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2. The Mapping Imaging Spectrometer for Europa (MISE)

Author

Blaney, Diana L., Hibbitts, Karl, Diniega, Serina, Davies, Ashley Gerard, Clark, Roger N., Green, Robert O., Hedman, Matthew, Langevin, Yves, Lunine, Jonathan, McCord, Thomas B., Murchie, Scott, Paranicas, Chris, Seelos, Frank, Soderblom, Jason M., Cable, Morgan L., Eckert, Regina, Thompson, David R., Trumbo, Samantha K., Bruce, Carl, Lundeen, Sarah R., Bender, Holly A., Helmlinger, Mark C., Moore, Lori B., Mouroulis, Pantazis, Small, Zachary, Tang, Hong, Van Gorp, Byron, Sullivan, Peter W., Zareh, Shannon, Rodriquez, Jose I., McKinley, Ian, Hahn, Daniel V., Bowers, Matthew, Hourani, Ramsey, Bryce, Brian A., Nuding, Danielle, Bailey, Zachery, Rettura, Alessandro, and Zarate, Evan D.

Published
2024
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3. Modeling the formation of Selk impact crater on Titan: Implications for Dragonfly

Author

Wakita, Shigeru, Johnson, Brandon C., Soderblom, Jason M., Shah, Jahnavi, Neish, Catherine D., and Steckloff, Jordan K.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Selk crater is an $\sim$ 80 km diameter impact crater on the Saturnian icy satellite, Titan. Melt pools associated with impact craters like Selk provide environments where liquid water and organics can mix and produce biomolecules like amino acids. It is partly for this reason that the Selk region has been selected as the area that NASA's Dragonfly mission will explore and address one of its primary goals: to search for biological signatures on Titan. Here we simulate Selk-sized impact craters on Titan to better understand the formation of Selk and its melt pool. We consider several structures for the icy target material by changing the thickness of the methane clathrate layer, which has a substantial effect on the target thermal structure and crater formation. Our numerical results show that a 4 km-diameter-impactor produces a Selk-sized crater when 5-15 km thick methane clathrate layers are considered. We confirm the production of melt pools in these cases and find that the melt volumes are similar regardless of methane clathrate layer thickness. The distribution of the melted material, however, is sensitive to the thickness of the methane clathrate layer. The melt pool appears as a torus-like shape with a few km depth in the case of 10-15 km thick methane clathrate layer, and as a shallower layer in the case of a 5 km thick clathrate layer. Melt pools of this thickness may take tens of thousands of years to freeze, allowing more time for complex organics to form., Comment: 32 pages, 11 figures, accepted for publication in PSJ

Published
2023
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4. Science Overview of the Europa Clipper Mission

Author

Pappalardo, Robert T., Buratti, Bonnie J., Korth, Haje, Senske, David A., Blaney, Diana L., Blankenship, Donald D., Burch, James L., Christensen, Philip R., Kempf, Sascha, Kivelson, Margaret G., Mazarico, Erwan, Retherford, Kurt D., Turtle, Elizabeth P., Westlake, Joseph H., Paczkowski, Brian G., Ray, Trina L., Kampmeier, Jennifer, Craft, Kate L., Howell, Samuel M., Klima, Rachel L., Leonard, Erin J., Matiella Novak, Alexandra, Phillips, Cynthia B., Daubar, Ingrid J., Blacksberg, Jordana, Brooks, Shawn M., Choukroun, Mathieu N., Cochrane, Corey J., Diniega, Serina, Elder, Catherine M., Ernst, Carolyn M., Gudipati, Murthy S., Luspay-Kuti, Adrienn, Piqueux, Sylvain, Rymer, Abigail M., Roberts, James H., Steinbrügge, Gregor, Cable, Morgan L., Scully, Jennifer E. C., Castillo-Rogez, Julie C., Hay, Hamish C. F. C., Persaud, Divya M., Glein, Christopher R., McKinnon, William B., Moore, Jeffrey M., Raymond, Carol A., Schroeder, Dustin M., Vance, Steven D., Wyrick, Danielle Y., Zolotov, Mikhail Y., Hand, Kevin P., Nimmo, Francis, McGrath, Melissa A., Spencer, John R., Lunine, Jonathan I., Paty, Carol S., Soderblom, Jason M., Collins, Geoffrey C., Schmidt, Britney E., Rathbun, Julie A., Shock, Everett L., Becker, Tracy C., Hayes, Alexander G., Prockter, Louise M., Weiss, Benjamin P., Hibbitts, Charles A., Moussessian, Alina, Brockwell, Timothy G., Hsu, Hsiang-Wen, Jia, Xianzhe, Gladstone, G. Randall, McEwen, Alfred S., Patterson, G. Wesley, McNutt, Jr., Ralph L., Evans, Jordan P., Larson, Timothy W., Cangahuala, L. Alberto, Havens, Glen G., Buffington, Brent B., Bradley, Ben, Campagnola, Stefano, Hardman, Sean H., Srinivasan, Jeffrey M., Short, Kendra L., Jedrey, Thomas C., St. Vaughn, Joshua A., Clark, Kevin P., Vertesi, Janet, and Niebur, Curt

Published
2024
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5. 8 Lunar Impact Features and Processes

Author

Osinski, Gordon R., primary, Melosh, H. Jay, additional, Andrews-Hanna, Jeff, additional, Baker, David, additional, Denevi, Brett, additional, Dhingra, Deepak, additional, Ghent, Rebecca, additional, Hayne, Paul O., additional, Hill, Patrick, additional, James, Peter B., additional, Jaret, Steven, additional, Johnson, Brandon, additional, Kenkmann, Thomas, additional, Kring, David, additional, Mahanti, Prasun, additional, Minton, David, additional, Neish, Catherine D., additional, Neumann, Greg, additional, Plescia, Jeff, additional, Potter, Ross W. K., additional, Richardson, Jim, additional, Silber, Elizabeth A., additional, Soderblom, Jason M., additional, Zanetti, Michael, additional, and Zellner, Nicolle, additional

