Your search keyword '"Karkoschka E"' showing total 25 results

1. Updated Radiative Transfer Model for Titan in the Near-infrared Wavelength Range: Validation against Huygens Atmospheric and Surface Measurements and Application to the Cassini/VIMS Observations of the Dragonfly Landing Area

Author

Es-sayeh, M., primary, Rodriguez, S., additional, Coutelier, M., additional, Rannou, P., additional, Bézard, B., additional, Maltagliati, L., additional, Cornet, T., additional, Grieger, B., additional, Karkoschka, E., additional, Le Mouélic, S., additional, Le Gall, A., additional, Neish, C., additional, MacKenzie, S., additional, Solomonidou, A., additional, Sotin, C., additional, and Coustenis, A., additional

Published

2023

2. In the News

Author

Karkoschka, E., Cohen, P. A., Nathan, A. M., Rigoni, D., and Maure, F.

Published

2011

3. A new digital terrain model of the Huygens landing site on Saturn's largest moon, Titan

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Daudon, C, Lucas, A, Rodriguez, S, Jacquemoud, S, Escalante López, A, Grieger, B, Howington-Kraus, E, Karkoschka, E, Kirk, RL, Perron, JT, Soderblom, JM, Costa, M, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Daudon, C, Lucas, A, Rodriguez, S, Jacquemoud, S, Escalante López, A, Grieger, B, Howington-Kraus, E, Karkoschka, E, Kirk, RL, Perron, JT, Soderblom, JM, and Costa, M

Abstract

© 2020. The Authors. River valleys have been observed on Titan at all latitudes by the Cassini-Huygens mission. Just like water on Earth, liquid methane carves into the substrate to form a complex network of rivers, particularly stunning in the images acquired near the equator by the Huygens probe. To better understand the processes at work that form these landscapes, one needs an accurate digital terrain model (DTM) of this region. The first and to date the only existing DTM of the Huygens landing site was produced by the U.S. Geological Survey (USGS) from high-resolution images acquired by the DISR (Descent Imager/Spectral Radiometer) cameras on board the Huygens probe and using the SOCET SET photogrammetric software. However, this DTM displays inconsistencies, primarily due to nonoptimal viewing geometries and to the poor quality of the original data, unsuitable for photogrammetric reconstruction. We investigate a new approach, benefiting from a recent reprocessing of the DISR images correcting both the radiometric and geometric distortions. For the DTM reconstruction, we use MicMac, a photogrammetry software based on automatic open-source shape-from-motion algorithms. To overcome challenges such as data quality and image complexity (unusual geometric configuration), we developed a specific pipeline that we detailed and documented in this article. In particular, we take advantage of geomorphic considerations to assess ambiguity on the internal calibration and the global orientation of the stereo model. Besides the novelty in this approach, the resulting DTM obtained offers the best spatial sampling of Titan's surface available and a significant improvement over the previous results.

Published

2022

4. HST Imaging of Atmospheric Phenomena Created by the Impact of Comet Shoemaker-Levy 9

Author

Hammel, H. B., Beebe, R. F., Ingersoll, A. P., Orton, G. S., Mills, J. R., Simon, A. A., Chodas, P., Clarke, J. T., De Jong, E., Dowling, T. E., Harrington, J., Huber, L. F., Karkoschka, E., Santori, C. M., Toigo, A., Yeomans, D., and West, R. A.

Published

1995

5. Depth of a strong jovian jet from a planetary-scale disturbance driven by storms

Author

Sanchez-Lavega, A., Orton, G. S., Hueso, R., Garcia-Melendo, E., Perez-Hoyos, S., Simon-Miller, A., Rojas, J. F., Gomez, J. M., Yanamandra-Fisher, P., Fletcher, L., Joels, J., Kemerer, J., Hora, J., Karkoschka, E., de Pater, I., Wong, M. H., Marcus, P. S., Pinilla-Alonso, N., Carvalho, F., Go, C., Parker, D., Salway, M., Valimberti, M., Wesley, A., and Pujic, Z.

