Herschel is equipped with three instruments that turn the telescope from a mere light-collector into powerful infrared eyes.
The Heterodyne Instrument for the Far Infrared (HIFI)
HIFI, a high-resolution spectrometer, is designed to observe unexploited wavelengths. With its high spectral resolution –– the highest ever in the range of wavelengths it covers –– HIFI will observe an unprecedented level of detail: it will be able to observe and identify individual molecular species in the enormity of space, and study their motion, temperature, and other physical properties. This is fundamental to the study of comets, planetary atmospheres, star formation and the development of distant and nearby galaxies.
HIFI can produce high-resolution spectra of thousands of wavelengths simultaneously. It covers two bands (157–212 microns and 240–625 microns), and uses superconducting mixers as detectors. It was designed and built by a nationally-funded consortium led by SRON Netherlands Institute for Space Research (Groningen, the Netherlands). The consortium includes institutes from France, Germany, USA, Canada, Ireland, Italy, Poland, Russia, Spain, Sweden, Switzerland and Taiwan.
Principal Investigator: Frank Helmich, SRON Netherlands Institute for Space Research, Groningen, The Netherlands.
The Photoconductor Array Camera and Spectrometer (PACS)
PACS consists of a colour camera and an imaging spectrometer. Within its wavelength range (55–210 microns), the PACS camera is the first instrument capable of obtaining the complete image of a target at once. The PACS spectrometer has a lower resolution than that of HIFI, but it is perfectly suited to seeing young galaxies and the gas clouds from which stars form.
PACS operates either as a special camera (photometer) in two colours simultaneously, or as a spectrometer, using either its bolometer or its photoconductor array detectors. It was designed and built by a nationally-funded consortium led by the Max Planck Institute for Extraterrestrial Physics (Garching, Germany); the consortium includes institutes from Belgium, Austria, France, Italy and Spain.
Principal Investigator: Albrecht Poglitsch, Max Planck Institute for Extraterrestrial Physics, Garching, Germany.
The Spectral and Photometric Imaging REceiver (SPIRE)
SPIRE also operates at wavelengths that have not been exploited before (194–672 microns). Like PACS, it consists of a colour camera and an imaging spectrometer, and it covers a complementary range of wavelengths. It is designed to study the star formation history of the Universe.
SPIRE performs photometry; that is, it measures the intensity of the radiation emitted by an astronomical object, in three bands simultaneously, centred on 250, 350 and 500 microns. It can also be operated as an imaging spectrometer. It was designed and built by a nationally-funded consortium led by Cardiff University (Cardiff, UK); the consortium includes France, Canada, China, Italy, Spain, Sweden and the US.
Together, PACS and SPIRE cover six colours of the infrared rainbow.
Herschel's three instruments are complementary: each instrument is designed to study gas and dust, but at different temperatures and states. Thanks to the large range of wavelengths covered, they will be able to witness the entire process of star formation, from the earliest stages of condensation to the moment at which the protostar emerges from its cocoon and is born.
Principal Investigator: Matthew Griffin, Cardiff University, Wales, UK.