Published
2024
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6. Methane-saturated layers limit the observability of impact craters on Titan

Author

Wakita, Shigeru, Johnson, Brandon C., Soderblom, Jason M., Shah, Jahnavi, and Neish, Catherine D.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

As the only icy satellite with a thick atmosphere and liquids on its surface, Titan represents a unique end-member to study the impact cratering process. Unlike craters on other Saturnian satellites, Titan's craters are preferentially located in high-elevation regions near the equator. This led to the hypothesis that the presence of liquid methane in Titan's lowlands affects crater morphology, making them difficult to identify. This is because surfaces covered by weak fluid-saturated sediment limit the topographic expression of impact craters, as sediment moves into the crater cavity shortly after formation. Here we simulate crater-forming impacts on Titan's surface, exploring how a methane-saturated layer overlying a methane-clathrate layer affects crater formation. Our numerical results show that impacts form smaller craters in a methane-clathrate basement than a water-ice basement, due to the differences in strength. We find that the addition of a methane-saturated layer atop this basement reduces crater depths and influences crater morphology. The morphology of impact craters formed in a thin methane-saturated layer are similar to those in a "dry" target, but a thick saturated layer produces an impact structure with little to no topography. A thick methane-saturated layer (thicker than 40% of the impactor diameter) could explain the dearth of craters in the low-elevation regions on Titan., Comment: 33 pages, 12 figures, accepted for publication in PSJ

Published
2022
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7. Science goals and new mission concepts for future exploration of Titan's atmosphere geology and habitability: Titan POlar Scout/orbitEr and In situ lake lander and DrONe explorer (POSEIDON)

Author

Rodriguez, Sébastien, Vinatier, Sandrine, Cordier, Daniel, Tobie, Gabriel, Achterberg, Richard K., Anderson, Carrie M., Badman, Sarah V., Barnes, Jason W., Barth, Erika L., Bézard, Bruno, Carrasco, Nathalie, Charnay, Benjamin, Clark, Roger N., Coll, Patrice, Cornet, Thomas, Coustenis, Athena, Couturier-Tamburelli, Isabelle, Dobrijevic, Michel, Flasar, F. Michael, de Kok, Remco, Freissinet, Caroline, Galand, Marina, Gautier, Thomas, Geppert, Wolf D., Griffith, Caitlin A., Gudipati, Murthy S., Hadid, Lina Z., Hayes, Alexander G., Hendrix, Amanda R., Jauman, Ralf, Jennings, Donald E., Jolly, Antoine, Kalousova, Klara, Koskinen, Tommi T., Lavvas, Panayotis, Lebonnois, Sébastien, Lebreton, Jean-Pierre, Gall, Alice Le, Lellouch, Emmanuel, Mouélic, Stéphane Le, Lopes, Rosaly M. C., Lora, Juan M., Lorenz, Ralph D., Lucas, Antoine, MacKenzie, Shannon, Malaska, Michael J., Mandt, Kathleen, Mastrogiuseppe, Marco, Newman, Claire E., Nixon, Conor A., Radebaugh, Jani, Rafkin, Scot C., Rannou, Pascal, Sciamma-O-Brien, Ella M., Soderblom, Jason M., Solomonidou, Anezina, Sotin, Christophe, Stephan, Katrin, Strobel, Darrell, Szopa, Cyril, Teanby, Nicholas A., Turtle, Elizabeth P., Vuitton, Véronique, and West, Robert A.

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

In response to ESA Voyage 2050 announcement of opportunity, we propose an ambitious L-class mission to explore one of the most exciting bodies in the Solar System, Saturn largest moon Titan. Titan, a "world with two oceans", is an organic-rich body with interior-surface-atmosphere interactions that are comparable in complexity to the Earth. Titan is also one of the few places in the Solar System with habitability potential. Titan remarkable nature was only partly revealed by the Cassini-Huygens mission and still holds mysteries requiring a complete exploration using a variety of vehicles and instruments. The proposed mission concept POSEIDON (Titan POlar Scout/orbitEr and In situ lake lander DrONe explorer) would perform joint orbital and in situ investigations of Titan. It is designed to build on and exceed the scope and scientific/technological accomplishments of Cassini-Huygens, exploring Titan in ways that were not previously possible, in particular through full close-up and in situ coverage over long periods of time. In the proposed mission architecture, POSEIDON consists of two major elements: a spacecraft with a large set of instruments that would orbit Titan, preferably in a low-eccentricity polar orbit, and a suite of in situ investigation components, i.e. a lake lander, a "heavy" drone (possibly amphibious) and/or a fleet of mini-drones, dedicated to the exploration of the polar regions. The ideal arrival time at Titan would be slightly before the next northern Spring equinox (2039), as equinoxes are the most active periods to monitor still largely unknown atmospheric and surface seasonal changes. The exploration of Titan northern latitudes with an orbiter and in situ element(s) would be highly complementary with the upcoming NASA New Frontiers Dragonfly mission that will provide in situ exploration of Titan equatorial regions in the mid-2030s., Comment: arXiv admin note: substantial text overlap with arXiv:1908.01374

Published
2021
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8. The Science Case for a Titan Flagship-class Orbiter with Probes

