226 $\pm$ 14 Rayleigh. An additional systematic error with values on the same order as the statistical errors may be due to uncertainties in modelling the reflected light from Europa's surface. The total emission also shows a clear dependence of Europa's position with respect to Jupiter's magnetospheric plasma sheet. We derive a lower limit for the O$_2$ column density of 6 $\times$ 10$^{18}$ m$^{-2}$. Previous observations of Europa's atmosphere with STIS in 1999 of Europa's trailing side show an enigmatic surplus of radiation on the anti-Jovian side within the disk of Europa. With emission from a radially symmetric atmosphere as a reference, we searched for an anti-Jovian vs sub-Jovian asymmetry with respect to the central meridian on the leading side, and found none. Likewise, we searched for departures from a radially symmetric atmospheric emission and found an emission surplus centered around 90 degree west longitude, for which plausible mechanisms exist. Previous work about the possibility of plumes on Europa due to tidally-driven shear heating found longitudes with strongest local strain rates which might be consistent with the longitudes of maximum UV emissions. Alternatively, asymmetries in Europa's UV emission can also be caused by inhomogeneous surface properties, inhomogeneous solar illuminations, and/or by Europa's complex plasma interaction with Jupiter's magnetosphere., Comment: in press, Astrophysical Journal, 16 Figures

Published
2011

14. Quantifying the Electron Energy of Mars Aurorae Through the Oxygen Emission Brightness Ratio at 130.4 and 135.6 nm.

Author

Soret, Lauriane, Hubert, Benoît, Gérard, Jean‐Claude, Jain, Sonal, Chirakkil, K., Lillis, R., and Deighan, J.

Subjects
AURORAS, MARS (Planet), MARTIAN atmosphere, ELECTRON transport, ELECTRONS
Abstract

Mars discrete aurorae are caused by accelerated electrons precipitating into the atmosphere and interacting with species such as atomic oxygen. However, the energy of the electrons causing these aurorae remains currently unclear: no simultaneous and concurrent measurements of electron analyzers and spectrometers have been performed so far, preventing from assessing the exact energy of the downgoing auroral electrons. Several auroral emissions have been observed so far on Mars, among which are two oxygen emissions in the far ultraviolet at 130.4 and 135.6 nm. In this study, we simulate the vertical distribution of these auroral oxygen emissions with an electron transport calculation coupled with a radiative transfer model to account for the optical thickness of the atmosphere for the 130.4‐nm triplet. We show that the brightness ratio of these oxygen emissions is independent of the downward electron energy flux and only slightly depends on the atomic oxygen atmospheric composition. In contrast, the brightness ratio is strongly related to the initial energy of the auroral electrons. Measuring the brightness ratio is therefore a unique tool to remotely estimate the energy of the electrons causing the Mars discrete aurorae. We compare our model results with observations from the Emirates Mars Ultraviolet Spectrometer on board the Emirates Mars Mission and find that electrons with typical energies of 250–300 eV are compatible with the observed ratio of 5. Plain Language Summary: Aurorae have been observed on the nightside of Mars. They are caused by energetic electrons that interact with the constituents of the Mars atmosphere. However, since no direct measurement has been performed during auroral events, the energy of these auroral electrons remains currently unclear. In this study, we simulate the brightnesses of two auroral emissions of atomic oxygen in the far ultraviolet as if they were seen from an orbiter. We use a photochemical model as well as an electron transport model and a radiative transfer model. We demonstrate that the brightness of these emissions strongly depends on the initial energy of the auroral electrons and their flux. In contrast, the ratio of the brightness of the emissions is independent on the flux and therefore represents a unique tool to remotely estimate the energy of the electrons causing the Mars discrete aurorae. We compare our model results with observations from the Emirates Mars Ultraviolet Spectrometer on board the Emirates Mars Mission and find that electrons with energies of 250–300 eV are responsible for the observed ratio of 5. Key Points: The 130.4 optically thick and the 135.6 nm optically thin oxygen emissions can be observed during a Mars auroral eventRadiative transfer effects increase the observed nadir brightness of the 130.4‐nm emissionBrightnesses of both emissions depends on O density, initial electron energy and flux, while their ratio depends on the electron energy [ABSTRACT FROM AUTHOR]

Published
2024
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15. Advancing Our Understanding of Martian Proton Aurora through a Coordinated Multi‐Model Comparison Campaign

Author

Hughes, Andréa C. G., primary, Chaffin, Michael, additional, Mierkiewicz, Edwin, additional, Deighan, Justin, additional, Jolitz, Rebecca D., additional, Kallio, Esa, additional, Gronoff, Guillaume, additional, Shematovich, Valery, additional, Bisikalo, Dmitry, additional, Halekas, Jasper, additional, Wedlund, Cyril Simon, additional, Schneider, Nicholas, additional, Ritter, Birgit, additional, Girazian, Zachary, additional, Jain, Sonal, additional, Gérard, Jean‐Claude, additional, and Hegyi, Bradley, additional

