JAXA, CNES and DLR sign cooperation agreement for MMX mission


Rover on the home stretch to the martian moon Phobos
The origin of the martian moons Phobos and Deimos is still an unsolved mystery in planetary research. Both moons will be the targets of the Japanese Martian Moons eXploration (MMX) mission. A German-French rover will land on Phobos as part of the mission and conduct a mobile exploration – despite the extremely low gravity. At the Paris Air Show in Le Bourget, the Japan Aerospace Exploration Agency (JAXA) signed an agreement with the German Aerospace Center (Deutsches Zentrum für Luft- und Raumfahrt; DLR) and the French space agency (Centre national d’études spatiales; https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg) on trilateral cooperation within the framework of the MMX mission. Meanwhile, the completion of the rover, including instruments and systems, is on the home stretch towards summer 2023. Parallel to the signing, the rover has been named IDEFIX.

“We are very excited to collaborate with https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg and DLR as part of the MMX mission, which endeavours to clarify the origin of the martian moons and the evolutionary process of the martian sphere by collecting samples from one of Mars’ two moons – Phobos – for the first time in space history,” said Hiroshi Yamakawa, President of JAXA. He added: “Japan shares a precious memory with France and Germany regarding the collaboration during the Hayabusa2 sample return mission, on which the joint https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg-DLR MASCOT lander flew. And we are looking forward to putting our efforts together once again for a successful MMX mission.”

On the occasion of the signing, Anke Kaysser-Pyzalla, Chair of the DLR Executive Board, said: “Japan and France are important strategic partner countries for DLR in almost all of our research areas. In this context, our cooperation within the framework of the MMX mission is a specific example of the creative power of our multifaceted collaboration. When a rover travels over the surface of the martian moon Phobos for the first time, we will have jointly pushed technological boundaries to learn more about the origin of the Solar System and Mars with its moons.” Walther Pelzer, DLR Executive Board Member and Director General of the German Space Agency at DLR emphasized: “MMX is a true example of how to conduct challenging space missions with international cooperation – as a joint undertaking, together with likeminded nations, space agencies and partners. Each side brings fruitful and specific competences, sharing costs and risks and gaining exceptional technological expertise and scientific results.”

“The signing of this new tripartite agreement between https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg, JAXA and DLR is another milestone in the fruitful cooperation between our three nations on the MMX mission. By studying the two Martian moons, Phobos and Deimos, this mission will lead to major advances in the knowledge of our Solar System”, says Philippe Baptiste, https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg’ CEO.

With the trilateral cooperation agreement that has now been signed, JAXA, https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg and DLR are creating a joint framework for the integration of the German-French rover into the Japanese MMX mission for a landing on the martian moon Phobos in the second half of the 2020s. MMX is a mission that will operate at the limits of what is technically feasible. For the first time, samples from the martian system, specifically from the martian moon Phobos, will be brought to Earth by the Japanese MMX mothercraft. The German-French rover will move across the surface of Phobos in conditions of extremely low gravity (approximately two-thousandths of Earth’s gravity) in order to explore it. The MMX rover is designed around this unique and challenging idea and has been given the name IDEFIX, today.

Rover to be completed in summer 2023
The final work to complete the rover is currently under way at the https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg site in Toulouse. In the last few months, the final integration of all instruments and subsystems, including the solar arrays, power system, on-board computer and radio system for contact with the MMX spacecraft, has taken place there. Previously, DLR had already integrated the rover’s carbon-reinforced composite structure, including the locomotion system, at their Bremen site and delivered it to https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg in Toulouse in November 2022. The miniRAD radiometer and the RAX spectrometer from DLR’s Berlin site were also shipped to Toulouse. In addition to the two DLR instruments for analyzing the thermal properties and minerological composition of the surface, https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg has installed two cameras that monitor the wheels and the ground. https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg has also developed and integrated the two navigation cameras that will be used for the navigation.

In the meantime, the rover has almost completed its space qualification tests at https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg in Toulouse. Among other things, these tests address its functionality as well as its ability to withstand the vibrations during launch and the extreme temperature fluctuation range of more than 200 degrees Celsius on Phobos. This adapter, the Mechanical and Electrical Connection and Support System (MECSS), was also provided by DLR. The communication system between the spacecraft and the rover, which is used to transmit commands and telemetry, and has been developed by https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg is also being tested during this qualification campaign. The rover test campaign is now in its final stretch. More tests, including EMC (Electromagnetic compatibility) tests and other final tests will be carried out before delivery this summer. Rover test campaign is now in its final straight. There are still the EMC (Electromagnetic compatibility) and final tests to be carried out before delivery this summer.