Author

Nixon, Conor A., Abshire, James, Ashton, Andrew, Barnes, Jason W., Carrasco, Nathalie, Choukroun, Mathieu, Coustenis, Athena, Couston, Louis-Alexandre, Edberg, Niklas, Gagnon, Alexander, Hofgartner, Jason D., Iess, Luciano, Mouélic, Stéphane Le, Lopes, Rosaly, Lora, Juan, Lorenz, Ralph D., Luspay-Kuti, Adrienn, Malaska, Michael, Mandt, Kathleen, Mastrogiuseppe, Marco, Mazarico, Erwan, Neveu, Marc, Perron, Taylor, Radebaugh, Jani, Rodriguez, Sébastien, Salama, Farid, Schoenfeld, Ashley, Soderblom, Jason M., Solomonidou, Anezina, Snowden, Darci, Sun, Xioali, Teanby, Nicholas, Tobie, Gabriel, Trainer, Melissa G., Tucker, Orenthal J., Turtle, Elizabeth P., Vinatier, Sandrine, Vuitton, Véronique, and Zhang, Xi

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

We outline a flagship-class mission concept focused on studying Titan as a global system, with particular emphasis on the polar regions. Investigating Titan from the unique standpoint of a polar orbit would enable comprehensive global maps to uncover the physics and chemistry of the atmosphere, and the topography and geophysical environment of the surface and subsurface. The mission includes two key elements: (1) an orbiter spacecraft, which also acts as a data relay, and (2) one or more small probes to directly investigate Titan's seas and make the first direct measurements of their liquid composition and physical environment. The orbiter would carry a sophisticated remote sensing payload, including a novel topographic lidar, a long-wavelength surface-penetrating radar, a sub-millimeter sounder for winds and for mesospheric/thermospheric composition, and a camera and near-infrared spectrometer. An instrument suite to analyze particles and fields would include a mass spectrometer to focus on the interactions between Titan's escaping upper atmosphere and the solar wind and Saturnian magnetosphere. The orbiter would enter a stable polar orbit around 1500 to 1800 km, from which vantage point it would make global maps of the atmosphere and surface. One or more probes, released from the orbiter, would investigate Titan's seas in situ, including possible differences in composition between higher and lower latitude seas, as well as the atmosphere during the parachute descent. The number of probes, as well as the instrument complement on the orbiter and probe, remain to be finalized during a mission study that we recommend to NASA as part of the NRC Decadal Survey for Planetary Science now underway, with the goal of an overall mission cost in the "small flagship" category of ~$2 bn. International partnerships, similar to Cassini-Huygens, may also be included for consideration., Comment: 13 pages, white paper submitted to the NRC Decadal Survey for Planetary Science and Astrobiology

Published
2020

9. Tidal Currents Detected in Kraken Mare Straits from Cassini VIMS Sun Glitter Observations

Author

Heslar, Michael F., Barnes, Jason W., Soderblom, Jason M., Seignovert, Benoit, Dhingra, Rajani D., and Sotin, Christophe

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

We present Cassini VIMS observations of sun glitter -- wave-induced reflections from a liquid surface offset from a specular point -- on Kraken Mare. Sun glitter reveals rough sea surfaces around Kraken Mare, namely the coasts and narrow straits. The sun glitter observations indicate wave activity driven by the winds and tidal currents in Kraken Mare during northern summer. T104 Cassini VIMS observations show three sun glitter features in Bayta Fretum indicative of variegated wave fields. We cannot uniquely determine one source for the coastal Bayta waves, but we lean toward the interpretation of surface winds, because tidal currents should be too weak to generate capillary-gravity waves in Bayta Fretum. T105 and T110 observations reveal wave fields in the straits of Seldon Fretum, Lulworth Sinus, and Tunu Sinus that likely originate from the constriction of tidal currents. Coastlines of Bermoothes and Hufaidh Insulae adjoin rough sea surfaces, suggesting a complex interplay of wind-roughened seas and localized tidal currents. Bermoothes and Hufaidh Insulae may share characteristics of either the Torres Strait off Australia or the Aland region of Finland, summarized as an island-dense strait with shallow bathymetry that hosts complex surface circulation patterns. Hufaidh Insulae could host seafloor bedforms formed by tidal currents with an abundant sediment supply, similar to the Torres Strait. The coastlines of Hufaidh and Bermoothes Insulae likely host ria or flooded coastal inlets, suggesting the Insulae may be local peaks of primordial crust isolated by an episode of sea-level rise or tectonic uplift., Comment: Accepted to the Planetary Science Journal, 25 pages, 13 figures

Published
2020

10. Stratification Dynamics of Titan's Lakes via Methane Evaporation

Author

Steckloff, Jordan K., Soderblom, Jason M., Farnsworth, Kendra K., Chevrier, Vincent F., Hanley, Jennifer, Soto, Alejandro, Groven, Jessica J., Grundy, William M., Pearce, Logan A., Tegler, Stephen C., and Engle, Anna

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Saturn's moon Titan is the only extraterrestrial body known to host stable lakes and a hydrological cycle. Titan's lakes predominantly contain liquid methane, ethane, and nitrogen, with methane evaporation driving its hydrological cycle. Molecular interactions between these three species lead to non-ideal behavior that causes Titan's lakes to behave differently than Earth's lakes. Here, we numerically investigate how methane evaporation and non-ideal interactions affect the physical properties, structure, dynamics, and evolution of shallow lakes on Titan. We find that, under certain temperature regimes, methane-rich mixtures are denser than relatively ethane-rich mixtures. This allows methane evaporation to stratify Titan's lakes into ethane-rich upper layers and methane-rich lower layers, separated by a strong compositional gradient. At temperatures above 86K, lakes remain well-mixed and unstratified. Between 84 and 86K, lakes can stratify episodically. Below 84K, lakes permanently stratify, and develop very methane-depleted epilimnia. Despite small seasonal and diurnal deviations (<5K) from typical surface temperatures, Titan's rain-filled ephemeral lakes and "phantom lakes" may nevertheless experience significantly larger temperature fluctuations, resulting in polymictic or even meromictic stratification, which may trigger ethane ice precipitation.