Published
2023
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16. Jupiter Science Enabled by ESA’s Jupiter Icy Moons Explorer

Author

Fletcher, Leigh N., primary, Cavalié, Thibault, additional, Grassi, Davide, additional, Hueso, Ricardo, additional, Lara, Luisa M., additional, Kaspi, Yohai, additional, Galanti, Eli, additional, Greathouse, Thomas K., additional, Molyneux, Philippa M., additional, Galand, Marina, additional, Vallat, Claire, additional, Witasse, Olivier, additional, Lorente, Rosario, additional, Hartogh, Paul, additional, Poulet, François, additional, Langevin, Yves, additional, Palumbo, Pasquale, additional, Gladstone, G. Randall, additional, Retherford, Kurt D., additional, Dougherty, Michele K., additional, Wahlund, Jan-Erik, additional, Barabash, Stas, additional, Iess, Luciano, additional, Bruzzone, Lorenzo, additional, Hussmann, Hauke, additional, Gurvits, Leonid I., additional, Santolik, Ondřej, additional, Kolmasova, Ivana, additional, Fischer, Georg, additional, Müller-Wodarg, Ingo, additional, Piccioni, Giuseppe, additional, Fouchet, Thierry, additional, Gérard, Jean-Claude, additional, Sánchez-Lavega, Agustin, additional, Irwin, Patrick G. J., additional, Grodent, Denis, additional, Altieri, Francesca, additional, Mura, Alessandro, additional, Drossart, Pierre, additional, Kammer, Josh, additional, Giles, Rohini, additional, Cazaux, Stéphanie, additional, Jones, Geraint, additional, Smirnova, Maria, additional, Lellouch, Emmanuel, additional, Medvedev, Alexander S., additional, Moreno, Raphael, additional, Rezac, Ladislav, additional, Coustenis, Athena, additional, and Costa, Marc, additional

Published
2023
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17. The thermal structure of the Venus atmosphere: Intercomparison of Venus Express and ground based observations of vertical temperature and density profiles

Author

Limaye, Sanjay S., Lebonnois, Sebastien, Mahieux, Arnaud, Pätzold, Martin, Bougher, Steven, Bruinsma, Sean, Chamberlain, Sarah, Clancy, R. Todd, Gérard, Jean-Claude, Gilli, Gabriella, Grassi, Davide, Haus, Rainer, Herrmann, Maren, Imamura, Takeshi, Kohler, Erika, Krause, Pia, Migliorini, Alessandra, Montmessin, Franck, Pere, Christophe, Persson, Moa, Piccialli, Arianna, Rengel, Miriam, Rodin, Alexander, Sandor, Brad, Sornig, Manuela, Svedhem, Håkan, Tellmann, Silvia, Tanga, Paolo, Vandaele, Ann C., Widemann, Thomas, Wilson, Colin F., Müller-Wodarg, Ingo, and Zasova, Ludmila

Published
2017
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18. A chemical survey of exoplanets with ARIEL

