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413 results on '"Plesa, Ana-Catalina"'

1. Volcanic and Tectonic Constraints on the Evolution of Venus

Author

Ghail, Richard C., Smrekar, Suzanne E., Widemann, Thomas, Byrne, Paul K., Gülcher, Anna J. P., O’Rourke, Joseph G., Borrelli, Madison E., Gilmore, Martha S., Herrick, Robert R., Ivanov, Mikhail A., Plesa, Ana-Catalina, Rolf, Tobias, Sabbeth, Leah, Schools, Joe W., and Gregory Shellnutt, J.

Published
2024
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2. Synergies between Venus & Exoplanetary Observations

Author

Way, M. J., Ostberg, Colby, Foley, Bradford J., Gillmann, Cedric, Höning, Dennis, Lammer, Helmut, O'Rourke, Joseph, Persson, Moa, Plesa, Ana-Catalina, Salvador, Arnaud, Scherf, Manuel, and Weller, Matthew

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

In this chapter we examine how our knowledge of present day Venus can inform terrestrial exoplanetary science and how exoplanetary science can inform our study of Venus. In a superficial way the contrasts in knowledge appear stark. We have been looking at Venus for millennia and studying it via telescopic observations for centuries. Spacecraft observations began with Mariner 2 in 1962 when we confirmed that Venus was a hothouse planet, rather than the tropical paradise science fiction pictured. As long as our level of exploration and understanding of Venus remains far below that of Mars, major questions will endure. On the other hand, exoplanetary science has grown leaps and bounds since the discovery of Pegasus 51b in 1995, not too long after the golden years of Venus spacecraft missions came to an end with the Magellan Mission in 1994. Multi-million to billion dollar/euro exoplanet focused spacecraft missions such as JWST, and its successors will be flown in the coming decades. At the same time, excitement about Venus exploration is blooming again with a number of confirmed and proposed missions in the coming decades from India, Russia, Japan, the European Space Agency and the National Aeronautics and Space Administration. In this chapter, we review what is known and what we may discover tomorrow in complementary studies of Venus and its exoplanetary cousins., Comment: 90 pages, 14 figures, Part of the collection "Venus: Evolution Through Time" https://link.springer.com/collections/jfjcifhefd

Published
2023
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3. First observations of core-transiting seismic phases on Mars

Author

Irving, Jessica CE, Lekić, Vedran, Durán, Cecilia, Drilleau, Mélanie, Kim, Doyeon, Rivoldini, Attilio, Khan, Amir, Samuel, Henri, Antonangeli, Daniele, Banerdt, William Bruce, Beghein, Caroline, Bozdağ, Ebru, Ceylan, Savas, Charalambous, Constantinos, Clinton, John, Davis, Paul, Garcia, Raphaël, Giardini, Domenico, Horleston, Anna Catherine, Huang, Quancheng, Hurst, Kenneth J, Kawamura, Taichi, King, Scott D, Knapmeyer, Martin, Li, Jiaqi, Lognonné, Philippe, Maguire, Ross, Panning, Mark P, Plesa, Ana-Catalina, Schimmel, Martin, Schmerr, Nicholas C, Stähler, Simon C, Stutzmann, Eleonore, and Xu, Zongbo

Subjects
Mars, core evolution, planetary structure
Abstract

We present the first observations of seismic waves propagating through the core of Mars. These observations, made using seismic data collected by the InSight geophysical mission, have allowed us to construct the first seismically constrained models for the elastic properties of Mars' core. We observe core-transiting seismic phase SKS from two farside seismic events detected on Mars and measure the travel times of SKS relative to mantle traversing body waves. SKS travels through the core as a compressional wave, providing information about bulk modulus and density. We perform probabilistic inversions using the core-sensitive relative travel times together with gross geophysical data and travel times from other, more proximal, seismic events to seek the equation of state parameters that best describe the liquid iron-alloy core. Our inversions provide constraints on the velocities in Mars' core and are used to develop the first seismically based estimates of its composition. We show that models informed by our SKS data favor a somewhat smaller (median core radius = 1,780 to 1,810 km) and denser (core density = 6.2 to 6.3 g/cm3) core compared to previous estimates, with a P-wave velocity of 4.9 to 5.0 km/s at the core-mantle boundary, with the composition and structure of the mantle as a dominant source of uncertainty. We infer from our models that Mars' core contains a median of 20 to 22 wt% light alloying elements when we consider sulfur, oxygen, carbon, and hydrogen. These data can be used to inform models of planetary accretion, composition, and evolution.

Published
2023

4. RayPC: Interactive Ray Tracing Meets Parallel Coordinates

Author

Fritsch, Jonathan, Flatken, Markus, Schneegans, Simon, Gerndt, Andreas, Plesa, Ana-Catalina, and Hüttig, Christian

Subjects
Computer Science - Graphics, Physics - Geophysics
Abstract

Large-scale numerical simulations of planetary interiors require dedicated visualization algorithms that are able to efficiently extract a large amount of information in an interactive and user-friendly way. Here we present a software framework for the visualization of mantle convection data. This framework combines real-time volume rendering, pathline visualization, and parallel coordinates to explore the fluid dynamics in an interactive way and to identify correlations between various output variables., Comment: Accepted at IEEE VIS 2021 as part of the SciVis contest

Published
2022

5. Interior Dynamics and Thermal Evolution of Mars -- a Geodynamic Perspective

Author

Plesa, Ana-Catalina, Wieczorek, Mark, Knapmeyer, Martin, Rivoldini, Attilio, Walterova, Michaela, and Breuer, Doris

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Over the past decades, global geodynamical models have been used to investigate the thermal evolution of terrestrial planets. With the increase of computational power and improvement of numerical techniques, these models have become more complex, and simulations are now able to use a high resolution 3D spherical shell geometry and to account for strongly varying viscosity, as appropriate for mantle materials. In this study we review global 3D geodynamic models that have been used to study the thermal evolution and interior dynamics of Mars. We discuss how these models can be combined with local and global observations to constrain the planet's thermal history. In particular, we use the recent InSight estimates of the crustal thickness, upper mantle structure, and core size to show how these constraints can be combined with 3D geodynamic models to improve our understanding of the interior dynamics, present-day thermal state and temperature variations in the interior of Mars.