Subjects

Thermal properties, Discovery and exploration, Observations, Composition, Properties, Jets (Fluid dynamics) -- Thermal properties -- Discovery and exploration, Jupiter (Planet) -- Discovery and exploration -- Thermal properties, Jovian atmosphere -- Composition -- Properties -- Observations -- Thermal properties -- Discovery and exploration, Jupiter (Planet) -- Atmosphere -- Discovery and exploration -- Thermal properties, Jets -- Thermal properties -- Discovery and exploration

Abstract

Author(s): A. Sánchez-Lavega (corresponding author) [1]; G. S. Orton [2]; R. Hueso [1]; E. García-Melendo [3]; S. Pérez-Hoyos [1]; A. Simon-Miller [4]; J. F. Rojas [5]; J. M. Gómez [3]; [...]

Published

2008

6. A new digital terrain model of the Huygens landing site on Saturn's largest moon, Titan

Author

Daudon, C, Lucas, A, Rodriguez, S, Jacquemoud, S, Escalante López, A, Grieger, B, Howington-Kraus, E, Karkoschka, E, Kirk, RL, Perron, JT, Soderblom, JM, Costa, M, Daudon, C, Lucas, A, Rodriguez, S, Jacquemoud, S, Escalante López, A, Grieger, B, Howington-Kraus, E, Karkoschka, E, Kirk, RL, Perron, JT, Soderblom, JM, and Costa, M

Abstract

© 2020. The Authors. River valleys have been observed on Titan at all latitudes by the Cassini-Huygens mission. Just like water on Earth, liquid methane carves into the substrate to form a complex network of rivers, particularly stunning in the images acquired near the equator by the Huygens probe. To better understand the processes at work that form these landscapes, one needs an accurate digital terrain model (DTM) of this region. The first and to date the only existing DTM of the Huygens landing site was produced by the U.S. Geological Survey (USGS) from high-resolution images acquired by the DISR (Descent Imager/Spectral Radiometer) cameras on board the Huygens probe and using the SOCET SET photogrammetric software. However, this DTM displays inconsistencies, primarily due to nonoptimal viewing geometries and to the poor quality of the original data, unsuitable for photogrammetric reconstruction. We investigate a new approach, benefiting from a recent reprocessing of the DISR images correcting both the radiometric and geometric distortions. For the DTM reconstruction, we use MicMac, a photogrammetry software based on automatic open-source shape-from-motion algorithms. To overcome challenges such as data quality and image complexity (unusual geometric configuration), we developed a specific pipeline that we detailed and documented in this article. In particular, we take advantage of geomorphic considerations to assess ambiguity on the internal calibration and the global orientation of the stereo model. Besides the novelty in this approach, the resulting DTM obtained offers the best spatial sampling of Titan's surface available and a significant improvement over the previous results.

Published

2021

7. Rain, winds and haze during the Huygens probe's descent to Titan's surface

Author

Tomasko, M. G., Archinal, B., Becker, T., Bezard, B., Bushroe, M., Combes, M., Cook, D., Coustenis, A., de Bergh, C., Dafoe, L. E., Doose, L., Doute, S., Eibl, A., Engel, S., Gliem, F., Grieger, B., Holso, K., Howington-Kraus, E., Karkoschka, E., Keller, H. U., Kirk, R., Kramm, R., Kuppers, M., Lanagan, P., Lellouch, E., Lemmon, M., Lunine, J., McFarlane, E., Moores, J., Prout, G. M., Rizk, B., Rosiek, M., Rueffer, P., Schroder, S. E., Schmitt, B., See, C., Smith, P., Soderblom, L., Thomas, N., and West, R.

Abstract

Author(s): M. G. Tomasko [1]; B. Archinal [2]; T. Becker [2]; B. Bézard [3]; M. Bushroe [1]; M. Combes [3]; D. Cook [2]; A. Coustenis [3]; C. de Bergh [3]; [...]

