Your search keyword '"Rosenblatt, Pascal"' showing total 9 results

1. GETEMME-a mission to explore the Martian satellites and the fundamentals of solar system physics.

Author

Oberst, Jürgen, Lainey, Valéry, Poncin-Lafitte, Christophe, Dehant, Veronique, Rosenblatt, Pascal, Ulamec, Stephan, Biele, Jens, Spurmann, Jörn, Kahle, Ralph, Klein, Volker, Schreiber, Ulrich, Schlicht, Anja, Rambaux, Nicolas, Laurent, Philippe, Noyelles, Benoît, Foulon, Bernard, Zakharov, Alexander, Gurvits, Leonid, Uchaev, Denis, and Murchie, Scott

Subjects

EINSTEIN field equations, GRAVITY, ASTROPHYSICS, PHYSICAL measurements, ACCELEROMETERS, MARTIAN exploration, SATELLITES of Mars, MARS (Planet), SOLAR system

Abstract

GETEMME (Gravity, Einstein's Theory, and Exploration of the Martian Moons' Environment), a mission which is being proposed in ESA's Cosmic Vision program, shall be launched for Mars on a Soyuz Fregat in 2020. The spacecraft will initially rendezvous with Phobos and Deimos in order to carry out a comprehensive mapping and characterization of the two satellites and to deploy passive Laser retro-reflectors on their surfaces. In the second stage of the mission, the spacecraft will be transferred into a lower 1500-km Mars orbit, to carry out routine Laser range measurements to the reflectors on Phobos and Deimos. Also, asynchronous two-way Laser ranging measurements between the spacecraft and stations of the ILRS (International Laser Ranging Service) on Earth are foreseen. An onboard accelerometer will ensure a high accuracy for the spacecraft orbit determination. The inversion of all range and accelerometer data will allow us to determine or improve dramatically on a host of dynamic parameters of the Martian satellite system. From the complex motion and rotation of Phobos and Deimos we will obtain clues on internal structures and the origins of the satellites. Also, crucial data on the time-varying gravity field of Mars related to climate variation and internal structure will be obtained. Ranging measurements will also be essential to improve on several parameters in fundamental physics, such as the Post-Newtonian parameter β as well as time-rate changes of the gravitational constant and the Lense-Thirring effect. Measurements by GETEMME will firmly embed Mars and its satellites into the Solar System reference frame. [ABSTRACT FROM AUTHOR]

Published

2012

2. Trojans' Odyssey: Unveiling the early history of the Solar System.

Author

Lamy, Philippe, Vernazza, Pierre, Poncy, Joel, Martinot, Vincent, Hinglais, Emmanuel, Canalias, Elisabet, Bell, Jim, Cruikshank, Dale, Groussin, Olivier, Helbert, Joern, Marzari, Francesco, Morbidelli, Alessandro, Rosenblatt, Pascal, and Sierks, Holger

Subjects

ASTEROIDS, TROJAN asteroids, LAGRANGE equations, RECONNAISSANCE operations, GRAVITY, INFRARED spectroscopy, SOLAR system

Abstract

In our present understanding of the Solar System, small bodies (asteroids, Jupiter Trojans, comets and TNOs) are the most direct remnants of the original building blocks that formed the planets. Jupiter Trojan and Hilda asteroids are small primitive bodies located beyond the 'snow line', around respectively the L and L Lagrange points of Jupiter at ∼5.2 AU (Trojans) and in the 2:3 mean-motion resonance with Jupiter near 3.9 AU (Hildas). They are at the crux of several outstanding and still conflicting issues regarding the formation and evolution of the Solar System. They hold the potential to unlock the answers to fundamental questions about planetary migration, the late heavy bombardment, the formation of the Jovian system, the origin and evolution of trans-neptunian objects, and the delivery of water and organics to the inner planets. The proposed Trojans' Odyssey mission is envisioned as a reconnaissance, multiple flyby mission aimed at visiting several objects, typically five Trojans and one Hilda. It will attempt exploring both large and small objects and sampling those with any known differences in photometric properties. The orbital strategy consists in a direct trajectory to one of the Trojan swarms. By carefully choosing the aphelion of the orbit (typically 5.3 AU), the trajectory will offer a long arc in the swarm thus maximizing the number of flybys. Initial gravity assists from Venus and Earth will help reducing the cruise time as well as the ΔV needed for injection thus offering enough capacity to navigate among Trojans. This solution further opens the unique possibility to flyby a Hilda asteroid when leaving the Trojan swarm. During the cruise phase, a Main Belt Asteroid could be targeted if requiring a modest ΔV. The specific science objectives of the mission will be best achieved with a payload that will perform high-resolution panchromatic and multispectral imaging, thermal-infrared imaging/ radiometry, near- and mid-infrared spectroscopy, and radio science/mass determination. The total mass of the payload amounts to 50 kg (including margins). The spacecraft is in the class of Mars-Express or a down-scaled version of Jupiter Ganymede Orbiter. It will have a dry mass of 1200 kg, a total mass at launch of 3070 kg and a ΔV capability of 700 m/s (after having reached the first Trojan) and can be launched by a Soyuz rocket. The mission operations concept (ground segment) and science operations are typical of a planetary mission as successfully implemented by ESA during, for instance, the recent flybys of Main Belt asteroids Steins and Lutetia. [ABSTRACT FROM AUTHOR]