Published
2022

6. Tidal insights into rocky and icy bodies: An introduction and overview

Author

Bagheri, Amirhossein, Efroimsky, Michael, Castillo-Rogez, Julie, Goossens, Sander, Plesa, Ana-Catalina, Rambaux, Nicolas, Rhoden, Alyssa, Walterová, Michaela, Khan, Amir, and Giardini, Domenico

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Solid body tides provide key information on the interior structure, evolution, and origin of the planetary bodies. Our Solar system harbours a very diverse population of planetary bodies, including those composed of rock, ice, gas, or a mixture of all. While a rich arsenal of geophysical methods has been developed over several years to infer knowledge about the interior of the Earth, the inventory of tools to investigate the interiors of other Solar-system bodies remains limited. With seismic data only available for the Earth, the Moon, and Mars, geodetic measurements, including the observation of the tidal response, have become especially valuable and therefore, has played an important role in understanding the interior and history of several Solar system bodies. To use tidal response measurements as a means to obtain constraints on the interior structure of planetary bodies, appropriate understanding of the viscoelastic reaction of the materials from which the planets are formed is needed. Here, we review the fundamental aspects of the tidal modeling and the information on the present-day interior properties and evolution of several planets and moons based on studying their tidal response. We begin with an outline of the theory of viscoelasticity and tidal response. Next, we proceed by discussing the information on the tidal response and the inferred structure of Mercury, Venus, Mars and its moons, the Moon, and the largest satellites of giant planets, obtained from the analysis of the data that has been provided by space missions. We also summarise the upcoming possibilities offered by the currently planned missions.

Published
2022
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7. The long-term evolution of the atmosphere of Venus: processes and feedback mechanisms

Author

Gillmann, Cedric, Way, M. J., Avice, Guillaume, Breuer, Doris, Golabek, Gregor J., Honing, Dennis, Krissansen-Totton, Joshua, Lammer, Helmut, O'Rourke, Joseph G., Persson, Moa, Plesa, Ana-Catalina, Salvador, Arnaud, Scherf, Manuel, and Zolotov, Mikhail Yu.

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

This work reviews the long-term evolution of the atmosphere of Venus, and modulation of its composition by interior-exterior cycling. The formation and evolution of Venus's atmosphere, leading to contemporary surface conditions, remain hotly debated topics, and involve questions that tie into many disciplines. We explore these various inter-related mechanisms which shaped the evolution of the atmosphere, starting with the volatile sources and sinks. Going from the deep interior to the top of the atmosphere, we describe volcanic outgassing, surface atmosphere interactions, and atmosphere escape. Furthermore, we address more complex aspects of the history of Venus, including the role of Late Accretion impacts, how magnetic field generation is tied into long-term evolution, and the implications of geochemical and geodynamical feedback cycles for atmospheric evolution. We highlight plausible end-member evolutionary pathways that Venus could have followed, from accretion to its present-day state, based on modeling and observations. In a first scenario, the planet was desiccated by atmospheric escape during the magma ocean phase. In a second scenario, Venus could have harbored surface liquid water for long periods of time, until its temperate climate was destabilized and it entered a runaway greenhouse phase. In a third scenario, Venus's inefficient outgassing could have kept water inside the planet, where hydrogen was trapped in the core and the mantle was oxidized. We discuss existing evidence and future observations and missions required to refine our understanding of the planet's history and of the complex feedback cycles between the interior, surface, and atmosphere that have been operating in the past, present or future of Venus.

Published
2022
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8. Seismic detection of a deep mantle discontinuity within Mars by InSight

Author

Huang, Quancheng, Schmerr, Nicholas C, King, Scott D, Kim, Doyeon, Rivoldini, Attilio, Plesa, Ana-Catalina, Samuel, Henri, Maguire, Ross R, Karakostas, Foivos, Lekić, Vedran, Charalambous, Constantinos, Collinet, Max, Myhill, Robert, Antonangeli, Daniele, Drilleau, Mélanie, Bystricky, Misha, Bollinger, Caroline, Michaut, Chloé, Gudkova, Tamara, Irving, Jessica CE, Horleston, Anna, Fernando, Benjamin, Leng, Kuangdai, Nissen-Meyer, Tarje, Bejina, Frederic, Bozdağ, Ebru, Beghein, Caroline, Waszek, Lauren, Siersch, Nicki C, Scholz, John-Robert, Davis, Paul M, Lognonné, Philippe, Pinot, Baptiste, Widmer-Schnidrig, Rudolf, Panning, Mark P, Smrekar, Suzanne E, Spohn, Tilman, Pike, William T, Giardini, Domenico, and Banerdt, W Bruce

Subjects
Earth Sciences, Physical Sciences, Astronomical Sciences, Geology, Geophysics, Earth, Planet, Extraterrestrial Environment, Iron, Mars, Minerals, interior of Mars, mantle transition zone, thermal evolution of Mars
Abstract