Published

2005

8. A New Digital Terrain Model of the Huygens Landing Site on Saturn's Largest Moon, Titan

Author

Daudon, C., primary, Lucas, A., additional, Rodriguez, S., additional, Jacquemoud, S., additional, Escalante López, A., additional, Grieger, B., additional, Howington‐Kraus, E., additional, Karkoschka, E., additional, Kirk, R. L., additional, Perron, J. T., additional, Soderblom, J. M., additional, and Costa, M., additional

Published

2020

9. First Results from the Descent Imager/Spectral Radiometer (DISR) Experiment on the Huygens Entry Probe of Titan

Author

Tomasko, M. G, Doose, L. R, Rizk, B, Smith, P, See, C, Bushroe, M, McFarlane, L, Engel, S, Eibl, A, and Karkoschka, E

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Cassini-Huygens mission was launched on October 15, 1997, and arrived in Orbit around Saturn in July, 2004. The Huygens Probe was released from the Cassini Orbiter on December 24, 2004 and entered Titan s atmosphere on January 14, 2005. Here we give the first results from the Descent Imager/Spectral Radiometer (DISR) instrument aboard the Huygens Probe during its descent into the atmosphere of Titan. Measurements were made by several different optical systems and sensors.

Published

2005

10. MP3 - A meteorology and physical properties package to explore air-sea interaction on Titan

Author

Lorenz, R. D., Stofan, E., Lunine, J. I., Zarnecki, J. C., Harri, A.-M., Karkoschka, E., Newman, C. E., Bierhaus, E. B., Clark, B. C., Yelland, M., Leese, M. R., Boldt, J., Darlington, E., Neish, C. D., Sotzen, K., Arvelo, J., Rasbach, C., Kretsch, W., Strohbehn, K., Grey, M., Mann, J., Zimmermann, H., and Reed, C.

Abstract

The exchange of mass, heat and momentum at the air:sea interface are profound influences on the terrestrial environment, affecting the intensity of hurricanes, the size of waves and lake-effect precipitation. Titan presents us with an opportunity to study these processes in a novel physical context, with a different sea, atmosphere and gravity. The MP3 instrument, under development for the proposed Discovery mission TiME (Titan Mare Explorer [1,2]) is an integrated suite of small, simple sensors that combines the function of traditional meteorology packages with liquid physical properties and depth-sounding : these latter functions follow the concept of - and indeed use spare elements from - the Huygens Surface Science Package (SSP,[3]). However, unlike Huygens’ brief and dynamic 3 hours of measurement, in TiME’s 6-Titan-day (96 Earth day) nominal mission enabled by radioisotope power, MP3 will have an unprecedented long-term measurement opportunity in one of the most evocative environments in the solar system, Titan’s sea Ligeia Mare.

Published

2012

11. Titan Mare Explorer (TiME): first in situ exploration of an extraterrestrial sea

Author

Stofan, E. R., Lorenz, R. D., Lunine, J. I., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H, and Zarnecki, J.

Abstract

The lakes and seas of Titan are a sink of products of photolysis in the atmosphere, and a crucial component in Titan's active methane cycle. In situ exploration of the seas is necessary to understand their intriguing prebiotic organic chemistry.

Published

2010

12. Exploring the seas of Titan: the Titan Mare Eplorer (TiME) mission

Author

Stofan, E. R., Lunine, J. I., Lorenz, R. D., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H., and Zarnecki, J.

Published

2010

13. Depth of a strong jovian jet from a planetary-scale disturbance driven by storms

Author

Sanchez-Lavega, A., Orton, G.S., Hueso, R., Garcia-Melendo, E., Perez-Hoyos, S., Simon-Miller, A., Rojas, J.F., Gomez, J.M., Yanamandra-Fisher, P., Fletcher, L., Joels, J., Kemerer, J., Hora, J., Karkoschka, E., de Pater, I., Wong, M.H., Marcus, P.S., Pinilla-Alonso, N., Carvalho, F., Go, C., Parker, D., Salway, M., Valimberti, M., and Pujic, Z.

Abstract

Nature 451, 437-440 (2008) In Fig. 3a, the descriptions of the continuous and dotted curves were inadvertently swapped. The continuous line corresponds to the modified synthetic thermal profile (storms reaching [...]

