As part of an international industrial consortium led by Thales Alenia Space, the Astrium site in Friedrichshafen is responsible for Herschel’s payload module consisting of a cryostat (a “super-cooling” system), the optical unit with the instruments and the solar arrays with a sun protection shield (Astrium’s subsidiary Dutch Space). Astrium Spain is involved in the Herschel payload module with electronic parts for the PACS instrument as well as with the electrical cryo-harnesses with extremely low heat conductivity, the service module carbon-fibre structure and the mounting struts to the payload module. In addition, Astrium (Friedrichshafen) is responsible for satellite integration and testing. One of the main technical challenges in implementing Herschel was the lightweight mirror built by the Astrium site in Toulouse and the company Boostec.

This mirror has a weight of only 350 kilograms and a diameter of 3.5 metres. At present, Herschel is the largest imaging space telescope in space. By comparison, the mirror of the Hubble telescope – which operates in the visible wavelength range – is only 2.4 metres across and weighs about one metric ton.

Scientists intend to use the Herschel telescope to peer billions of light years back into deep space and to examine the birth and early development of the stars. Herschel is to observe forming stars and galaxies in the infrared with an unprecedented resolution. Herschel will be able to detect even the weakest heat radiation emanating from cosmic dust as it begins to develop into stars and galaxies. The sensitive instruments need to be cooled to minus 271.5 degrees Celsius (less than two degrees above the absolute zero) inside the cryostat to prevent them from being “blinded” by the heat radiation produced during the satellite’s operation. This low temperature will be achieved using 2,300 litres of liquid helium, which is enough to keep the satellite going in space for more than four years.

ESA’s Planck research satellite will help scientists “travel back in time” 13.8 billion years to the beginnings of the universe and detect its “first light”. The satellite’s two telescope mirrors developed by Astrium in Friedrichshafen have a carbon-fibre sandwich design and will play a key role in capturing what is known as cosmic radiation. They will focus the incident microwave radiation onto two highly sensitive instruments. Astrium Spain provided the structure of the service module and the electronic components for the Planck cooling as well as the instruments HFI and LFI.

Cosmic background radiation is a relic from the dawn of our universe. It began to form just a few hundred thousand years after the Big Bang, when the temperature of the universe was still several thousand degrees. During this period, free protons and electrons – which diverted the direction of the radiation – joined to form neutral hydrogen atoms, and the universe became transparent.

The Planck space telescope will measure this radiation in nine different wave bands over a period of up to two-and-a-half years from its position near the second Lagrange point using a high-frequency and a low-frequency instrument.

By detecting the faintest temperature differences, Planck will not only be able to examine the early stages of our universe, but will hopefully also provide answers to vital cosmological questions: What exactly happened during the Big Bang? What types of matter, radiation and energy is the universe made of today? How old is it, and how did its structures form?

Source: EADS / ESA