Constraining the thermal and compositional state of the mantle is crucial for deciphering the formation and evolution of Mars. Mineral physics predicts that Mars' deep mantle is demarcated by a seismic discontinuity arising from the pressure-induced phase transformation of the mineral olivine to its higher-pressure polymorphs, making the depth of this boundary sensitive to both mantle temperature and composition. Here, we report on the seismic detection of a midmantle discontinuity using the data collected by NASA's InSight Mission to Mars that matches the expected depth and sharpness of the postolivine transition. In five teleseismic events, we observed triplicated P and S waves and constrained the depth of this discontinuity to be 1,006 [Formula: see text] 40 km by modeling the triplicated waveforms. From this depth range, we infer a mantle potential temperature of 1,605 [Formula: see text] 100 K, a result consistent with a crust that is 10 to 15 times more enriched in heat-producing elements than the underlying mantle. Our waveform fits to the data indicate a broad gradient across the boundary, implying that the Martian mantle is more enriched in iron compared to Earth. Through modeling of thermochemical evolution of Mars, we observe that only two out of the five proposed composition models are compatible with the observed boundary depth. Our geodynamic simulations suggest that the Martian mantle was relatively cold 4.5 Gyr ago (1,720 to 1,860 K) and are consistent with a present-day surface heat flow of 21 to 24 mW/m2.

Published
2022

9. InSight Constraints on the Global Character of the Martian Crust

Author

Wieczorek, Mark A, Broquet, Adrien, McLennan, Scott M, Rivoldini, Attilio, Golombek, Matthew, Antonangeli, Daniele, Beghein, Caroline, Giardini, Domenico, Gudkova, Tamara, Gyalay, Szilárd, Johnson, Catherine L, Joshi, Rakshit, Kim, Doyeon, King, Scott D, Knapmeyer‐Endrun, Brigitte, Lognonné, Philippe, Michaut, Chloé, Mittelholz, Anna, Nimmo, Francis, Ojha, Lujendra, Panning, Mark P, Plesa, Ana‐Catalina, Siegler, Matthew A, Smrekar, Suzanne E, Spohn, Tilman, and Banerdt, W Bruce

Subjects
mars, crust, crustal composition, gravity, seismology, Astronomical and Space Sciences, Geochemistry, Geology
Abstract

Analyses of seismic data from the InSight mission have provided the first in situ constraints on the thickness of the crust of Mars. These crustal thickness constraints are currently limited to beneath the lander that is located in the northern lowlands, and we use gravity and topography data to construct global crustal thickness models that satisfy the seismic data. These models consider a range of possible mantle and core density profiles, a range of crustal densities, a low-density surface layer, and the possibility that the crustal density of the northern lowlands is greater than that of the southern highlands. Using the preferred InSight three-layer seismic model of the crust, the average crustal thickness of the planet is found to lie between 30 and 72 km. Depending on the choice of the upper mantle density, the maximum permissible density of the northern lowlands and southern highlands crust is constrained to be between 2,850 and 3,100 kg m−3. These crustal densities are lower than typical Martian basaltic materials and are consistent with a crust that is on average more felsic than the materials found at the surface. We argue that a substantial portion of the crust of Mars is a primary crust that formed during the initial differentiation of the planet. Various hypotheses for the origin of the observed intracrustal seisimic layers are assessed, with our preferred interpretation including thick volcanic deposits, ejecta from the Utopia basin, porosity closure, and differentiation products of a Borealis impact melt sheet.

Published
2022

10. Spin state and deep interior structure of Mars from InSight radio tracking

Author

Le Maistre, Sébastien, Rivoldini, Attilio, Caldiero, Alfonso, Yseboodt, Marie, Baland, Rose-Marie, Beuthe, Mikael, Van Hoolst, Tim, Dehant, Véronique, Folkner, William M., Buccino, Dustin, Kahan, Daniel, Marty, Jean-Charles, Antonangeli, Daniele, Badro, James, Drilleau, Mélanie, Konopliv, Alex, Péters, Marie-Julie, Plesa, Ana-Catalina, Samuel, Henri, Tosi, Nicola, Wieczorek, Mark, Lognonné, Philippe, Panning, Mark, Smrekar, Suzanne, and Banerdt, W. Bruce

Published
2023
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11. Heat Transfer, Planetary

Author

Spohn, Tilman, Kaltenegger, Lisa, Plesa, Ana-Catalina, Gargaud, Muriel, editor, Irvine, William M., editor, Amils, Ricardo, editor, Claeys, Philippe, editor, Cleaves, Henderson James, editor, Gerin, Maryvonne, editor, Rouan, Daniel, editor, Spohn, Tilman, editor, Tirard, Stéphane, editor, and Viso, Michel, editor

Published
2023
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12. An autonomous lunar geophysical experiment package (ALGEP) for future space missions: In response to Call for White Papers for the Voyage 2050 long-term plan in the ESA Science Program

Author

Kawamura, Taichi, Grott, Matthias, Garcia, Raphael, Wieczorek, Mark, de Raucourt, Sébastien, Lognonné, Philippe, Bernauer, Felix, Breuer, Doris, Clinton, John, Delage, Pierre, Drilleau, Mélanie, Ferraioli, Luigi, Fuji, Nobuaki, Horleston, Anna, Kletetschka, Günther, Knapmeyer, Martin, Knapmeyer-Endrun, Brigitte, Padovan, Sebastiano, Plesa, Ana-Catalina, Rivoldini, Attilio, Robertsson, Johan, Rodriguez, Sebastien, Stähler, Simon C., Stutzmann, Eleonore, Teanby, Nicholas A., Tosi, Nicola, Vrettos, Christos, Banerdt, Bruce, Fa, Wenzhe, Huang, Qian, Irving, Jessica, Ishihara, Yoshiaki, Miljković, Katarina, Mittelholz, Anna, Nagihara, Seiichi, Neal, Clive, Qu, Shaobo, Schmerr, Nicholas, and Tsuji, Takeshi