Published
2020

11. Science goals and mission concepts for a future orbital and in situ exploration of Titan

Author

Rodriguez, Sébastien, Vinatier, Sandrine, Cordier, Daniel, Carrasco, Nathalie, Charnay, Benjamin, Cornet, Thomas, Coustenis, Athena, de Kok, Remco, Freissinet, Caroline, Galand, Marina, Geppert, Wolf D., Jauman, Ralf, Kalousova, Klara, Koskinen, Tommi T., Lebonnois, Sébastien, Gall, Alice Le, Mouélic, Stéphane Le, Lucas, Antoine, Mandt, Kathleen, Mastrogiuseppe, Marco, Nixon, Conor A., Radebaugh, Jani, Rannou, Pascal, Soderblom, Jason M., Solomonidou, Anezina, Sotin, Christophe, Stephan, Katrin, Teanby, Nick, Tobie, Gabriel, and Vuitton, Véronique

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

In this white paper, we present a cross-section of important scientific questions that remain partially or completely unanswered, ranging from Titan exosphere to the deep interior, and we detail which instrumentation and mission scenarios should be used to answer them. Our intention is to formulate the science goals for the next generation of planetary missions to Titan in order to prepare the future exploration of the moon. The ESA L-class mission concept that we propose is composed of a Titan orbiter and at least an in situ element (lake lander and/or drone(s))., Comment: White Paper submission to the call for ESA Voyage 2050 long-term plan

Published
2019

14. The NASA Roadmap to Ocean Worlds

Author

Hendrix, Amanda R, Hurford, Terry A, Barge, Laura M, Bland, Michael T, Bowman, Jeff S, Brinckerhoff, William, Buratti, Bonnie J, Cable, Morgan L, Castillo-Rogez, Julie, Collins, Geoffrey C, Diniega, Serina, German, Christopher R, Hayes, Alexander G, Hoehler, Tori, Hosseini, Sona, Howett, Carly JA, McEwen, Alfred S, Neish, Catherine D, Neveu, Marc, Nordheim, Tom A, Patterson, G Wesley, Patthoff, D Alex, Phillips, Cynthia, Rhoden, Alyssa, Schmidt, Britney E, Singer, Kelsi N, Soderblom, Jason M, and Vance, Steven D

Subjects
Astronomical Sciences, Physical Sciences, Life Below Water, Exobiology, Oceans and Seas, Planets, United States, United States National Aeronautics and Space Administration, Roadmap, Enceladus, Titan, Europa, Triton, NASA, NASA., Astronomical and Space Sciences, Geochemistry, Geology, Astronomy & Astrophysics, Astronomical sciences
Abstract

In this article, we summarize the work of the NASA Outer Planets Assessment Group (OPAG) Roadmaps to Ocean Worlds (ROW) group. The aim of this group is to assemble the scientific framework that will guide the exploration of ocean worlds, and to identify and prioritize science objectives for ocean worlds over the next several decades. The overarching goal of an Ocean Worlds exploration program as defined by ROW is to "identify ocean worlds, characterize their oceans, evaluate their habitability, search for life, and ultimately understand any life we find." The ROW team supports the creation of an exploration program that studies the full spectrum of ocean worlds, that is, not just the exploration of known ocean worlds such as Europa but candidate ocean worlds such as Triton as well. The ROW team finds that the confirmed ocean worlds Enceladus, Titan, and Europa are the highest priority bodies to target in the near term to address ROW goals. Triton is the highest priority candidate ocean world to target in the near term. A major finding of this study is that, to map out a coherent Ocean Worlds Program, significant input is required from studies here on Earth; rigorous Research and Analysis studies are called for to enable some future ocean worlds missions to be thoughtfully planned and undertaken. A second finding is that progress needs to be made in the area of collaborations between Earth ocean scientists and extraterrestrial ocean scientists.

Published
2019

15. Evidence of Titan's Climate History from Evaporite Distribution

Author

MacKenzie, Shannon M., Barnes, Jason W., Sotin, Christophe, Soderblom, Jason M., Mouélic, Stéphane Le, Rodriguez, Sebastien, Baines, Kevin H., Buratti, Bonnie J., Clark, Roger N., Nicholson, Phillip D., and McCord, Thomas B.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Water-ice-poor, 5-$\mu$m-bright material on Saturn's moon Titan has previously been geomorphologically identified as evaporitic. Here we present a global distribution of the occurrences of the 5-$\mu$m-bright spectral unit, identified with Cassini's Visual Infrared Mapping Spectrometer (VIMS) and examined with RADAR when possible. We explore the possibility that each of these occurrences are evaporite deposits. The 5-$\mu$m-bright material covers 1\% of Titan's surface and is not limited to the poles (the only regions with extensive, long-lived surface liquid). We find the greatest areal concentration to be in the equatorial basins Tui Regio and Hotei Regio. Our interpretations, based on the correlation between 5-$\mu$m-bright material and lakebeds, imply that there was enough liquid present at some time to create the observed 5-$\mu$m-bright material. We address the climate implications surrounding a lack of evaporitic material at the south polar basins: if the south pole basins were filled at some point in the past, then where is the evaporite?

Published
2014
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16. Evolution of Impact Melt Pools on Titan

Author

Kalousová, Klára, primary, Wakita, Shigeru, additional, Sotin, Christophe, additional, Neish, Catherine D., additional, Soderblom, Jason M., additional, Souček, Ondřej, additional, and Johnson, Brandon C., additional

Published
2024
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19. Explorer of Enceladus and Titan (E2T): Investigating ocean worlds' evolution and habitability in the solar system

Author

Mitri, Giuseppe, Postberg, Frank, Soderblom, Jason M., Wurz, Peter, Tortora, Paolo, Abel, Bernd, Barnes, Jason W., Berga, Marco, Carrasco, Nathalie, Coustenis, Athena, Paul de Vera, Jean Pierre, D'Ottavio, Andrea, Ferri, Francesca, Hayes, Alexander G., Hayne, Paul O., Hillier, Jon K., Kempf, Sascha, Lebreton, Jean-Pierre, Lorenz, Ralph D., Martelli, Andrea, Orosei, Roberto, Petropoulos, Anastassios E., Reh, Kim, Schmidt, Juergen, Sotin, Christophe, Srama, Ralf, Tobie, Gabriel, Vorburger, Audrey, Vuitton, Véronique, Wong, Andre, and Zannoni, Marco

Published
2018
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21. NEWTS1.0: Numerical model of coastal Erosion by Waves and Transgressive Scarps.