Author

Tinetti, Giovanna, Drossart, Pierre, Eccleston, Paul, Hartogh, Paul, Heske, Astrid, Leconte, Jérémy, Micela, Giusi, Ollivier, Marc, Pilbratt, Göran, Puig, Ludovic, Turrini, Diego, Vandenbussche, Bart, Wolkenberg, Paulina, Beaulieu, Jean-Philippe, Buchave, Lars A., Ferus, Martin, Griffin, Matt, Guedel, Manuel, Justtanont, Kay, Lagage, Pierre-Olivier, Machado, Pedro, Malaguti, Giuseppe, Min, Michiel, Nørgaard-Nielsen, Hans Ulrik, Rataj, Mirek, Ray, Tom, Ribas, Ignasi, Swain, Mark, Szabo, Robert, Werner, Stephanie, Barstow, Joanna, Burleigh, Matt, Cho, James, du Foresto, Vincent Coudé, Coustenis, Athena, Decin, Leen, Encrenaz, Therese, Galand, Marina, Gillon, Michael, Helled, Ravit, Morales, Juan Carlos, Muñoz, Antonio García, Moneti, Andrea, Pagano, Isabella, Pascale, Enzo, Piccioni, Giuseppe, Pinfield, David, Sarkar, Subhajit, Selsis, Franck, Tennyson, Jonathan, Triaud, Amaury, Venot, Olivia, Waldmann, Ingo, Waltham, David, Wright, Gillian, Amiaux, Jerome, Auguères, Jean-Louis, Berthé, Michel, Bezawada, Naidu, Bishop, Georgia, Bowles, Neil, Coffey, Deirdre, Colomé, Josep, Crook, Martin, Crouzet, Pierre-Elie, Da Peppo, Vania, Sanz, Isabel Escudero, Focardi, Mauro, Frericks, Martin, Hunt, Tom, Kohley, Ralf, Middleton, Kevin, Morgante, Gianluca, Ottensamer, Roland, Pace, Emanuele, Pearson, Chris, Stamper, Richard, Symonds, Kate, Rengel, Miriam, Renotte, Etienne, Ade, Peter, Affer, Laura, Alard, Christophe, Allard, Nicole, Altieri, Francesca, André, Yves, Arena, Claudio, Argyriou, Ioannis, Aylward, Alan, Baccani, Cristian, Bakos, Gaspar, Banaszkiewicz, Marek, Barlow, Mike, Batista, Virginie, Bellucci, Giancarlo, Benatti, Serena, Bernardi, Pernelle, Bézard, Bruno, Blecka, Maria, Bolmont, Emeline, Bonfond, Bertrand, Bonito, Rosaria, Bonomo, Aldo S., Brucato, John Robert, Brun, Allan Sacha, Bryson, Ian, Bujwan, Waldemar, Casewell, Sarah, Charnay, Bejamin, Pestellini, Cesare Cecchi, Chen, Guo, Ciaravella, Angela, Claudi, Riccardo, Clédassou, Rodolphe, Damasso, Mario, Damiano, Mario, Danielski, Camilla, Deroo, Pieter, Di Giorgio, Anna Maria, Dominik, Carsten, Doublier, Vanessa, Doyle, Simon, Doyon, René, Drummond, Benjamin, Duong, Bastien, Eales, Stephen, Edwards, Billy, Farina, Maria, Flaccomio, Ettore, Fletcher, Leigh, Forget, François, Fossey, Steve, Fränz, Markus, Fujii, Yuka, García-Piquer, Álvaro, Gear, Walter, Geoffray, Hervé, Gérard, Jean Claude, Gesa, Lluis, Gomez, H., Graczyk, Rafał, Griffith, Caitlin, Grodent, Denis, Guarcello, Mario Giuseppe, Gustin, Jacques, Hamano, Keiko, Hargrave, Peter, Hello, Yann, Heng, Kevin, Herrero, Enrique, Hornstrup, Allan, Hubert, Benoit, Ida, Shigeru, Ikoma, Masahiro, Iro, Nicolas, Irwin, Patrick, Jarchow, Christopher, Jaubert, Jean, Jones, Hugh, Julien, Queyrel, Kameda, Shingo, Kerschbaum, Franz, Kervella, Pierre, Koskinen, Tommi, Krijger, Matthijs, Krupp, Norbert, Lafarga, Marina, Landini, Federico, Lellouch, Emanuel, Leto, Giuseppe, Luntzer, A., Rank-Lüftinger, Theresa, Maggio, Antonio, Maldonado, Jesus, Maillard, Jean-Pierre, Mall, Urs, Marquette, Jean-Baptiste, Mathis, Stephane, Maxted, Pierre, Matsuo, Taro, Medvedev, Alexander, Miguel, Yamila, Minier, Vincent, Morello, Giuseppe, Mura, Alessandro, Narita, Norio, Nascimbeni, Valerio, Nguyen Tong, N., Noce, Vladimiro, Oliva, Fabrizio, Palle, Enric, Palmer, Paul, Pancrazzi, Maurizio, Papageorgiou, Andreas, Parmentier, Vivien, Perger, Manuel, Petralia, Antonino, Pezzuto, Stefano, Pierrehumbert, Ray, Pillitteri, Ignazio, Piotto, Giampaolo, Pisano, Giampaolo, Prisinzano, Loredana, Radioti, Aikaterini, Réess, Jean-Michel, Rezac, Ladislav, Rocchetto, Marco, Rosich, Albert, Sanna, Nicoletta, Santerne, Alexandre, Savini, Giorgio, Scandariato, Gaetano, Sicardy, Bruno, Sierra, Carles, Sindoni, Giuseppe, Skup, Konrad, Snellen, Ignas, Sobiecki, Mateusz, Soret, Lauriane, Sozzetti, Alessandro, Stiepen, A., Strugarek, Antoine, Taylor, Jake, Taylor, William, Terenzi, Luca, Tessenyi, Marcell, Tsiaras, Angelos, Tucker, C., Valencia, Diana, Vasisht, Gautam, Vazan, Allona, Vilardell, Francesc, Vinatier, Sabrine, Viti, Serena, Waters, Rens, Wawer, Piotr, Wawrzaszek, Anna, Whitworth, Anthony, Yung, Yuk L., Yurchenko, Sergey N., Osorio, María Rosa Zapatero, Zellem, Robert, Zingales, Tiziano, and Zwart, Frans