Published
2022
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14. Mars from the InSight: Seismology Beyond Earth

Author

Knapmeyer-Endrun, Brigitte, Banerdt, W. Bruce, Smrekar, Suzanne E., Lognonné, Philippe, Giardini, Domenico, Beghein, Caroline, Beucler, Éric, Bozdağ, Ebru, Clinton, John, Garcia, Raphael F., Irving, Jessica C. E., Kawamura, Taichi, Kedar, Sharon, Margerin, Ludovic, Panning, Mark P., Pike, Tom W., Plesa, Ana-Catalina, Schmerr, Nicholas, Teanby, Nicholas, Weber, Renee, Wieczorek, Mark, Barkaoui, Salma, Brinkman, Nienke, Ceylan, Savas, Charalambous, Constantinos, Compaire, Nicolas, Dahmen, Nikolaj, van Driel, Martin, Horleston, Anna, Huang, Quancheng, Hurst, Kenneth, Kenda, Balthasar, Khan, Amir, Kim, Doyeon, Knapmeyer, Martin, Li, Jiaqi, Menina, Sabrina, Murdoch, Naomi, Perrin, Clément, Schimmel, Martin, Stähler, Simon C., Stutzmann, Eléonore, Bezaeva, Natalia S., Series Editor, Gomes Coe, Heloisa Helena, Series Editor, Nawaz, Muhammad Farrakh, Series Editor, Vacareanu, Radu, editor, and Ionescu, Constantin, editor

Published
2022
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16. Shergottites

Author

Plesa, Ana-Catalina, Gargaud, Muriel, editor, Irvine, William M., editor, Amils, Ricardo, editor, Claeys, Philippe, editor, Cleaves, Henderson James, editor, Gerin, Maryvonne, editor, Rouan, Daniel, editor, Spohn, Tilman, editor, Tirard, Stéphane, editor, and Viso, Michel, editor

Published
2023
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17. Nakhlites

Author

Plesa, Ana-Catalina, Gargaud, Muriel, editor, Irvine, William M., editor, Amils, Ricardo, editor, Claeys, Philippe, editor, Cleaves, Henderson James, editor, Gerin, Maryvonne, editor, Rouan, Daniel, editor, Spohn, Tilman, editor, Tirard, Stéphane, editor, and Viso, Michel, editor

Published
2023
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19. Variations of Heat Flux and Elastic Thickness of Mercury From 3‐D Thermal Evolution Modeling.

Author

Fleury, Aymeric, Plesa, Ana‐Catalina, Tosi, Nicola, Walterová, Michaela, and Breuer, Doris

Subjects
*HEAT flux, *SURFACE temperature, *TEMPERATURE distribution, *SPHERICAL harmonics, *MAGNETIC fields
Abstract

Mercury's low obliquity and 3:2 spin‐orbit resonance create a surface temperature distribution with large latitudinal and longitudinal variations. These propagate via thermal conduction through the thin silicate shell influencing the interior temperature distribution. We use 3‐D thermal evolution models to investigate the effects of lateral variations of surface temperature and crustal thickness on the surface and core‐mantle boundary (CMB) heat fluxes, and elastic thickness distribution. Surface temperature variations cause a long‐wavelength perturbation of the heat fluxes, as well as of the elastic lithosphere thickness, while variations in crustal thickness affect these quantities at small spatial scales. Like the surface temperature, the present‐day CMB heat flux pattern is characterized primarily by spherical harmonics of degrees two and four, which could affect dynamo generation. Placing robust constraints on the thermal evolution based on the available estimates of the age and thickness of the elastic lithosphere remains challenging due to their large uncertainties. Plain Language Summary: The orbit of Mercury around the Sun leads to a specific surface temperature distribution, with some regions receiving more insolation than others. The thickness of Mercury's crust has been derived using gravity and topography data acquired by the MESSENGER mission. Since the rocky mantle of Mercury is rather thin (≈ ${\approx} $400 km), temperature variations driven by the insolation and by crustal properties (i.e., crustal heat sources and thermal conductivity) can affect the entire mantle, down to the core‐mantle boundary. Here we model the global thermal evolution of Mercury, and investigate the influence of surface temperature and crustal thickness variations on the history and present‐day state of the interior. We find that the surface temperature variations are reflected in the variations of Mercury's surface and core‐mantle boundary heat fluxes, as well as in the thickness of the elastic part of its lithosphere. Crustal thickness variations lead to more local temperature differences, thus resulting in smaller scale variations in the lithosphere thickness and heat fluxes. The heat flux pattern at the core mantle boundary induced by the surface temperature distribution could affect magnetic field generation and should be tested by future dynamo models. Key Points: The distribution of Mercury's mantle temperature is strongly influenced by surface temperature and crustal thickness variationsSurface heat flux and elastic thickness are controlled at large scales by surface temperature, and at small scales by crustal thicknessSurface temperature variations influence the CMB heat flux distribution, which we make readily available to test dynamo models [ABSTRACT FROM AUTHOR]

Published
2024
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20. Icy ocean worlds - astrobiology research in Germany.