Published

2007

14. Constraints on the composition of Jupiter's stratospheric aerosols from ultraviolet photometry

Author

Tomasko, M. G, Karkoschka, E, and Martinek, S

Subjects

Lunar And Planetary Exploration

Abstract

The absolute reflectivity of Jupiter has been obtained in 50 A-wide regions centering on 0.221, 0.233, 0.252, and 0.330 microns from three series of IUE satellite spectra taken in November 1979. The data indicate a strong decrease in reflectivity for latitudes greater than about 30 deg, in keeping with Voyager measurements. An additional 24 spectra were also obtained in a west-east series along the equator, as well as near 40 deg N latitude. These data favor models in which the haze particles have effective radii within a factor of 2 of 0.2 microns. Near the equator, the haze aerosols produce much less absorption than near 40 deg N; the aerosol distributions and optical properties derived are noted to be more dependent on the assumed location and reflectivity of the top of the tropospheric cloud.

Published

1986

15. Erratum: Depth of a strong jovian jet from a planetary-scale disturbance driven by storms

Author

Sánchez-Lavega, A., primary, Orton, G. S., additional, Hueso, R., additional, García-Melendo, E., additional, Pérez-Hoyos, S., additional, Simon-Miller, A., additional, Rojas, J. F., additional, Gómez, J. M., additional, Yanamandra-Fisher, P., additional, Fletcher, L., additional, Joels, J., additional, Kemerer, J., additional, Hora, J., additional, Karkoschka, E., additional, de Pater, I., additional, Wong, M. H., additional, Marcus, P. S., additional, Pinilla-Alonso, N., additional, Carvalho, F., additional, Go, C., additional, Parker, D., additional, Salway, M., additional, Valimberti, M., additional, Wesley, A., additional, and Pujic, Z., additional

Published

2008

16. Hubble space telescope visible imaging of Jupiter during the Comet crash

Author

Hammel, H. B., Beebe, R. F., Ingersoll, A. P., Orton, G. S., Mills, J. R., Simon, A. A., Chodas, P., Clarke, J. T., De Jong, E., Dowling, T. E., Harrington, J., Huber, L. F., Karkoschka, E., Santori, C. M., Toigo, A., Yeomans, D., West, R. A., Hammel, H. B., Beebe, R. F., Ingersoll, A. P., Orton, G. S., Mills, J. R., Simon, A. A., Chodas, P., Clarke, J. T., De Jong, E., Dowling, T. E., Harrington, J., Huber, L. F., Karkoschka, E., Santori, C. M., Toigo, A., Yeomans, D., and West, R. A.

Abstract

In July 1994, the fragments of Comet Shoemaker-Levy 9 plunged into Jupiter. We present preliminary results from analysis of the Hubble Space Telescope (HST) imaging observations of Jupiter obtained before, during, and after the impacts. We discuss observations of observed phenomena ranging from plumes to waves to atmospheric evolution. We report positions of all detected impact sites (we could not locate F, P2, T, U, and V). By comparing predicted and observed impact longitudes, we estimate the actual impact time. On average, impacts occurred about 8 minutes later than predicted, although this varied from on time to more than 15 minutes late. We also present an assessment of the relative size of the disturbance for each event. HST images showed the development of several of the erupting plumes (A, E, G, and W) over a period of about 20 minutes. In three cases (A, G, and W), we may have detected the incoming bolide, although alternative explanations for pre-plume flashes are possible. For fragments E, G, and W, we detected the 10 to 15 km/sec. A fascinating and unexpected feature of the impact plumes is that they all appear to reach the same height (about 3300 km) regardless of the size of the impactor that generated them. This point greatly confounded the impact modelers, who planned to use the plume heights to estimate the diameter of the impacting comet fragments.