Author

Palermo, Rose V., Perron, J. Taylor, Soderblom, Jason M., Birch, Samuel P. D., Hayes, Alexander G., and Ashton, Andrew D.

Subjects
COASTAL changes, BEACH erosion, PHENOMENOLOGICAL theory (Physics)
Abstract

Models of rocky-coast erosion help us understand the physical phenomena that control coastal morphology and evolution, infer the processes shaping coasts in remote environments, and evaluate risk from natural hazards and future climate change. Existing models, however, are highly complex, are computationally expensive, and depend on many input parameters; this limits our ability to explore planform erosion of rocky coasts over long timescales (thousands to millions of years) and over a range of conditions. In this paper, we present a simplified cellular model of coastline evolution in closed basins through uniform erosion and wave-driven erosion. Uniform erosion is modeled as a constant rate of retreat. Wave erosion is modeled as a function of fetch, the distance over which the wind blows to generate waves, and the angle between the incident wave and the shoreline. This reduced-complexity model can be used to evaluate how a detachment-limited coastal landscape reflects climate, sea-level history, material properties, and the relative influence of different erosional processes. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Gravity field of the Orientale basin from the Gravity Recovery and Interior Laboratory Mission

Author

Zuber, Maria T., Smith, David E., Neumann, Gregory A., Goossens, Sander, Andrews-Hanna, Jeffrey C., Head, James W., Kiefer, Walter S., Asmar, Sami W., Konopliv, Alexander S., Lemoine, Frank G., Matsuyama, Isamu, Melosh, H. Jay, McGovern, Patrick J., Nimmo, Francis, Phillips, Roger J., Solomon, Sean C., Taylor, G. Jeffrey, Watkins, Michael M., Wieczorek, Mark A., Williams, James G., Jansen, Johanna C., Johnson, Brandon C., Keane, James T., Mazarico, Erwan, Miljković, Katarina, Park, Ryan S., Soderblom, Jason M., and Yuan, Dah-Ning

Published
2016

25. Formation of the Orientale lunar multiring basin

Author

Johnson, Brandon C., Blair, David M., Collins, Gareth S., Melosh, H. Jay, Freed, Andrew M., Taylor, G. Jeffrey, Head, James W., Wieczorek, Mark A., Andrews-Hanna, Jeffrey C., Nimmo, Francis, Keane, James T., Miljković, Katarina, Soderblom, Jason M., and Zuber, Maria T.

Published
2016

26. NEWTS1.0: Numerical model of coastal Erosion by Waves and Transgressive Scarps.

Author

Palermo, Rose V., Perron, J. Taylor, Soderblom, Jason M., Birch, Samuel P. D., Hayes, Alexander G., and Ashton, Andrew D.

Subjects
COASTAL changes, BEACH erosion, SEA level, PHENOMENOLOGICAL theory (Physics), MARITIME history
Abstract

Models of rocky coast erosion help us understand the physical phenomena that control coastal morphology and evolution, infer the processes shaping coasts in remote environments, and evaluate risk from natural hazards and future climate change. Existing models, however, are highly complex, computationally expensive, and depend on many input parameters; this limits our ability to explore planform erosion of rocky coasts over long timescales (100s to 100,000s years) and a range of conditions. In this paper, we present a simplified cellular model of coastline evolution through uniform erosion and wave-driven erosion. Uniform erosion is modeled as a constant rate of retreat. Wave erosion is modeled as a function of fetch, the distance over which the wind blows to generate waves, and the angle between the incident wave and the shoreline. This reduced complexity model can be used to evaluate how a detachment-limited coastal landscape reflects climate, sea level history, material properties, and the relative influence of different erosional processes. [ABSTRACT FROM AUTHOR]

Published
2023
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30. The NASA Roadmap to Ocean Worlds

Author

Hendrix, Amanda R, Hurford, Terry A, Barge, Laura M, Bland, Michael T, Bowman, Jeff S, Brinckerhoff, William, Buratti, Bonnie J, Cable, Morgan L, Castillo-Rogez, Julie, Collins, Geoffrey C, Diniega, Serina, German, Christopher R, Hayes, Alexander G, Hoehler, Tori, Hosseini, Sona, Howett, Carly J.A, McEwen, Alfred S, Neish, Catherine D, Neveu, Marc, Nordheim, Tom A, Patterson, G. Wesley, Patthoff, D. Alex, Phillips, Cynthia, Rhoden, Alyssa, Schmidt, Britney E, Singer, Kelsi N, Soderblom, Jason M, and Vance, Steven D

Subjects
Exobiology
Abstract

In this article, we summarize the work of the NASA Outer Planets Assessment Group (OPAG) Roadmaps to Ocean Worlds (ROW) group. The aim of this group is to assemble the scientific framework that will guide the exploration of ocean worlds, and to identify and prioritize science objectives for ocean worlds over the next several decades. The overarching goal of an Ocean Worlds exploration program as defined by ROW is to “identify ocean worlds, characterize their oceans, evaluate their habitability, search for life, and ultimately understand any life we find.” The ROW team supports the creation of an exploration program that studies the full spectrum of ocean worlds, that is, not just the exploration of known ocean worlds such as Europa but candidate ocean worlds such as Triton as well. The ROW team finds that the confirmed ocean worlds Enceladus, Titan, and Europa are the highest priority bodies to target in the near term to address ROW goals. Triton is the highest priority candidate ocean world to target in the near term. A major finding of this study is that, to map out a coherent Ocean Worlds Program, significant input is required from studies here on Earth; rigorous Research and Analysis studies are called for to enable some future ocean worlds missions to be thoughtfully planned and undertaken. A second finding is that progress needs to be made in the area of collaborations between Earth ocean scientists and extraterrestrial ocean scientists.