Author

Klenner, Fabian, Baqué, Mickael, Beblo-Vranesevic, Kristina, Bönigk, Janine, Boxberg, Marc S., Dachwald, Bernd, Digel, Ilya, Elsaesser, Andreas, Espe, Clemens, Funke, Oliver, Hauber, Ernst, Heinen, Dirk, Hofmann, Florence, Sánchez, Lucía Hortal, Khawaja, Nozair, Napoleoni, Maryse, Plesa, Ana-Catalina, Postberg, Frank, Purser, Autun, and Rückriemen-Bez, Tina

Subjects
ASTROBIOLOGY, OCEAN, INFORMATION sharing, SOLAR system
Abstract

Icy bodies with subsurface oceans are a prime target for astrobiology investigations, with an increasing number of scientists participating in the planning, development, and realization of space missions to these worlds. Within Germany, the Ocean Worlds and Icy Moons working group of the German Astrobiology Society provides an invaluable platform for scientists and engineers from universities and other organizations with a passion for icy ocean worlds to share knowledge and start collaborations. We here present an overview about astrobiology research activities related to icy ocean worlds conducted either in Germany or in strong collaboration with scientists in Germany. With recent developments, Germany offers itself as a partner to contribute to icy ocean world missions. [ABSTRACT FROM AUTHOR]

Published
2024
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22. Seismic wave detectability on Venus using ground deformation sensors, infrasound sensors on balloons and airglow imagers

Author

Garcia, Raphael F., primary, Zelst, Iris van, additional, Kawamura, Taichi, additional, Näsholm, Sven Peter, additional, Horleston, Anna Catherine, additional, Klaasen, Sara, additional, Lefevre, Maxence, additional, Solberg, Céline Marie, additional, Smolinski, Krystyna T., additional, Plesa, Ana-Catalina, additional, Brissaud, Quentin, additional, Maia, Julia S., additional, Stähler, Simon C., additional, Lognonné, Philippe, additional, Panning, Mark Paul, additional, Gülcher, Anna, additional, Ghail, Richard, additional, and Toffoli, Barbara De, additional

Published
2024
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28. Tidal insights into rocky and icy bodies: an introduction and overview

Author

Bagheri, Amirhossein, primary, Efroimsky, Michael, additional, Castillo-Rogez, Julie, additional, Goossens, Sander, additional, Plesa, Ana-Catalina, additional, Rambaux, Nicolas, additional, Rhoden, Alyssa, additional, Walterová, Michaela, additional, Khan, Amir, additional, and Giardini, Domenico, additional

Published
2022
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31. Estimates on the Possible Annual Seismicity of Venus.

Author

van Zelst, Iris, Maia, Julia S., Plesa, Ana‐Catalina, Ghail, Richard, and Spühler, Moritz

Subjects
VENUS (Planet), PLATE tectonics, RIFTS (Geology), SEISMOLOGY, EARTH (Planet)
Abstract

There is a growing consensus that Venus is seismically active, although its level of seismicity could be very different from that of Earth due to the lack of plate tectonics. Here, we estimate upper and lower bounds on the expected annual seismicity of Venus by scaling the seismicity of the Earth. We consider different scaling factors for different tectonic settings and account for the lower seismogenic thickness of Venus. We find that 95–296 venusquakes equal to or bigger than moment magnitude (Mw) 4 per year are expected for an inactive Venus, where the global seismicity rate is assumed to be similar to that of continental intraplate seismicity on Earth. For the active Venus scenarios, we assume that the coronae, fold belts, and rifts of Venus are currently seismically active. This results in 1,161–3,609 venusquakes ≥Mw4 annually as a realistic lower bound and 5,715–17,773 venusquakes ≥Mw4 per year as a maximum upper bound for an active Venus. Plain Language Summary: Venus could be seismically active at the moment, but it is uncertain how many earthquakes (or to use the proper term: venusquakes) there could be in a year. Here, we calculate the minimum and maximum number of venusquakes we could expect in a given year on Venus based on different assumptions. If we assume there is not much seismic activity on Venus (comparable to the interior of tectonic plates on Earth), we find that we could expect about a few hundred venusquakes per year with a magnitude bigger than or equal to 4. For an estimate of the maximum amount of venusquakes, we assume that Venus has regions with more seismic activity: the so‐called coronae, fold belts, and rifts. Depending on our assumptions, we then find that more than 17,000 venusquakes with a magnitude bigger than or equal to 4 could occur in a year. Key Points: An inactive Venus with global background seismicity like Earth's continental intraplate seismicity has a few hundred quakes ≥Mw4 per yearA lower bound on an active Venus where fold belts, coronae, and rifts are seismically active predicts a few thousand quakes ≥Mw4 annuallyThe upper bound for an active Venus results in thousands (∼5,000–18,000) venusquakes ≥Mw4 per year [ABSTRACT FROM AUTHOR]

Published
2024
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32. Mars Soil Temperature and Thermal Properties from InSight HP^3 Data

Author

Spohn, Tilman, primary, Krause, Christian, additional, Golombeck, Matthew, additional, Mueller, Nils T, additional, Grott, Matthias, additional, Knollenberg, Joerg, additional, Plesa, Ana-Catalina, additional, Breuer, Doris, additional, Morgan, Paul, additional, Bickel, Valentin T., additional, Banerdt, William Bruce, additional, and Smrekar, Suzanne E, additional

Published
2024
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33. Initial results from the InSight mission on Mars