Published

2012

3. The origin of the Martian moons revisited.

Author

Rosenblatt, Pascal

Subjects

DEIMOS (Satellite), ORIGIN of planets, ASTRONOMICAL observations, SATELLITES of Mars, PHOBOS (Satellite)

Abstract

The origin of the Martian moons, Phobos and Deimos, is still an open issue: either they are asteroids captured by Mars or they formed in situ from a circum-Mars debris disk. The capture scenario mainly relies on the remote-sensing observations of their surfaces, which suggest that the moon material is similar to outer-belt asteroid material. This scenario, however, requires high tidal dissipation rates inside the moons to account for their current orbits around Mars. Although the in situ formation scenarios have not been studied in great details, no observational constraints argue against them. Little attention has been paid to the internal structure of the moons, yet it is pertinent for explaining their origin. The low density of the moons indicates that their interior contains significant amounts of porous material and/or water ice. The porous content is estimated to be in the range of 30-60% of the volume for both moons. This high porosity enhances the tidal dissipation rate but not sufficiently to meet the requirement of the capture scenario. On the other hand, a large porosity is a natural consequence of re-accretion of debris at Mars' orbit, thus providing support to the in situ formation scenarios. The low density also allows for abundant water ice inside the moons, which might significantly increase the tidal dissipation rate in their interiors, possibly to a sufficient level for the capture scenario. Precise measurements of the rotation and gravity field of the moons are needed to tightly constrain their internal structure in order to help answering the question of the origin. [ABSTRACT FROM AUTHOR]

Published

2011

4. Determination of Venus' Interior Structure with EnVision.

Author

Rosenblatt, Pascal, Dumoulin, Caroline, Marty, Jean-Charles, Genova, Antonio, and Bellucci, Giancarlo

Subjects

MOMENTS of inertia, PLANETARY interiors, GRAVITY, LITHOSPHERE, VISCOSITY

Abstract

The Venusian geological features are poorly gravity-resolved, and the state of the core is not well constrained, preventing an understanding of Venus' cooling history. The EnVision candidate mission to the ESA's Cosmic Vision Programme consists of a low-altitude orbiter to investigate geological and atmospheric processes. The gravity experiment aboard this mission aims to determine Venus' geophysical parameters to fully characterize its internal structure. By analyzing the radio-tracking data that will be acquired through daily operations over six Venusian days (four Earth's years), we will derive a highly accurate gravity field (spatial resolution better than ~170 km), allowing detection of lateral variations of the lithosphere and crust properties beneath most of the geological features. The expected 0.3% error on the Love number k2, 0.1° error on the tidal phase lag and 1.4% error on the moment of inertia are fundamental to constrain the core size and state as well as the mantle viscosity. [ABSTRACT FROM AUTHOR]

Published

2021

5. VENUS GRAVITY FIELD MODELING FROM MAGELLAN AND VENUS EXPRESS TRACKING DATA.

Author

Goossens, Sander, Lemoine, Frank G., Rosenblatt, Pascal, Lebonnois, Sébastien, and Mazarico, Erwan

Subjects

GRAVITY, VENUSIAN atmosphere, GENERAL circulation model

Published

2017

6. EnVision: Understanding Why our most Earth-like Neighbour is so Different.

Author

Ghail, Richard, Wilson, Colin, Widemann, Thomas, Bruzzone, Lorenzo, Helbert, Joern, Dumoulin, Caroline, Rosenblatt, Pascal, Vandaele, Ann C., and Marcq, Emmanuel

Published

2019

7. EnVision M5 mission project : expected outcomes on the internal structure and dynamics of Venus.

Author

Dumoulin, Caroline, Rosenblatt, Pascal, Rambaux, Nicolas, and Marty, Jean-Charles

Published

2019

8. THE VERY MODEL OF A MODERN MARTIAN MOON.

Author

Rosenblatt, Pascal

Subjects

SATELLITES of Mars, PHOBOS (Satellite), DEIMOS (Satellite)

Abstract

The article explains why numerical models have been key to understanding the origin of the Martian moons Phobos and Deimos.

Published

2016

9. Mars geodesy, rotation and gravity.

Author

Rosenblatt, Pascal and Dehant, Veronique

Published

2010