Published
2018
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32. Reconstructing river flows remotely on Earth, Titan, and Mars.

Author

Birch, Samuel P. D., Parker, Gary, Corlies, Paul, Soderblom, Jason M., Miller, Julia W., Palermo, Rose V., Lora, Juan M., Ashton, Andrew D., Hayes, Alexander G., and Perron, J. Taylor

Subjects
STREAMFLOW, EARTHFLOWS, MARS (Planet), GALE Crater (Mars), ALLUVIAL streams
Abstract

Alluvial rivers are conveyor belts of fluid and sediment that provide a record of upstream climate and erosion on Earth, Titan, and Mars. However, many of Earth’s rivers remain unsurveyed, Titan’s rivers are not well resolved by current spacecraft data, and Mars’ rivers are no longer active, hindering reconstructions of planetary surface conditions. To overcome these problems, we use dimensionless hydraulic geometry relations—scaling laws that relate river channel dimensions to flow and sediment transport rates—to calculate in-channel conditions using only remote sensing measurements of channel width and slope. On Earth, this offers a way to predict flow and sediment flux in rivers that lack field measurements and shows that the distinct dynamics of bedload-dominated, suspended load-dominated, and bedrock rivers give rise to distinct channel characteristics. On Mars, this approach not only predicts grain sizes at Gale Crater and Jezero Crater that overlap with those measured by the Curiosity and Perseverance rovers, it enables reconstructions of past flow conditions that are consistent with proposed long-lived hydrologic activity at both craters. On Titan, our predicted sediment fluxes to the coast of Ontario Lacus could build the lake’s river delta in as little as ~1,000 y, and our scaling relationships suggest that Titan’s rivers may be wider, slope more gently, and transport sediment at lower flows than rivers on Earth or Mars. Our approach provides a template for predicting channel properties remotely for alluvial rivers across Earth, along with interpreting spacecraft observations of rivers on Titan and Mars. [ABSTRACT FROM AUTHOR]

Published
2023
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35. Science goals and new mission concepts for future exploration of Titan's atmosphere, geology and habitability : titan POlar scout/orbitEr and in situ lake lander and DrONe explorer (POSEIDON)

Author

Rodriguez, Sébastien, Vinatier, Sandrine, Cordier, Daniel, Tobie, Gabriel, Achterberg, Richard K., Anderson, Carrie M., Badman, Sarah V., Barnes, Jason W., Barth, Erika L., Bézard, Bruno, Carrasco, Nathalie, Charnay, Benjamin, Clark, Roger N., Coll, Patrice, Cornet, Thomas, Coustenis, Athena, Couturier-Tamburelli, Isabelle, Dobrijevic, Michel, Flasar, F. Michael, de Kok, Remco, Freissinet, Caroline, Galand, Marina, Gautier, Thomas, Geppert, Wolf D., Griffith, Caitlin A., Gudipati, Murthy S., Hadid, Lina Z., Hayes, Alexander G., Hendrix, Amanda R., Jaumann, Ralf, Jennings, Donald E., Jolly, Antoine, Kalousova, Klara, Koskinen, Tommi T., Lavvas, Panayotis, Lebonnois, Sébastien, Lebreton, Jean-Pierre, Le Gall, Alice, Lellouch, Emmanuel, Le Mouélic, Stéphane, Lopes, Rosaly M. C., Lora, Juan M., Lorenz, Ralph D., Lucas, Antoine, MacKenzie, Shannon, Malaska, Michael J., Mandt, Kathleen, Mastrogiuseppe, Marco, Newman, Claire E., Nixon, Conor A., Radebaugh, Jani, Rafkin, Scot C., Rannou, Pascal, Sciamma-O'Brien, Ella M., Soderblom, Jason M., Solomonidou, Anezina, Sotin, Christophe, Stephan, Katrin, Strobel, Darrell, Szopa, Cyril, Teanby, Nicholas A., Turtle, Elizabeth P., Vuitton, Véronique, West, Robert A., Rodriguez, Sébastien, Vinatier, Sandrine, Cordier, Daniel, Tobie, Gabriel, Achterberg, Richard K., Anderson, Carrie M., Badman, Sarah V., Barnes, Jason W., Barth, Erika L., Bézard, Bruno, Carrasco, Nathalie, Charnay, Benjamin, Clark, Roger N., Coll, Patrice, Cornet, Thomas, Coustenis, Athena, Couturier-Tamburelli, Isabelle, Dobrijevic, Michel, Flasar, F. Michael, de Kok, Remco, Freissinet, Caroline, Galand, Marina, Gautier, Thomas, Geppert, Wolf D., Griffith, Caitlin A., Gudipati, Murthy S., Hadid, Lina Z., Hayes, Alexander G., Hendrix, Amanda R., Jaumann, Ralf, Jennings, Donald E., Jolly, Antoine, Kalousova, Klara, Koskinen, Tommi T., Lavvas, Panayotis, Lebonnois, Sébastien, Lebreton, Jean-Pierre, Le Gall, Alice, Lellouch, Emmanuel, Le Mouélic, Stéphane, Lopes, Rosaly M. C., Lora, Juan M., Lorenz, Ralph D., Lucas, Antoine, MacKenzie, Shannon, Malaska, Michael J., Mandt, Kathleen, Mastrogiuseppe, Marco, Newman, Claire E., Nixon, Conor A., Radebaugh, Jani, Rafkin, Scot C., Rannou, Pascal, Sciamma-O'Brien, Ella M., Soderblom, Jason M., Solomonidou, Anezina, Sotin, Christophe, Stephan, Katrin, Strobel, Darrell, Szopa, Cyril, Teanby, Nicholas A., Turtle, Elizabeth P., Vuitton, Véronique, and West, Robert A.