Author

Banerdt, W. Bruce, Smrekar, Suzanne E., Banfield, Don, Giardini, Domenico, Golombek, Matthew, Johnson, Catherine L., Lognonné, Philippe, Spiga, Aymeric, Spohn, Tilman, Perrin, Clément, Stähler, Simon C., Antonangeli, Daniele, Asmar, Sami, Beghein, Caroline, Bowles, Neil, Bozdag, Ebru, Chi, Peter, Christensen, Ulrich, Clinton, John, Collins, Gareth S., Daubar, Ingrid, Dehant, Véronique, Drilleau, Mélanie, Fillingim, Matthew, Folkner, William, Garcia, Raphaël F., Garvin, Jim, Grant, John, Grott, Matthias, Grygorczuk, Jerzy, Hudson, Troy, Irving, Jessica C. E., Kargl, Günter, Kawamura, Taichi, Kedar, Sharon, King, Scott, Knapmeyer-Endrun, Brigitte, Knapmeyer, Martin, Lemmon, Mark, Lorenz, Ralph, Maki, Justin N., Margerin, Ludovic, McLennan, Scott M., Michaut, Chloe, Mimoun, David, Mittelholz, Anna, Mocquet, Antoine, Morgan, Paul, Mueller, Nils T., Murdoch, Naomi, Nagihara, Seiichi, Newman, Claire, Nimmo, Francis, Panning, Mark, Pike, W. Thomas, Plesa, Ana-Catalina, Rodriguez, Sébastien, Rodriguez-Manfredi, Jose Antonio, Russell, Christopher T., Schmerr, Nicholas, Siegler, Matt, Stanley, Sabine, Stutzmann, Eléanore, Teanby, Nicholas, Tromp, Jeroen, van Driel, Martin, Warner, Nicholas, Weber, Renee, and Wieczorek, Mark

Published
2020
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35. New Numerically Derived Scaling Relationships for Impact Basins on Mars.

Author

Branco, Hely C., Miljkovic, Katarina, and Plesa, Ana‐Catalina

Subjects
MARS (Planet), PLANETARY surfaces, IMPACT craters, ORIGIN of planets, BOMBARDMENT, TEMPERATURE effect, SEISMIC anisotropy
Abstract

Most impact basins are believed to have formed during the early epochs of planetary evolution. The planet's gravity, internal structure, and thermal regime have the strongest control over their formation. Because of this, we can use the geophysical constraints on Mars' interior composition, structure, and geophysical evolution derived from the InSight mission to better understand the formation of impact basins on the planet. To achieve this, we performed numerical simulations of large impacts using the iSALE shock physics code. We investigated the effects of temperature and crustal thickness variations on impact basin size and morphology. Our scaling relationships indicate that: (a) basins formed in a warmer crust have larger final diameters in comparison to basins formed in a colder crust, a difference that is further accentuated as basin size gets bigger; and (b) the largest impact basins on Mars were created by impactors ranging from 35 to 680 km in diameter, up to ∼32% larger than estimates based on classical scaling. Our results expand the current understanding of the extent of early and large impact bombardment on Mars and provide a more comprehensive knowledge of impact basin formation on planetary surfaces. Plain Language Summary: The recent advancements in the understanding of Mars' that resulted from the InSight mission can be used to better understand the early large bombardment that took place 4.4 to 3.7 Ga ago. This bombardment formed impact basins, the largest and most complex type of craters. Their size and shape depend on the interior structure and temperature of the planet when they formed. We can better understand basins by simulating their formation and comparing the results with observations. Here, we used advanced interior structure and temperature evolution models of Mars to simulate the formation of impact basins as accurately as possible. We simulated basins of various sizes forming at different locations at multiple stages during Mars' evolution. Based on that, we derived equations referred to as scaling relationships that express the connection between basin size and impact conditions for different epochs and locations on Mars. We concluded that: (a) basins formed in a warmer crust are larger than basins formed in a colder crust, and (b) the largest reported basins on the planet were created by impactors much larger than previously thought. Our results provide a more comprehensive knowledge of impact basin formation and valuable insights into the early large bombardment. Key Points: We numerically simulated impact basin formation on Mars using recent internal structure and temperature modelsWe described how thermal evolution and crustal thickness variations could have affected impact basin formation on MarsWe derived new scaling relationships for impact basins and provided an insight into the early large bombardment on Mars [ABSTRACT FROM AUTHOR]

Published
2024
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41. Towards coupled interior-atmosphere models of Earth and Venus

Author

Van Zelst, Iris, Taysum, Benjamin, Plesa, Ana-Catalina, Grenfell, John Lee, Breuer, Doris, and Rauer, Heike

Abstract

Updates on three different projects for the Exoclimes VI conference: - atmospheric modelling of steam-dominated atmospheres of Earth-like exoplanets in 1D - coupled interior-atmosphere evolution on Venus - estimating the current level of seismicity on Venus&nbsp

Published
2023
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42. Global Crustal Thickness Revealed by Surface Waves Orbiting Mars

Author

Kim, Doyeon, Duran, Andrea Cecilia, Giardini, Domenico, Plesa, Ana-Catalina, Stähler, Simon Christian, Boehm, C., Lekić, Vedran, McLennan, Scott M., Ceylan, Savas, Clinton, John Francis, Davis, P., Khan, Amir, Knapmeyer-Endrun, Brigitte, Panning, Mark P., Wieczorek, Mark A., Lognonné, Philippe, and Banerdt, Bruce

Subjects
upper mantle, marsquake, Mars, crust, surface waves, dichotomy
Abstract

We report observations of Rayleigh waves that orbit around Mars up to three times following the S1222a marsquake. Averaging these signals, we find the largest amplitude signals at 30 and 85 s central period, propagating with distinctly different group velocities of 2.9 and 3.8 km/s, respectively. The group velocities constraining the average crustal thickness beneath the great circle path rule out the majority of previous crustal models of Mars that have a >200 kg/m(3) density contrast across the equatorial dichotomy between northern lowlands and southern highlands. We find that the thickness of the Martian crust is 42-56 km on average, and thus thicker than the crusts of the Earth and Moon. Considered with the context of thermal evolution models, a thick Martian crust suggests that the crust must contain 50%-70% of the total heat production to explain present-day local melt zones in the interior of Mars., Geophysical Research Letters, 50 (12), ISSN:0094-8276, ISSN:1944-8007