Published
2018
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22. Enhanced C2H2 Absorption Within Jupiter's Southern Auroral Oval From Juno UVS Observations

Author

Giles, Rohini S., primary, Hue, Vincent, additional, Greathouse, Thomas K., additional, Gladstone, G. Randall, additional, Kammer, Joshua A., additional, Versteeg, Maarten H., additional, Bonfond, Bertrand, additional, Grodent, Denis C., additional, Gérard, Jean‐Claude, additional, Sinclair, James A., additional, Bolton, Scott J., additional, and Levin, Steven M., additional

Published
2023
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23. Laboratory Study of the Cameron Bands and UV Doublet in the Middle Ultraviolet 180–300 nm by Electron Impact upon CO2 with Application to Mars

Author

Lee, Rena A., primary, Ajello, Joseph M., additional, Malone, Charles P., additional, Evans, J. Scott, additional, Veibell, Victoir, additional, Holsclaw, Gregory M., additional, McClintock, William E., additional, Hoskins, Alan C., additional, Jain, Sonal K., additional, Gérard, Jean-Claude, additional, Aryal, Saurav, additional, and Schneider, Nicholas M., additional

Published
2022
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24. Magnetosphere-Ionosphere-Thermosphere Coupling study at Jupiter Based on Juno First 30 Orbits and Modeling Tools

Author

Al Saati, Sariah, primary, Clément, Noé, additional, Louis, Corentin, additional, Blanc, Michel, additional, Wang, Yuxian, additional, André, Nicolas, additional, Lamy, Laurent, additional, Gérard, Jean-Claude, additional, Bonfond, Bertrand, additional, Mauk, Barry, additional, Clark, George, additional, Allegrini, Frédéric, additional, Bolton, Scott, additional, Gladstone, Randy, additional, Connerney, John, additional, Kotsiaros, Stavros, additional, and Kurth, William, additional

Published
2022
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26. Two Martian years at Mars: Observations by NOMAD on ExoMars Trace Gas Orbiter

Author

Vandaele, Ann Carine, primary, Daerden, Frank, additional, Thomas, Ian R., additional, Depiesse, Cédric, additional, Erwin, Justin, additional, Flimon, Zachary, additional, Neary, Lori, additional, Piccialli, Arianna, additional, Ristic, Bojan, additional, Trompet, Loïc, additional, Viscardy, Sébastien, additional, Willame, Yannick, additional, Aoki, Shohei, additional, Gérard, Jean-Claude, additional, Villanueva, Geronimo, additional, Mason, Jon, additional, Patel, Manish, additional, Bellucci, Giancarlo, additional, Lopez-Valverde, Miguel, additional, and Lopez-Moreno, Jose Juan, additional

Published
2022
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31. Juno's multi-instruments observations during the flybys of auroral bright spots in Jupiter's polar aurorae

Author

Haewsantati, Kamolporn, primary, Bonfond, Bertrand, additional, wannawichian, Suwicha, additional, Gladstone, Randy, additional, Hue, Vincent, additional, Greathouse, Thomas K., additional, Grodent, Denis, additional, Yao, Zhonghua, additional, Gérard, Jean-Claude M. C., additional, Guo, Ruilong, additional, Elliott, Sadie Suzanne, additional, Mauk, Barry H., additional, Clark, George, additional, Gershman, Daniel J, additional, Kotsiaros, Stavros, additional, Kurth, William S, additional, Connerney, John E. P., additional, Szalay, Jamey R., additional, and Phriksee, Anirut, additional

Published
2022
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32. Comparison of ICON-EUV F-Peak Characteristic Parameters with External Data Sources

Author

Haystack Observatory, Wautelet, Gilles, Hubert, Benoît, Gérard, Jean-Claude, Immel, Thomas J., Sirk, Martin M., Korpela, Eric J., Stephan, Andrew W., Mende, Stephen B., England, Scott L., Erickson, Philip J., Haystack Observatory, Wautelet, Gilles, Hubert, Benoît, Gérard, Jean-Claude, Immel, Thomas J., Sirk, Martin M., Korpela, Eric J., Stephan, Andrew W., Mende, Stephen B., England, Scott L., and Erickson, Philip J.