Abstract

In response to ESA’s “Voyage 2050” announcement of opportunity, we propose an ambitious L-class mission to explore one of the most exciting bodies in the Solar System, Saturn’s largest moon Titan. Titan, a “world with two oceans”, is an organic-rich body with interior-surface-atmosphere interactions that are comparable in complexity to the Earth. Titan is also one of the few places in the Solar System with habitability potential. Titan’s remarkable nature was only partly revealed by the Cassini-Huygens mission and still holds mysteries requiring a complete exploration using a variety of vehicles and instruments. The proposed mission concept POSEIDON (Titan POlar Scout/orbitEr and In situ lake lander DrONe explorer) would perform joint orbital and in situ investigations of Titan. It is designed to build on and exceed the scope and scientific/technological accomplishments of Cassini-Huygens, exploring Titan in ways that were not previously possible, in particular through full close-up and in situ coverage over long periods of time. In the proposed mission architecture, POSEIDON consists of two major elements: a spacecraft with a large set of instruments that would orbit Titan, preferably in a low-eccentricity polar orbit, and a suite of in situ investigation components, i.e. a lake lander, a “heavy” drone (possibly amphibious) and/or a fleet of mini-drones, dedicated to the exploration of the polar regions. The ideal arrival time at Titan would be slightly before the next northern Spring equinox (2039), as equinoxes are the most active periods to monitor still largely unknown atmospheric and surface seasonal changes. The exploration of Titan’s northern latitudes with an orbiter and in situ element(s) would be highly complementary in terms of timing (with possible mission timing overlap), locations, and science goals with the upcoming NASA New Frontiers Dragonfly mission that will provide in situ exploration of Titan’s equatorial regions, in the mid-2030s.

Published
2022
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36. Science goals and new mission concepts for future exploration of Titan’s atmosphere, geology and habitability:titan POlar scout/orbitEr and in situ lake lander and DrONe explorer (POSEIDON)

Author

Rodriguez, Sébastien, Vinatier, Sandrine, Cordier, Daniel, Tobie, Gabriel, Achterberg, Richard K., Anderson, Carrie M., Badman, Sarah V., Barnes, Jason W., Barth, Erika L., Bézard, Bruno, Carrasco, Nathalie, Charnay, Benjamin, Clark, Roger N., Coll, Patrice, Cornet, Thomas, Coustenis, Athena, Couturier-Tamburelli, Isabelle, Dobrijevic, Michel, Flasar, F. Michael, de Kok, Remco, Freissinet, Caroline, Galand, Marina, Gautier, Thomas, Geppert, Wolf D., Griffith, Caitlin A., Gudipati, Murthy S., Hadid, Lina Z., Hayes, Alexander G., Hendrix, Amanda R., Jaumann, Ralf, Jennings, Donald E., Jolly, Antoine, Kalousova, Klara, Koskinen, Tommi T., Lavvas, Panayotis, Lebonnois, Sébastien, Lebreton, Jean-Pierre, Le Gall, Alice, Lellouch, Emmanuel, Le Mouélic, Stéphane, Lopes, Rosaly M. C., Lora, Juan M., Lorenz, Ralph D., Lucas, Antoine, MacKenzie, Shannon, Malaska, Michael J., Mandt, Kathleen, Mastrogiuseppe, Marco, Newman, Claire E., Nixon, Conor A., Radebaugh, Jani, Rafkin, Scot C., Rannou, Pascal, Sciamma-O’Brien, Ella M., Soderblom, Jason M., Solomonidou, Anezina, Sotin, Christophe, Stephan, Katrin, Strobel, Darrell, Szopa, Cyril, Teanby, Nicholas A., Turtle, Elizabeth P., Vuitton, Véronique, West, Robert A., Rodriguez, Sébastien, Vinatier, Sandrine, Cordier, Daniel, Tobie, Gabriel, Achterberg, Richard K., Anderson, Carrie M., Badman, Sarah V., Barnes, Jason W., Barth, Erika L., Bézard, Bruno, Carrasco, Nathalie, Charnay, Benjamin, Clark, Roger N., Coll, Patrice, Cornet, Thomas, Coustenis, Athena, Couturier-Tamburelli, Isabelle, Dobrijevic, Michel, Flasar, F. Michael, de Kok, Remco, Freissinet, Caroline, Galand, Marina, Gautier, Thomas, Geppert, Wolf D., Griffith, Caitlin A., Gudipati, Murthy S., Hadid, Lina Z., Hayes, Alexander G., Hendrix, Amanda R., Jaumann, Ralf, Jennings, Donald E., Jolly, Antoine, Kalousova, Klara, Koskinen, Tommi T., Lavvas, Panayotis, Lebonnois, Sébastien, Lebreton, Jean-Pierre, Le Gall, Alice, Lellouch, Emmanuel, Le Mouélic, Stéphane, Lopes, Rosaly M. C., Lora, Juan M., Lorenz, Ralph D., Lucas, Antoine, MacKenzie, Shannon, Malaska, Michael J., Mandt, Kathleen, Mastrogiuseppe, Marco, Newman, Claire E., Nixon, Conor A., Radebaugh, Jani, Rafkin, Scot C., Rannou, Pascal, Sciamma-O’Brien, Ella M., Soderblom, Jason M., Solomonidou, Anezina, Sotin, Christophe, Stephan, Katrin, Strobel, Darrell, Szopa, Cyril, Teanby, Nicholas A., Turtle, Elizabeth P., Vuitton, Véronique, and West, Robert A.