Published
2023

43. Mars from the InSight: Seismology Beyond Earth

Author

Knapmeyer-Endrun, Brigitte [0000-0003-3309-6785], Banerdt, W. Bruce [0000-0003-3125-1542], Smrekar, Suzanne E. [0000-0001-8775-075X], Lognonné, Philippe [0000-0002-1014-920X], Giardini, Domenico [0000-0002-5573-7638], Beghein, Caroline [0000-0002-3158-2213], Beucler, Éric [0000-0003-2605-4990], Bozdağ, Ebru 0000-0002-4269-3533`], Clinton, John [0000-0001-8626-2703], Garcia, Raphael F. [0000-0003-1460-6663], Irving, Jessica C. E. [0000-0002-0866-8246], Kawamura, Taichi [0000-0001-5246-5561], Kedar, Sharon [0000-0001-6315-5446], Margerin, Ludovic [0000-0003-4848-3227], Panning, Mark P. [0000-0002-2041-3190], Pike, Tom W. [0000-0002-7660-6231], Plesa, Ana Catalina [0000-0003-3366-7621], Schmerr, Nicholas [0000-0002-3256-1262], Teanby, Nicholas [0000-0003-3108-5775], Weber, Renee [0000-0002-1649-483X], Wieczorek, Mark [0000-0001-7007-4222], Barkaoui, Salma [0000-0001-7266-0815], Brinkman, Nienke [0000-0002-1842-0834], Ceylan, Savas [0000-0002-6552-6850], Charalambous, Constantinos [0000-0002-9139-3895], Compaire, Nicolas [0000-0002-8932-732X], Van Driel, Martin [0000-0002-8938-4615], Horleston, Anna [0000-0002-6748-6522], Huang, Quancheng [0000-0002-5681-5159], Hurst, Kenneth [0000-0002-3822-4689], Kenda, Balthasar [0000-0002-2572-8749], Khan, Amir [0000-0003-4462-3173], Kim, Doyeon [0000-0003-4594-2336], Knapmeyer, Martin [0000-0003-0319-2514], Li, Jiaqi [0000-0001-7525-5401], Menina, Sabrina [0000-0003-1044-6877], Murdoch, Naomi [0000-0002-9701-4075], Perrin, Clément [0000-0002-7200-5682], Schimmel, Martin [0000-0003-2601-4462], Stähler, Simon C. [0000-0002-0783-2489], Stutzmann, Eléonore [0000-0002-4348-7475], Knapmeyer-Endrun, Brigitte, Banerdt, W. Bruce, Smrekar, Suzanne E., Lognonné, Philippe, Giardini, Domenico, Beghein, Caroline, Beucler, Éric, Bozdağ, Ebru, Clinton, John, Garcia, Raphael F., Irving, Jessica C. E., Kawamura, Taichi, Kedar, Sharon, Margerin, Ludovic, Panning, Mark P., Pike, Tom W., Plesa, Ana Catalina, Schmerr, Nicholas, Teanby, Nicholas, Weber, Renee, Wieczorek, Mark, Barkaoui, Salma, Brinkman, Nienke, Ceylan, Savas, Charalambous, Constantinos, Compaire, Nicolas, Dahmen, Nikolaj, van Driel, Martin, Horleston, Anna, Huang, Quancheng, Hurst, Kenneth, Kenda, Balthasar, Khan, Amir, Kim, Doyeon, Knapmeyer, Martin, Li, Jiaqi, Menina, Sabrina, Murdoch, Naomi, Perrin, Clément, Schimmel, Martin, Stähler, Simon C., Stutzmann, Eléonore, Knapmeyer-Endrun, Brigitte [0000-0003-3309-6785], Banerdt, W. Bruce [0000-0003-3125-1542], Smrekar, Suzanne E. [0000-0001-8775-075X], Lognonné, Philippe [0000-0002-1014-920X], Giardini, Domenico [0000-0002-5573-7638], Beghein, Caroline [0000-0002-3158-2213], Beucler, Éric [0000-0003-2605-4990], Bozdağ, Ebru 0000-0002-4269-3533`], Clinton, John [0000-0001-8626-2703], Garcia, Raphael F. [0000-0003-1460-6663], Irving, Jessica C. E. [0000-0002-0866-8246], Kawamura, Taichi [0000-0001-5246-5561], Kedar, Sharon [0000-0001-6315-5446], Margerin, Ludovic [0000-0003-4848-3227], Panning, Mark P. [0000-0002-2041-3190], Pike, Tom W. [0000-0002-7660-6231], Plesa, Ana Catalina [0000-0003-3366-7621], Schmerr, Nicholas [0000-0002-3256-1262], Teanby, Nicholas [0000-0003-3108-5775], Weber, Renee [0000-0002-1649-483X], Wieczorek, Mark [0000-0001-7007-4222], Barkaoui, Salma [0000-0001-7266-0815], Brinkman, Nienke [0000-0002-1842-0834], Ceylan, Savas [0000-0002-6552-6850], Charalambous, Constantinos [0000-0002-9139-3895], Compaire, Nicolas [0000-0002-8932-732X], Van Driel, Martin [0000-0002-8938-4615], Horleston, Anna [0000-0002-6748-6522], Huang, Quancheng [0000-0002-5681-5159], Hurst, Kenneth [0000-0002-3822-4689], Kenda, Balthasar [0000-0002-2572-8749], Khan, Amir [0000-0003-4462-3173], Kim, Doyeon [0000-0003-4594-2336], Knapmeyer, Martin [0000-0003-0319-2514], Li, Jiaqi [0000-0001-7525-5401], Menina, Sabrina [0000-0003-1044-6877], Murdoch, Naomi [0000-0002-9701-4075], Perrin, Clément [0000-0002-7200-5682], Schimmel, Martin [0000-0003-2601-4462], Stähler, Simon C. [0000-0002-0783-2489], Stutzmann, Eléonore [0000-0002-4348-7475], Knapmeyer-Endrun, Brigitte, Banerdt, W. Bruce, Smrekar, Suzanne E., Lognonné, Philippe, Giardini, Domenico, Beghein, Caroline, Beucler, Éric, Bozdağ, Ebru, Clinton, John, Garcia, Raphael F., Irving, Jessica C. E., Kawamura, Taichi, Kedar, Sharon, Margerin, Ludovic, Panning, Mark P., Pike, Tom W., Plesa, Ana Catalina, Schmerr, Nicholas, Teanby, Nicholas, Weber, Renee, Wieczorek, Mark, Barkaoui, Salma, Brinkman, Nienke, Ceylan, Savas, Charalambous, Constantinos, Compaire, Nicolas, Dahmen, Nikolaj, van Driel, Martin, Horleston, Anna, Huang, Quancheng, Hurst, Kenneth, Kenda, Balthasar, Khan, Amir, Kim, Doyeon, Knapmeyer, Martin, Li, Jiaqi, Menina, Sabrina, Murdoch, Naomi, Perrin, Clément, Schimmel, Martin, Stähler, Simon C., and Stutzmann, Eléonore