Abstract

We provide the first comparison of the ICON-EUV O+ density profile with radio wave datasets coming from GNSS radio-occultation, ionosondes and incoherent scatter radar. The peak density and height deduced from those different observation techniques are compared. It is found that the EUV-deduced peak density is smaller than that from other techniques by 50 to 60%, while the altitude of the peak is retrieved with a slight bias of 10 to 20 km on average. These average values are found to vary between November 2019 and March 2021. Magnetic latitude and local time are not factors significantly influencing this variability. In contrast, the EUV density is closer to that deduced from radio-wave techniques in the mid latitude region, i.e. where the ionospheric crests do not play a role. The persistent very low solar activity conditions prevailing during the studied time interval challenge the EUV O+ density profile retrieval technique. These values are consistent, both in magnitude and direction, with a systematic error on the order of 10% in the data or the forward model, or a combination of both. Ultimately, the EUV instrument on-board ICON provides the only known technique capable of precisely monitoring the ionospheric peak properties at daytime from a single space platform, on a global scale and at high cadence. This feature paves the way to transpose the technology to the study of the ionosphere surrounding other planets.

Published
2022

34. Publisher Correction: Martian dust storm impact on atmospheric H2O and D/H observed by ExoMars Trace Gas Orbiter

Author

Vandaele, Ann Carine, Korablev, Oleg, Daerden, Frank, Aoki, Shohei, Thomas, Ian R., Altieri, Francesca, López-Valverde, Miguel, Villanueva, Geronimo, Liuzzi, Giuliano, Smith, Michael D., Erwin, Justin T., Trompet, Loïc, Fedorova, Anna A., Montmessin, Franck, Trokhimovskiy, Alexander, Belyaev, Denis A., Ignatiev, Nikolay I., Luginin, Mikhail, Olsen, Kevin S., Baggio, Lucio, Alday, Juan, Bertaux, Jean-Loup, Betsis, Daria, Bolsée, David, Clancy, R. Todd, Cloutis, Edward, Depiesse, Cédric, Funke, Bernd, Garcia-Comas, Maia, Gérard, Jean-Claude, Giuranna, Marco, Gonzalez-Galindo, Francisco, Grigoriev, Alexey V., Ivanov, Yuriy S., Kaminski, Jacek, Karatekin, Ozgur, Lefèvre, Franck, Lewis, Stephen, López-Puertas, Manuel, Mahieux, Arnaud, Maslov, Igor, Mason, Jon, Mumma, Michael J., Neary, Lori, Neefs, Eddy, Patrakeev, Andrey, Patsaev, Dmitry, Ristic, Bojan, Robert, Séverine, Schmidt, Frédéric, Shakun, Alexey, Teanby, Nicholas A., Viscardy, Sébastien, Willame, Yannick, Whiteway, James, Wilquet, Valérie, Wolff, Michael J., Bellucci, Giancarlo, Patel, Manish R., López-Moreno, Jose-Juan, Forget, François, Wilson, Colin F., Young, Roland, Svedhem, Håkan, Vago, Jorge L., Rodionov, Daniel, NOMAD Science Team, and ACS Science Team

Published
2019
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36. Magnetosphere-Ionosphere-Thermosphere Coupling study at Jupiter Based on Juno First 30 Orbits and Modelling Tools

Author

Blanc, Michel, primary, Al Saati, Sariah, additional, Clement, Noe, additional, Wang, Yuxian, additional, Louis, Corentin, additional, Andre, Nicolas, additional, Lamy, Laurent, additional, Gérard, Jean-Claude, additional, Bonfond, Bertrand, additional, Clark, George, additional, Mauk, Barry, additional, Allegrini, Frederick, additional, Gladstone, Randy, additional, Bolton, Scott, additional, Kotsiaros, Stavros, additional, and Kurth, William, additional

Published
2022
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38. The two faces of the Jovian UV aurorae

Author

Bonfond, Bertrand, primary, Grodent, Denis, additional, Palmaerts, Benjamin, additional, Gladstone, Randy, additional, Badman, Sarah, additional, Clarke, John, additional, Gérard, Jean-Claude, additional, Giles, Rohini, additional, Greathouse, Thomas, additional, Haewsantati, Kamolporn, additional, Hue, Vincent, additional, Kammer, Joshua, additional, Nichols, Jonathan, additional, Sicorello, Guillaume, additional, Wannawichian, Suwicha, additional, and Yao, Zhonghua, additional

Published
2022
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39. Local Time Dependence of Jupiter's Polar Auroral Emissions Observed by Juno UVS

Author

Greathouse, Thomas, primary, Gladstone, Randy, additional, Versteeg, Maarten, additional, Hue, Vincent, additional, Kammer, Joshua, additional, Giles, Rohini, additional, Davis, Michael, additional, Bolton, Scott, additional, Levin, Steven, additional, Connerney, John, additional, Gérard, Jean‐Claude, additional, Grodent, Denis, additional, Bonfond, Bertrand, additional, Bunce, Emma, additional, and Vogt, Marissa F., additional

Published
2021
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40. Magnetosphere-Ionosphere-Thermosphere Coupling study at Jupiter Based on Juno First 30 Orbits and Modelling Tools