MMX spacecraft
The MMX spacecraft consists of three modules. The exploration module has landing legs, samplers and some instruments as well as the MMX rover on board. The exploration module is connected to the return module with the sample return capsule, which in turn is connected to a propulsion module housing propellant tanks and thrusters. The MMX spacecraft design has been completed, and the project team has started the final manufacture, testing and integration of the spacecraft including instruments provided by partner agencies toward the launch target in FY2024.

The mission timeline
The launch of the mission is scheduled for the mid-2020s. After a journey of approximately one year, MMX will reach Mars and enter orbit. Then, the eight scientific instruments on the exploration module will begin mapping and characterizing the surfaces of Phobos and Deimos. During the course of the mission, the rover is scheduled to land on Phobos. This will involve setting the rover down from an altitude between 40 and 100 meters above the surface. After landing, the rover will autonomously upright itself and then become operational. The measurement phase will then begin; this will last about three months, during which the rover will approach various targets that are of interest for scientific analysis. Towards the end of the mission, ground samples will be collected by the mother spacecraft, taking into account the knowledge acquired using the rover. These will be delivered back to Earth in the return module for more detailed analyses.

The origin of fear and terror
In Greek mythology, Phobos and Deimos were the companions of Ares, the god of war, who in Roman antiquity had his counterpart in Mars, also a god of war. They were discovered in 1877 by the American astronomer Asaph Hall. Due to their small size (Phobos is 27 kilometres in its largest diameter and Deimos 15 kilometres), both moons are irregularly shaped and resemble asteroids. Thus, one theory is that Mars simply captured the two moons in the past, which possibly originated from the asteroid belt. However, both moons orbit Mars near the ecliptic plane on which all planets and most of their moons move around the Sun. In addition, both orbits are almost circular. Such a coincidence would be difficult to account for under the ‘captured asteroids’ theory. This could be explained if Phobos and Deimos were remnants of a huge asteroid impact on Mars. MMX aims to solve this long-discussed mystery of planetary science. The formation of the Mars system is also key to better understanding the processes of planet formation in the Solar System. In any case, traces of martian rocks are likely to be found on the surface of Phobos, which landed on Phobos as ejecta from later asteroid impacts. This means that the samples from Phobos could also bring material from Mars to Earth in the return capsule and thus into terrestrial laboratories.

MMX – Martian Moons eXploration
MMX is a mission of the Japanese space agency JAXA with contributions from NASA, ESA, https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg (the French space agency) and DLR. https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg (Centre national d’études spatiales) and the German Aerospace Center (Deutsches Zentrum für Luft- und Raumfahrt; DLR) are jointly contributing a 25-kilogram rover to the MMX mission. The German-French rover is being designed and built under the joint leadership of https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg and DLR. In particular, DLR is responsible for the development of the rover’s running gear, including the lightweight chassis, as well as the entire locomotion system. DLR is also contributing the connection adapter to the MMX spacecraft and providing a Raman spectrometer and a radiometer as scientific experiments. These will analyse the surface composition, temperature and texture on Phobos. https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg is making significant contributions with camera systems for spatial orientation and exploration on the surface, as well as instruments for the study of mechanical soil properties. https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg is also developing the rover’s central service module, including the on-board computer and the power and communications systems. After the launch of the MMX mission, the rover will be operated by a https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg control centre in Toulouse (France) and a DLR control centre in Cologne (Germany).
The MMX mission is a continuation of an already long-standing successful cooperation between JAXA, https://fscience-old.originis.fr/wp-content/uploads/2023/06/GLOC_Oslo_Norway_S2_27juillet2022_web-2-1.jpg and DLR. It builds on the previous mission, Hayabusa2, in which JAXA sent a spacecraft to the asteroid Ryugu with the German-French MASCOT lander on board. On 3 October 2018, MASCOT landed on Ryugu and sent spectacular images of a landscape covered with boulders and rocks, and virtually no dust. Hayabusa2 collected samples from Ryugu and brought them to Earth on 6 December 2020.


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