Rosetta will be the first mission ever to land on a comet. After its lander reaches the comet, the main spacecraft will follow the comet for many months as it heads towards the Sun. Rosetta’s task is to study comets, which are considered the primitive building blocks of the Solar System. It will help us understand if life on Earth began with the help of comet seeding.
Rosetta is one of the most challenging missions ever - many of the complex navigation and landing manoeuvres need to take place automatically with absolutely no room for error. The issues and complications of sending a small spacecraft halfway across the solar system and soft-land on a small comet are immense.
- A large number of complex scientific instruments need to be accommodated on one side of the spacecraft, which must permanently face the comet during the operational phase of the mission.
- The spacecraft needs to endure both extremes of temperature, from that of deep space to very close to the active comet
- Complex spacecraft navigation needs to take place at low altitude orbits around the dust and gas jets of the comet which also has a weak but asymmetrical, rotating gravity field.
- The Rosetta Lander has to be stowed to survive the cruise and eventually to self-eject from the spacecraft. The orbiter must navigate with millimetre accuracy for the ejection, and then relay data from the Lander back to Earth.
Rosetta will be the first space mission to journey beyond the main asteroid belt and rely solely on solar cells for power generation, rather than the traditional radio-isotope thermal generators. The new solar-cell technology used on the Orbiter's two giant solar panels allows it to operate over 800 million km from the Sun, where sunlight levels are only 4% of those on Earth. Hundreds of thousands of specially developed non-reflective, silicon cells generate up to 8700 W in the inner Solar System and around 400 W for the deep-space comet encounter.
The Rosetta mission will achieve many historic landmarks:
- Rosetta will be the first spacecraft to orbit a comet's nucleus.
- It will be the first spacecraft to fly alongside a comet as it heads towards the inner Solar System.
- Rosetta will be the first spacecraft to examine from close proximity how a frozen comet is transformed by the warmth of the Sun.
- Shortly after its arrival at the comet, the Rosetta Orbiter will dispatch a robotic Lander for the first controlled touchdown on a comet nucleus.
The main spacecraft measures 2.8m x 2.1m x 2.0m, on which all subsystems and payload equipment are mounted. There are two 14-metre-long solar panels with a total area of 64 square metres. At launch, the vehicle weighs approximately 3,000kg (fully fuelled) including 1670kg of propellant, 165kg of scientific payload for the orbiter and 100kg for the lander.
The 'top' of the spacecraft accommodates the payload instruments, and the 'base' of the spacecraft the subsystems. The large number of complex scientific instruments need to be accommodated on one side of the spacecraft, which must permanently face the comet during the operational phase of the mission. Until its release, the Lander is carried on the opposite side of the Orbiter to the large, dish-shaped high-gain antenna.
As it arrives on the comet, the Rosetta Lander uses three different techniques (self-adjusting landing gear, harpoons and a drill) to ensure that once it has arrived on the surface of the comet, it stays there.
As soon as it touches down, two harpoons will anchor the probe to the surface, the self-adjusting landing gear will ensure that it stays upright, even on a slope and then the lander's feet will drill into the ground. These devices will help counteract the fact that there is very low gravity on a comet. In place, the Lander will focus on the study of the composition and structure of the comet nucleus material. Goals include the determination of the elements that exist, traces of minerals and isotopic composition of the comet's surface and immediate subsurface. In addition the comet's surface strength, density, texture, porosity, ice phases and thermal properties will be looked at. Texture investigations will include microscopic studies of individual grains.
The journey to Rosetta's final destination will involve complex fly-bys,
The Orbiter's scientific payload includes 11 experiments and a small Lander which is equipped with its own payload of scientific instruments. Scientific consortia from institutes across Europe and the United States have provided these state-of-the-art instruments.
The Lander is provided by a European consortium under the leadership of the German Aerospace Research Institute (DLR). Other members of the consortium are ESA, CNES and institutes from Austria, Finland, France, Hungary, Ireland, Italy and the UK.
Last update: 6 May 2004