Published

1995

17. MP3 - A meteorology and physical properties package to explore air-sea interaction on Titan

Author

Lorenz, R. D., Stofan, E., Lunine, J. I., Zarnecki, J. C., Harri, A.-M., Karkoschka, E., Newman, C. E., Bierhaus, E. B., Clark, B. C., Yelland, M., Leese, M. R., Boldt, J., Darlington, E., Neish, C. D., Sotzen, K., Arvelo, J., Rasbach, C., Kretsch, W., Strohbehn, K., Grey, M., Mann, J., Zimmermann, H., Reed, C., Lorenz, R. D., Stofan, E., Lunine, J. I., Zarnecki, J. C., Harri, A.-M., Karkoschka, E., Newman, C. E., Bierhaus, E. B., Clark, B. C., Yelland, M., Leese, M. R., Boldt, J., Darlington, E., Neish, C. D., Sotzen, K., Arvelo, J., Rasbach, C., Kretsch, W., Strohbehn, K., Grey, M., Mann, J., Zimmermann, H., and Reed, C.

Abstract

The exchange of mass, heat and momentum at the air:sea interface are profound influences on the terrestrial environment, affecting the intensity of hurricanes, the size of waves and lake-effect precipitation. Titan presents us with an opportunity to study these processes in a novel physical context, with a different sea, atmosphere and gravity. The MP3 instrument, under development for the proposed Discovery mission TiME (Titan Mare Explorer [1,2]) is an integrated suite of small, simple sensors that combines the function of traditional meteorology packages with liquid physical properties and depth-sounding : these latter functions follow the concept of - and indeed use spare elements from - the Huygens Surface Science Package (SSP,[3]). However, unlike Huygens’ brief and dynamic 3 hours of measurement, in TiME’s 6-Titan-day (96 Earth day) nominal mission enabled by radioisotope power, MP3 will have an unprecedented long-term measurement opportunity in one of the most evocative environments in the solar system, Titan’s sea Ligeia Mare.

18. Exploring the seas of Titan: the Titan Mare Eplorer (TiME) mission

Author

Stofan, E. R., Lunine, J. I., Lorenz, R. D., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H., Zarnecki, J., Stofan, E. R., Lunine, J. I., Lorenz, R. D., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H., and Zarnecki, J.

19. Titan Mare Explorer (TiME): first in situ exploration of an extraterrestrial sea

Author

Stofan, E. R., Lorenz, R. D., Lunine, J. I., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H, Zarnecki, J., Stofan, E. R., Lorenz, R. D., Lunine, J. I., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H, and Zarnecki, J.

Abstract

The lakes and seas of Titan are a sink of products of photolysis in the atmosphere, and a crucial component in Titan's active methane cycle. In situ exploration of the seas is necessary to understand their intriguing prebiotic organic chemistry.

20. MP3 - A meteorology and physical properties package to explore air-sea interaction on Titan

Author

Lorenz, R. D., Stofan, E., Lunine, J. I., Zarnecki, J. C., Harri, A.-M., Karkoschka, E., Newman, C. E., Bierhaus, E. B., Clark, B. C., Yelland, M., Leese, M. R., Boldt, J., Darlington, E., Neish, C. D., Sotzen, K., Arvelo, J., Rasbach, C., Kretsch, W., Strohbehn, K., Grey, M., Mann, J., Zimmermann, H., Reed, C., Lorenz, R. D., Stofan, E., Lunine, J. I., Zarnecki, J. C., Harri, A.-M., Karkoschka, E., Newman, C. E., Bierhaus, E. B., Clark, B. C., Yelland, M., Leese, M. R., Boldt, J., Darlington, E., Neish, C. D., Sotzen, K., Arvelo, J., Rasbach, C., Kretsch, W., Strohbehn, K., Grey, M., Mann, J., Zimmermann, H., and Reed, C.

Abstract

The exchange of mass, heat and momentum at the air:sea interface are profound influences on the terrestrial environment, affecting the intensity of hurricanes, the size of waves and lake-effect precipitation. Titan presents us with an opportunity to study these processes in a novel physical context, with a different sea, atmosphere and gravity. The MP3 instrument, under development for the proposed Discovery mission TiME (Titan Mare Explorer [1,2]) is an integrated suite of small, simple sensors that combines the function of traditional meteorology packages with liquid physical properties and depth-sounding : these latter functions follow the concept of - and indeed use spare elements from - the Huygens Surface Science Package (SSP,[3]). However, unlike Huygens’ brief and dynamic 3 hours of measurement, in TiME’s 6-Titan-day (96 Earth day) nominal mission enabled by radioisotope power, MP3 will have an unprecedented long-term measurement opportunity in one of the most evocative environments in the solar system, Titan’s sea Ligeia Mare.