Author

Al Saati, Sariah, Clément, Noé, Blanc, Michel, Wang, Yuxian, André, Nicolas, Louis, Corentin, Lamy, Laurent, Blelly, Pierre-Louis, Louarn, Philippe, Marchaudon, Aurélie, Gérard, Jean-Claude, Bonfond, Bertrand, Grodent, Denis, Dinelli, Bianca Maria, Adriani, Alberto, Mura, Alessandro, Mauk, Barry, Clark, George, Allegrini, Frederick, Bolton, Scott, Laboratoire d'études spatiales et d'instrumentation en astrophysique = Laboratory of Space Studies and Instrumentation in Astrophysics (LESIA), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Laboratoire d'Astrophysique de Marseille (LAM), and Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDU]Sciences of the Universe [physics], Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics
Abstract

Virtual meeting; International audience; The dynamics of the Jovian magnetosphere is controlled by the complex interplay of the planet's fast rotation, its solar-wind interaction and its main plasma source at the Io torus. At the ionospheric level, these MIT coupling processes can be characterized by a set of key parameters which include ionospheric conductances, currents and electric fields, exchanges of particles along field lines and auroral emissions. Knowledge of these key parameters in turn makes it possible to estimate the net deposition/extraction of momentum and energy into/out of the Jovian upper atmosphere. In this talk we will extend to the first thirty Juno science orbits the method described in Wang et al. (JGR 2021, under review) which combines Juno multi-instrument data (MAG, JADE, JEDI, UVS, JIRAM and WAVES), adequate modelling tools and data bases to retrieve these key parameters along the Juno magnetic footprint and across the north and south auroral ovals. We will present preliminary distributions of conductances, electric currents and electric fields obtained from these orbits and will compare them with model predictions.

Published
2021

41. Enhanced C2H2 Absorption Within Jupiter's Southern Auroral Oval From Juno UVS Observations.

Author

Giles, Rohini S., Hue, Vincent, Greathouse, Thomas K., Gladstone, G. Randall, Kammer, Joshua A., Versteeg, Maarten H., Bonfond, Bertrand, Grodent, Denis C., Gérard, Jean‐Claude, Sinclair, James A., Bolton, Scott J., and Levin, Steven M.

Subjects
ATMOSPHERE of Jupiter, JUPITER (Planet), JUNO (Space probe), ATMOSPHERIC chemistry, UPPER atmosphere
Abstract

Reflected sunlight observations from the Ultraviolet Spectrograph (UVS) on the Juno spacecraft were used to study the distribution of acetylene (C2H2) at Jupiter's south pole. We find that the shape of the C2H2 absorption feature varies significantly across the polar region, and this can be used to infer spatial variability in the C2H2 abundance. There is a localized region of enhanced C2H2 absorption which coincides with the location of Jupiter's southern polar aurora; the C2H2 abundance poleward of the auroral oval is a factor of 3 higher than adjacent quiescent, non‐auroral longitudes. This builds on previous infrared studies, which found enhanced C2H2 abundances within the northern auroral oval. This suggests that Jupiter's upper‐atmosphere chemistry is being strongly influenced by the influx of charged auroral particles and demonstrates the necessity of developing ion‐neutral photochemical models of Jupiter's polar regions. Plain Language Summary: The Ultraviolet Spectrograph on the Juno mission to Jupiter measures ultraviolet sunlight that is reflected from the planet's upper atmosphere and these observations can be used to measure the abundances of different gases in the stratosphere. In this paper, we study the spatial distribution of the molecule acetylene at Jupiter's south pole. We find that there is a significant increase in the acetylene abundance at the location of Jupiter's southern aurora. This suggests that the charged particles that travel along magnetic field lines toward Jupiter's poles and produce bright auroral emission also have a strong influence on the chemistry of Jupiter's upper atmosphere. Key Points: Ultraviolet reflected sunlight observations from Juno Ultraviolet Spectrograph were used to study the distribution of C2H2 at Jupiter's south poleFrom the changes in the spectral shape, we infer enhanced C2H2 absorption within the southern auroral ovalJupiter's atmospheric chemistry at the poles is strongly influenced by the influx of charged auroral particles [ABSTRACT FROM AUTHOR]

Published
2023
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44. A Preliminary Study of Magnetosphere‐Ionosphere‐Thermosphere Coupling at Jupiter: Juno Multi‐Instrument Measurements and Modeling Tools

Author

Wang, Yuxian, primary, Blanc, Michel, additional, Louis, Corentin, additional, Wang, Chi, additional, André, Nicolas, additional, Adriani, Alberto, additional, Allegrini, Frederic, additional, Blelly, Pierre‐Louis, additional, Bolton, Scott, additional, Bonfond, Bertrand, additional, Clark, George, additional, Dinelli, Bianca Maria, additional, Gérard, Jean‐Claude, additional, Gladstone, Randy, additional, Grodent, Denis, additional, Kotsiaros, Stavros, additional, Kurth, William, additional, Lamy, Laurent, additional, Louarn, Philippe, additional, Marchaudon, Aurélie, additional, Mauk, Barry, additional, Mura, Alessandro, additional, and Tao, Chihiro, additional