Abstract

In response to ESA’s “Voyage 2050” announcement of opportunity, we propose an ambitious L-class mission to explore one of the most exciting bodies in the Solar System, Saturn’s largest moon Titan. Titan, a “world with two oceans”, is an organic-rich body with interior-surface-atmosphere interactions that are comparable in complexity to the Earth. Titan is also one of the few places in the Solar System with habitability potential. Titan’s remarkable nature was only partly revealed by the Cassini-Huygens mission and still holds mysteries requiring a complete exploration using a variety of vehicles and instruments. The proposed mission concept POSEIDON (Titan POlar Scout/orbitEr and In situ lake lander DrONe explorer) would perform joint orbital and in situ investigations of Titan. It is designed to build on and exceed the scope and scientific/technological accomplishments of Cassini-Huygens, exploring Titan in ways that were not previously possible, in particular through full close-up and in situ coverage over long periods of time. In the proposed mission architecture, POSEIDON consists of two major elements: a spacecraft with a large set of instruments that would orbit Titan, preferably in a low-eccentricity polar orbit, and a suite of in situ investigation components, i.e. a lake lander, a “heavy” drone (possibly amphibious) and/or a fleet of mini-drones, dedicated to the exploration of the polar regions. The ideal arrival time at Titan would be slightly before the next northern Spring equinox (2039), as equinoxes are the most active periods to monitor still largely unknown atmospheric and surface seasonal changes. The exploration of Titan’s northern latitudes with an orbiter and in situ element(s) would be highly complementary in terms of timing (with possible mission timing overlap), locations, and science goals with the upcoming NASA New Frontiers Dragonfly mission that will provide in situ exploration of Titan’s equatorial regions, in the mid-2030s.

Published
2022

44. Science goals and new mission concepts for future exploration of Titan’s atmosphere, geology and habitability: titan POlar scout/orbitEr and in situ lake lander and DrONe explorer (POSEIDON)

Author

Rodriguez, Sébastien, primary, Vinatier, Sandrine, additional, Cordier, Daniel, additional, Tobie, Gabriel, additional, Achterberg, Richard K., additional, Anderson, Carrie M., additional, Badman, Sarah V., additional, Barnes, Jason W., additional, Barth, Erika L., additional, Bézard, Bruno, additional, Carrasco, Nathalie, additional, Charnay, Benjamin, additional, Clark, Roger N., additional, Coll, Patrice, additional, Cornet, Thomas, additional, Coustenis, Athena, additional, Couturier-Tamburelli, Isabelle, additional, Dobrijevic, Michel, additional, Flasar, F. Michael, additional, de Kok, Remco, additional, Freissinet, Caroline, additional, Galand, Marina, additional, Gautier, Thomas, additional, Geppert, Wolf D., additional, Griffith, Caitlin A., additional, Gudipati, Murthy S., additional, Hadid, Lina Z., additional, Hayes, Alexander G., additional, Hendrix, Amanda R., additional, Jaumann, Ralf, additional, Jennings, Donald E., additional, Jolly, Antoine, additional, Kalousova, Klara, additional, Koskinen, Tommi T., additional, Lavvas, Panayotis, additional, Lebonnois, Sébastien, additional, Lebreton, Jean-Pierre, additional, Le Gall, Alice, additional, Lellouch, Emmanuel, additional, Le Mouélic, Stéphane, additional, Lopes, Rosaly M. C., additional, Lora, Juan M., additional, Lorenz, Ralph D., additional, Lucas, Antoine, additional, MacKenzie, Shannon, additional, Malaska, Michael J., additional, Mandt, Kathleen, additional, Mastrogiuseppe, Marco, additional, Newman, Claire E., additional, Nixon, Conor A., additional, Radebaugh, Jani, additional, Rafkin, Scot C., additional, Rannou, Pascal, additional, Sciamma-O’Brien, Ella M., additional, Soderblom, Jason M., additional, Solomonidou, Anezina, additional, Sotin, Christophe, additional, Stephan, Katrin, additional, Strobel, Darrell, additional, Szopa, Cyril, additional, Teanby, Nicholas A., additional, Turtle, Elizabeth P., additional, Vuitton, Véronique, additional, and West, Robert A., additional

Published
2022
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45. VIMS spectral mapping observations of Titan during the Cassini prime mission

Author

Barnes, Jason W., Soderblom, Jason M., Brown, Robert H., Buratti, Bonnie J., Sotin, Christophe, Baines, Kevin H., Clark, Roger N., Jaumann, Ralf, McCord, Thomas B., Nelson, Robert, Le Mouélic, Stéphane, Rodriguez, Sebastien, Griffith, Caitlin, Penteado, Paulo, Tosi, Federico, Pitman, Karly M., Soderblom, Laurence, Stephan, Katrin, Hayne, Paul, Vixie, Graham, Bibring, Jean-Pierre, Bellucci, Giancarlo, Capaccioni, Fabrizio, Cerroni, Priscilla, Coradini, Angioletta, Cruikshank, Dale P., Drossart, Pierre, Formisano, Vittorio, Langevin, Yves, Matson, Dennis L., Nicholson, Phillip D., and Sicardy, Bruno

Published
2009
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48. Precipitation-induced surface brightenings seen on Titan by Cassini VIMS and ISS

Author

Barnes, Jason W, Buratti, Bonnie J, Turtle, Elizabeth P, Bow, Jacob, Dalba, Paul A, Perry, Jason, Brown, Robert H, Rodriguez, Sebastien, Mouélic, Stéphane Le, Baines, Kevin H, Sotin, Christophe, Lorenz, Ralph D, Malaska, Michael J, McCord, Thomas B, Clark, Roger N, Jaumann, Ralf, Hayne, Paul O, Nicholson, Philip D, Soderblom, Jason M, and Soderblom, Laurence A

Published
2013
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