21. Exploring the seas of Titan: the Titan Mare Eplorer (TiME) mission

Author

Stofan, E. R., Lunine, J. I., Lorenz, R. D., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H., Zarnecki, J., Stofan, E. R., Lunine, J. I., Lorenz, R. D., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H., and Zarnecki, J.

22. Titan Mare Explorer (TiME): first in situ exploration of an extraterrestrial sea

Author

Stofan, E. R., Lorenz, R. D., Lunine, J. I., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H, Zarnecki, J., Stofan, E. R., Lorenz, R. D., Lunine, J. I., Aharonson, O., Bierhaus, E., Clark, B., Griffith, C., Harri, A.-M., Karkoschka, E., Kirk, R., Kantsiper, B., Mahaffy, P., Newman, C., Ravine, M., Trainer, M., Waite, H, and Zarnecki, J.

Abstract

The lakes and seas of Titan are a sink of products of photolysis in the atmosphere, and a crucial component in Titan's active methane cycle. In situ exploration of the seas is necessary to understand their intriguing prebiotic organic chemistry.

23. Titan's diverse landscapes as evidenced by Cassini RADAR's third and fourth looks at Titan

Author

L. Roth, Y. Anderson, Rosaly M. C. Lopes, S. D. Wall, Bashar Rizk, R. Boehmer, William T. K. Johnson, Roberto Orosei, S. Hensley, Robert West, Bobby Kazeminejad, Yonggyu Gim, K. Kelleher, M. A. Janssen, Giorgio Franceschetti, Howard A. Zebker, G. Hamilton, Pierre Encrenaz, Laurence A. Soderblom, Roberto Seu, Flora Paganelli, S. Shaffer, Francesco Posa, Steven J. Ostro, Ralph D. Lorenz, Enrico Flamini, Randolph L. Kirk, Jani Radebaugh, Charles A. Wood, C. See, Charles Elachi, P. Paillou, Philip S. Callahan, Michael Allison, Jonathan I. Lunine, Lauren Wye, Elisabeth A. McFarlane, Ellen R. Stofan, S. Vetrella, Bryan Stiles, Giovanni Picardi, Duane O. Muhleman, Erich Karkoschka, Giovanni Alberti, Lunine, J. I., Elachi, C., Wall, S. D., Janssen, M. A., Allison, M. D., Anderson, Y., Boehmer, R., Callahan, P., Encrenaz, P., Flamini, E., Franceschetti, G., Gim, Y., Hamilton, G., Hensley, S., Johnson, W. T. K., Kelleher, K., Kirk, R. L., Lopes, R. M., Lorenz, R. D., Muhleman, D. O., Orosei, R., Ostro, S. J., Paganelli, F., Paillou, P., Picardi, G., Posa, F., Radebaugh, J., Roth, L. E., Seu, R., Shaffer, S., Soderblom, L. A., Stiles, B., Stofan, E. R., Vetrella, Sergio, West, R., Wood, C. A., Wye, L., Zebker, H., Alberti, G., Karkoschka, E., Rizk, B., Mcfarlane, E., See, C., Kazeminejad, B., Lunar and Planetary Laboratory [Tucson] (LPL), University of Arizona, Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Istituto di Fisica dello Spazio Interplanetario (IFSI), Consiglio Nazionale delle Ricerche (CNR), NASA Goddard Institute for Space Studies (GISS), NASA Goddard Space Flight Center (GSFC), Observatoire de Paris - Site de Paris (OP), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), Facoltá di Ingegneria, Facoltá di Ingegneria, Naples, US Geological Survey [Flagstaff], United States Geological Survey [Reston] (USGS), Division of Geological and Planetary Sciences [Pasadena], California Institute of Technology (CALTECH), CNR-IASF, Laboratoire d'astrodynamique, d'astrophysique et d'aéronomie de bordeaux (L3AB), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Sciences et Technologies - Bordeaux 1, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Dipartimento Interateneo di Fisica, Politecnico di Bari, Proxemy Research Inc, Planetary Science Institute [Tucson] (PSI), Stanford University, Department of Electrical Engineering [Stanford], CO.RI.S.T.A., European Space Department, Johns Hopkins University (JHU), Johns Hopkins University Applied Physics Laboratory [Laurel, MD] (APL), Dept. Geological Sciences, and Brigham Young University (BYU)