Published
2021
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45. HST Far-Ultraviolet Imaging of Jupiter During the Impacts of Comet Shoemaker-Levy 9

Author

Clarke, John T., Prangé, Renée, Ballester, Gilda E., Trauger, John, Evans, Robin, Rego, Daniel, Stapelfeldt, Karl, Ip, Wing, Gérard, Jean-Claude, Hammel, Heidi, Ballav, Manish, Ben Jaffel, Lotfi, Bertaux, Jean-Loup, Crisp, David, Emerich, Claude, Harris, Walter, Horanyi, Mihaly, Miller, Steven, Storrs, Alex, and Weaver, Harold

Published
1995

46. The Martian environment observed by NOMAD on ExoMars Trace Gas Orbiter

Author

Vandaele, Ann Carine, primary, Daerden, Frank, additional, Thomas, Ian R., additional, Aoki, Shohei, additional, Depiesse, Cédric, additional, Erwin, Justin, additional, Neary, Lori, additional, Piccialli, Arianna, additional, Ristic, Bojan, additional, Robert, Séverine, additional, Trompet, Loïc, additional, Viscardy, Sébastien, additional, Willame, Yannick, additional, Gérard, Jean-Claude, additional, Villanueva, Geronimo, additional, Mason, Jon, additional, Patel, Manish, additional, Bellucci, Giancarlo, additional, Lopez-Valverde, Miguel, additional, and Lopez-Moreno, Jose-Juan, additional

Published
2021
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47. Distribution et saisonnalité du monoxyde de carbone dans la basse atmosphère de Mars à partir des mesures du sondeur PFS

Author

Coheur, Pierre, Vandaele, Ann Carine, Debaille, Vinciane, Bauduin, Sophie, Määttänen, Anni A, Gérard, Jean-Claude, Vander Auwera, Jean, Bouche, Jimmy, Coheur, Pierre, Vandaele, Ann Carine, Debaille, Vinciane, Bauduin, Sophie, Määttänen, Anni A, Gérard, Jean-Claude, Vander Auwera, Jean, and Bouche, Jimmy

Abstract

La connaissance de l'abondance du monoxyde de carbone (CO) dans l'atmosphère de Mars est essentielle pour évaluer les processus qui régissent le cycle du carbone sur la planète. Les mesures d'occultation solaire fournissent des mesures verticalement résolues du CO de quelques kilomètres au-dessus de la surface à des altitudes plus élevées. Elles peuvent être complétées avantageusement par des mesures au nadir pour améliorer le suivi de la couche proche de la surface et la couverture spatiale des observations. Jusqu'à présent, dans l'infrarouge, les restitutions de CO à partir d'observations au nadir ont cependant été effectuées principalement sur des spectres moyens et seules les abondances estimées pour la colonne atmosphérique totale ont été obtenues.Dans ce travail, nous explorons la possibilité d'exploiter les mesures individuelles au nadir du spectromètre Planetary Fourier Spectrometer (PFS), à bord de Mars Express (MEX), dans la bande 1--0 du CO centrée à 2143 cm-1, et comprise dans le canal à courte longueur d'onde de PFS, pour restituer les profils verticaux de cette espèce. Plus précisément, l'objectif de ce travail vise à répondre aux questions suivantes: (1) Peut-on restituer des profils verticaux de CO dans la basse atmosphère de Mars à partir d'observations PFS individuelles au nadir ?Quelle est la sensibilité verticale de PFS et la fiabilité des restitutions ?(2) Quelle est la variabilité spatiale du CO à travers les différentes saisons sur Mars et comment cette espèce est-elle reliée à l'abondance du CO2 ?Notre travail étudie d'abord et pour la première fois la restitution des profils verticaux de CO dans la basse atmosphère de Mars à partir d'observations individuelles au nadir de PFS. Les restitutions sont effectuées pour un ensemble restreint de 16 spectres PFS sélectionnés avec des rapports signal/bruit élevés et en appliquant la méthode de l'estimation optimale (OEM) avec des contraintes appropriées, construites à partir de simulations de modèles, Doctorat en Sciences, info:eu-repo/semantics/nonPublished

Published
2021

48. A preliminary study of Magnetosphere‐Ionosphere‐Thermosphere coupling at Jupiter: Juno multi‐instrument measurements and modelling tools

