New observations from the Herschel Space Observatory have revealed that prodigious star formation in galaxies of the early Universe were often accompanied by ‘fireworks’ in the form of energy bursts caused by the massive central black hole accretion in these galaxies.
The Milky Way Galaxy forms stars at a slow, steady pace: on average one new star a year is born. Since our galaxy contains about a hundred billion stars, the actual changes are very slight. The Milky Way is an extremely quiet galaxy; its central black hole is inactive, with only weak energy outbursts due to the occasional capture of a passing star or gas cloud.
This is in marked contrast to the ‘active’ galaxies of which there are various types and which were abundant in the early Universe. Quasars and radio galaxies are prime examples: owing to their bright, exotic radiation, these objects can be observed as far as the edge of the observable universe. The light of the normal stars in their galaxies is extremely faint at such distances, but active galaxies can be easily detected through their luminous radio, ultraviolet or X-ray radiation, which results from steady accretion onto their massive central black holes.
Until recently these distant active galaxies were only interesting in their own right as peculiar exotic objects. Little was known about the composition of the galaxies, or their relationship to the normal galaxy population. Herschel is considerably larger than NASA’s Hubble, and operates at far-infrared wavelengths. This enables Herschel to detect heat radiation generated by the processes involved in the formation of stars and planets at a small scale, and of complete galaxies at a large scale.
Since 1997, a team led by Dr Peter Barthel of the Kapteyn Institute of the University of Groningen in the Netherlands has used the Herschel cameras to observe seventy of these objects. Initial inspection of the observations has revealed that many emit bright far-infrared radiation.
The study, published in the Astrophysical Journal Letters (arXiv.org version), provides detailed analysis of three distant radio galaxies dubbed 3C 368, 3C 68.2 and 3C 257.
The fact that these three objects, as well as many others from the observational sample, emit strong far-infrared radiation indicates that vigorous star formation is taking place in their galaxies, creating hundreds of stars per year during one or more episodes lasting millions of years. The bright radio emission implies strong, simultaneous black hole accretion. This means that while the black holes in the centers of the galaxies are growing as a consequence of the accretion, the host galaxies are also growing rapidly.
The Herschel observations thereby provide an explanation for the observation that more massive galaxies have more massive black holes. Astronomers have observed this scaling relationship since the 1990s: the fireworks in the early Universe could well be responsible for this relationship.
“It is becoming clear that active galaxies are not only among the largest, most distant, most powerful and most spectacular objects in the Universe, but also among the most important objects; many if not all massive normal galaxies must also have gone through similar phases of simultaneous black hole-driven activity and star formation,” Dr Barthel explained.
Bibliographic information: Peter Barthel et al. 2012. Extreme Host Galaxy Growth in Powerful Early-epoch Radio Galaxies. ApJ 757, L26; doi: 10.1088/2041-8205/757/2/L26