Subjects

Synthetic aperture radar, 010504 meteorology & atmospheric sciences, Terrain, radar observations, surfaces, 01 natural sciences, law.invention, Latitude, Sand dune stabilization, Astrobiology, [PHYS.ASTR.CO]Physics [physics]/Astrophysics [astro-ph]/Cosmology and Extra-Galactic Astrophysics [astro-ph.CO], symbols.namesake, Paleontology, geological processes, geophysics, satellites, titan, law, 0103 physical sciences, Radar, 010303 astronomy & astrophysics, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, [SDU.ASTR]Sciences of the Universe [physics]/Astrophysics [astro-ph], Titan moon, Astronomy and Astrophysics, Crust, Tectonics, Radar imaging, Space and Planetary Science, Physical Sciences, symbols, Cassini, Titan (rocket family), Geology

Abstract

International audience; Cassini's third and fourth radar flybys, T7 and T8, covered diverse terrains in the high southern and equatorial latitudes, respectively. The T7 synthetic aperture radar (SAR) swath is somewhat more straightforward to understand in terms of a progressive poleward descent from a high, dissected, and partly hilly terrain down to a low flat plain with embayments and deposits suggestive of the past or even current presence of hydrocarbon liquids. The T8 swath is dominated by dunes likely made of organic solids, but also contain somewhat enigmatic, probably tectonic, features that may be partly buried or degraded by erosion or relaxation in a thin crust. The dark areas in T7 show no dune morphology, unlike the dark areas in T8, but are radiometrically warm like the dunes. The Huygens landing site lies on the edge of the T8 swath; correlation of the radar and Huygens DISR images allows accurate determination of its coordinates, and indicates that to the north of the landing site sit two large longitudinal dunes. Indeed, had the Huygens probe trajectory been just 10 km north of where it actually was, images of large sand dunes would have been returned in place of the fluvially dissected terrain actually seen?illustrating the strong diversity of Titan's landscapes even at local scales.

Published

2008

24. Clouds of high contrast on Uranus.

Author

Karkoschka E

Subjects

Atmosphere, Methane, Extraterrestrial Environment, Uranus

Abstract

Near-infrared images of Uranus taken with the Hubble Space Telescope in July and October 1997 revealed discrete clouds with contrasts exceeding 10 times the highest contrast observed before with other techniques. At visible wavelengths, these 10 clouds had lower contrasts than clouds seen by Voyager 2 in 1986. Uranus' rotational rates for southern latitudes were identical in 1986 and 1997. Clouds in northern latitudes rotate slightly more slowly than clouds in opposite southern latitudes.

Published

1998

25. Impact debris particles in Jupiter's stratosphere.

Author

West RA, Karkoschka E, Friedson AJ, Seymour M, Baines KH, and Hammel HB

Subjects

Atmosphere, Nitrogen analysis, Sulfur analysis, Temperature, Extraterrestrial Environment, Jupiter, Solar System

Abstract

The aftermath of the impacts of periodic comet Shoemaker-Levy 9 on Jupiter was studied with the Wide Field Planetary Camera 2 on the Hubble Space Telescope. The impact debris particles may owe their dark brown color to organic material rich in sulfur and nitrogen. The total volume of aerosol 1 day after the last impact is equal to the volume of a sphere of radius 0.5 kilometer. In the optically thick core regions, the particle mean radius is between 0.15 and 0.3 micrometer, and the aerosol is spread over many scale heights, from approximately 1 millibar to 200 millibars of pressure or more. Particle coagulation can account for the evolution of particle radius and total optical depth during the month following the impacts.

Published

1995