Abstract

When NASA’s InSight lander touched down in Elysium Planitia, Mars, in November 2018 and deployed its seismometer SEIS, it ushered in a new age for planetary seismology - more than 40 years after the first attempt to record marsquakes with the Viking missions. SEIS, an extremely sensitive instrument, has by now provided near continuous seismic records for more than 3 years. Its rich dataset shows Mars to be seismically active, with over 1,300 marsquakes detected so far, mostly with magnitudes below 4. Despite their small size, these quakes provide important and unprecedented constraints on the interior structure of the planet, from the shallow subsurface via the crust, the lithosphere, and the mantle transition zone down to the core, and allow to study Martian tectonics and thermo-chemical evolution. Single-station seismology has answered some of the big questions about the interior of our planetary neighbour, and this contribution gives an overview of results and surprises so far.

Published
2022

45. Global crustal thickness revealed by surface waves orbiting Mars

Author

Kim, Doyeon, primary, Duran, Cecilia, additional, Giardini, Domenico, additional, Plesa, Ana-Catalina, additional, Stähler, Simon C., additional, Boehm, Christian, additional, Lekic, Vedran, additional, McLennan, Scott M., additional, Ceylan, Savas, additional, Clinton, John, additional, Davis, Paul McEwan, additional, Khan, Amir, additional, Knapmeyer-Endrun, Brigitte, additional, Panning, Mark Paul, additional, Wieczorek, Mark A., additional, and Lognonné, Philippe, additional

Published
2023
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46. Synergies Between Venus & Exoplanetary Observations : Venus and Its Extrasolar Siblings

Author

Way, Michael J., Ostberg, Colby, Foley, Bradford J., Gillmann, Cedric, Höning, Dennis, Lammer, Helmut, O'Rourke, Joseph, Persson, Moa, Plesa, Ana-Catalina, Salvador, Arnaud, Scherf, Manuel, Weller, Matthew, Way, Michael J., Ostberg, Colby, Foley, Bradford J., Gillmann, Cedric, Höning, Dennis, Lammer, Helmut, O'Rourke, Joseph, Persson, Moa, Plesa, Ana-Catalina, Salvador, Arnaud, Scherf, Manuel, and Weller, Matthew

Abstract

Here we examine how our knowledge of present day Venus can inform terrestrial exoplanetary science and how exoplanetary science can inform our study of Venus. In a superficial way the contrasts in knowledge appear stark. We have been looking at Venus for millennia and studying it via telescopic observations for centuries. Spacecraft observations began with Mariner 2 in 1962 when we confirmed that Venus was a hothouse planet, rather than the tropical paradise science fiction pictured. As long as our level of exploration and understanding of Venus remains far below that of Mars, major questions will endure. On the other hand, exoplanetary science has grown leaps and bounds since the discovery of Pegasus 51b in 1995, not too long after the golden years of Venus spacecraft missions came to an end with the Magellan Mission in 1994. Multi-million to billion dollar/euro exoplanet focused spacecraft missions such as JWST, and its successors will be flown in the coming decades. At the same time, excitement about Venus exploration is blooming again with a number of confirmed and proposed missions in the coming decades from India, Russia, Japan, the European Space Agency (ESA) and the National Aeronautics and Space Administration (NASA). Here we review what is known and what we may discover tomorrow in complementary studies of Venus and its exoplanetary cousins.

Published
2023
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47. MAGMARS: A Melting Model for the Martian Mantle and FeO‐Rich Peridotite

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Collinet, Max, Plesa, Ana-Catalina, Grove, Timothy L, Schwinger, Sabrina, Ruedas, Thomas, Breuer, Doris, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Collinet, Max, Plesa, Ana-Catalina, Grove, Timothy L, Schwinger, Sabrina, Ruedas, Thomas, and Breuer, Doris

Published
2023

50. Crustal structure observed by the InSight mission to Mars

Author

Kim, Doyeon, primary, Stähler, Simon, additional, Boehm, Christian, additional, Lekic, Ved, additional, Giardini, Domenico, additional, Ceylan, Savas, additional, Clinton, John, additional, Davis, Paul, additional, Duran, Cecilia, additional, Khan, Amir, additional, Knapmeyer-Endrun, Brigitte, additional, Maguire, Ross, additional, Panning, Mark, additional, Plesa, Ana-Catalina, additional, Schmerr, Nicholas, additional, Wieczorek, Mark, additional, Zenhäusern, Géraldine, additional, Lognonné, Philippe, additional, and Banerdt, William, additional

Published
2023
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