Author

Wang, Yuxian, Blanc, Michel, Louis, Corentin, Wang, Chi, André, Nicolas, Adriani, Alberto, Allegrini, Frederic, Blelly, Pierre‐Louis, Bolton, Scott, Bonfond, Bertrand, Clark, George, Dinelli, Bianca Maria, Gérard, Jean‐Claude, Gladstone, Randy, Grodent, Denis, Kotsiaros, Stavros, Kurth, William, Lamy, Laurent, Louarn, Philippe, Marchaudon, Aurélie, Mauk, Barry, Mura, Alessandro, Tao, Chihiro, Wang, Yuxian, Blanc, Michel, Louis, Corentin, Wang, Chi, André, Nicolas, Adriani, Alberto, Allegrini, Frederic, Blelly, Pierre‐Louis, Bolton, Scott, Bonfond, Bertrand, Clark, George, Dinelli, Bianca Maria, Gérard, Jean‐Claude, Gladstone, Randy, Grodent, Denis, Kotsiaros, Stavros, Kurth, William, Lamy, Laurent, Louarn, Philippe, Marchaudon, Aurélie, Mauk, Barry, Mura, Alessandro, and Tao, Chihiro

Abstract

The dynamics of the Jovian magnetosphere are controlled by the interplay of the planet’s fast rotation, its main iogenic plasma source and its interaction with the solar wind. Magnetosphere-Ionosphere-Thermosphere (MIT) coupling processes controlling this interplay are significantly different from their Earth and Saturn counterparts. At the ionospheric level, they can be characterized by a set of key parameters: ionospheric conductances, electric currents and fields, exchanges of particles along field lines, Joule heating and particle energy deposition. From these parameters, one can determine (1) how magnetospheric currents close into the ionosphere, and (2) the net deposition/extraction of energy into/out of the upper atmosphere associated to MIT coupling. We present a new method combining Juno multi-instrument data (MAG, JADE, JEDI, UVS, JIRAM and Waves) and modelling tools to estimate these key parameters along Juno’s trajectories. We first apply this method to two southern hemisphere main auroral oval crossings to illustrate how the coupling parameters are derived. We then present a preliminary statistical analysis of the morphology and amplitudes of these key parameters for eight among the first nine southern perijoves. We aim to extend our method to more Juno orbits to progressively build a comprehensive view of Jovian MIT coupling at the level of the main auroral oval.

Published
2021

49. First Observation of the Oxygen 630 nm Emission in the Martian Dayglow

Author

Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), European Commission, UK Space Agency, Agenzia Spaziale Italiana, European Space Agency, Gérard, Jean-Claude, Aoki, Shohei, Gkouvelis, L., Soret, L., Willame, Y., Thomas, Ian R., Depiesse, C., Ristic, Bojan, Vandaele, Ann Carine, Hubert, B., Daerden, Frank, Patel, Manish R., López-Moreno, José Juan, Bellucci, Giancarlo, Mason, Jonathon P., López-Valverde, M. A., Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), European Commission, UK Space Agency, Agenzia Spaziale Italiana, European Space Agency, Gérard, Jean-Claude, Aoki, Shohei, Gkouvelis, L., Soret, L., Willame, Y., Thomas, Ian R., Depiesse, C., Ristic, Bojan, Vandaele, Ann Carine, Hubert, B., Daerden, Frank, Patel, Manish R., López-Moreno, José Juan, Bellucci, Giancarlo, Mason, Jonathon P., and López-Valverde, M. A.

Abstract

Following the recent detection of the oxygen green line airglow on Mars, we have improved the statistical analysis of the data recorded by the NOMAD/UVIS instrument on board the ExoMars Trace Gas Orbiter mission by summing up hundreds of spectra to increase the signal-to-noise ratio. This led to the observation of the OI 630 nm emission, the first detection in a planetary atmosphere outside the Earth. The average limb profile shows a broad peak intensity of 4.8 kR near 150 km. Comparison with a photochemical model indicates that it is well predicted by current photochemistry, considering the sources of uncertainty. The red/green line intensity ratio decreases dramatically with altitude as a consequence of the efficient quenching of O(1D) by CO2. Simultaneous observations of the green and red dayglow will provide information on variations in the thermosphere in response to seasonal changes and the effects of solar events. © 2021. American Geophysical Union.

Published
2021

50. Local Time Dependence of Jupiter's Polar Auroral Emissions Observed by Juno UVS

Author

Greathouse, Thomas K., primary, Gladstone, Randy, additional, Versteeg, Maarten H., additional, Hue, Vincent, additional, Kammer, Joshua, additional, Giles, Rohini S, additional, Davis, Michael W., additional, Bolton, Scott J, additional, Levin, Steven M., additional, Connerney, John E. P., additional, Gérard, Jean-Claude M.C., additional, Grodent, Denis, additional, Bonfond, Bertrand, additional, Bunce, Emma, additional, and Vogt, Marissa F., additional

Published
2021
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