Europe opens a window onto a violent Universe
ESA PR 66-2002. The European Space Agency has today launched a new observatory set to revolutionise the branch of astrophysics that seeks to unravel the secrets of the highest energy – and therefore the most violent – phenomena in the Universe.
This comes 20 years after the end of ESA's Cos-B mission, which produced a complete map of the sky in the high-energy gamma-ray waveband.
In the framework of ESA's co-operation with Russia, a Russian Proton launcher was chosen to place the Integral (International Gamma-Ray Astrophysics Laboratory) observatory in orbit. The launcher lifted off from Baikonur in Kazakhstan today at 10:41 local time (06:41 CEST).
After re-ignition of its upper stage, it placed Integral in its 72-hour elliptical orbit, ranging from only 10 000 kilometres up to 153 000 kilometres from the Earth, i.e. nearly half the distance to the Moon.
Controlled by ESA’s ESOC mission operations centre in Darmstadt in Germany, the satellite will now undergo a two-months test period intended first to verify that the instruments onboard are working correctly and then that the data they collect is of good quality.
Integral was developed by Italy's Alenia Spazio supported by over 30 firms in Europe. The satellite (mass 4000 kilograms, height 5 metres) has two main instruments: the SPI spectrometer and IBIS imager.
Developed by a Franco-German-led team, the spectrometer will conduct a spectral analysis of isolated sources and of regions of gamma-ray activity with unprecedented energy resolution (40 times better than previous satellites), using germanium detectors cooled to 85 Kelvin. Since mirrors and lenses are of no use in detecting gamma rays, the SPI uses the 'coded-mask imaging' technique to form its images from very faint radiation. These images are then decoded by computer.
The imager, designed by an Italian-led team, is the perfect partner for SPI. It has a weaker energy resolution, but an angular resolution 12 times sharper thanks to a coded mask optimised for the purpose and two new-generation detector layers.
To supplement the observations by SPI and IBIS, Integral also carries a Danish X-ray imager (JEM-X), with twin detectors each fitted with coded masks, and a Spanish CCD imager (OMC) operating in the visible spectrum waveband.
By combining the data collected by these four instruments, it will be possible, for the first time, to make simultaneous observations of high-energy phenomena at seven orders of magnitude, from visible light to gamma rays. All the raw data collected by Integral will be sent directly to the ground via the ESA station at Redu in Belgium, or the station operated by NASA – another partner in the programme – at Goldstone in the USA. The raw data will be centralised at ESOC in order to be processed and redistributed to the scientific community via the Integral Scientific Data Centre (ISDC) at Versoix in Switzerland.
Operating in an orbit that enables it to spend most of its time outside the Van Allen radiation belts, which can hamper observation of cosmic gamma rays, Integral will primarily study the densest sky objects, such as neutron stars and black holes, which are all sources of very high energy radiation. While IBIS will supply very detailed images of these sources, SPI will conduct the first in-depth analysis of this gamma radiation. Integral’s observations should enable astrophysicists to confirm the presence of giant black holes at the centre of galaxies, starting with the Milky Way.
Other areas of interest for the European gamma-ray observatory will include events of rare violence such as nova and supernova explosions. These will be explored with precision thanks to the gamma radiation given off by the radioactive isotopes emitted. Integral will also be a unique means for observing gamma bursts, these still largely unexplained explosions at the outer reaches of the Universe, which for the first time can be studied in parallel along a wide range of the electromagnetic spectrum.
Integral is the second medium-size mission carried out under the Horizon 2000 programme, following the Huygens probe, whose destination is Saturn and its moon Titan; the third will be the Planck observatory, which will study the background noise of the Universe, as from 2007. The Integral mission should last at least two years.