Supermassive black holes (SMBHs) – black holes with masses exceeding a million times that of the Sun – are known to prevail in the universe today. However, it is not clear yet when, where, and how they formed during the 13.8 billion years of cosmic history.
Observations in the past few decades have revealed that every galaxy harbors a SMBH in the center, and that the black hole mass is almost always one-thousandth of the host galaxy mass. This close relationship implies that galaxies and SMBHs have co-evolved together. Revealing the origin of SMBHs is thus crucial not only to understand SMBHs themselves, but also to elucidate the formation processes of galaxies, the major constituents of the visible universe.
A key to addressing this issue lies in the early universe, where the time elapse since the Big Bang (i.e., the beginning of the universe) was less than a billion years. Thanks to the finite speed of light, we can look back at the past by observing the distant universe. Did SMBHs already exist when the universe was only a billion years old or less? Is it possible for a black hole to acquire such a large mass (exceeding a million solar masses and sometimes reaching billions of solar masses) in such a short time? If so, what are the underlying physical mechanisms and conditions? In order to close in on the origin of SMBHs, we need to observe them and compare their properties with predictions from theoretical models. And in order to do so, we first need to find where they are in the sky.
Researchers used the Subaru Telescope at the top of Maunakea, Hawaii, for the present study.
One of the biggest advantages of Subaru is its widefield observing capability, which is particularly suited for our purpose. Since SMBHs do not emit light, we looked for a special class called “quasars” – SMBHs with shining outskirts where the infalling material releases gravitational energy. We observed a wide sky area equivalent to 5000 times the full moon, and successfully discovered 162 quasars residing in the early universe. In particular, 22 of them lived in the era when the universe was less than 800 million years old – the most ancient period in which quasars have been recognized to date. The large number of quasars we discovered has allowed us to determine the most fundamental measure called the “luminosity function”, which describes the space density of quasars as a function of radiation energy. We found that quasars were forming very rapidly in the early universe, while the overall shape of the luminosity function (except for the amplitude) remained unchanged over time.
This characteristic behavior of the luminosity function provides strong constraints on theoretical models, which could ultimately reproduce all the observables and describe the origin of SMBHs.
On the other hand, the universe was known to have experienced a major phase transition called “cosmic reionization” in its early stage. Past observations suggest that the whole intergalactic space was ionized in this event. The source of the ionization energy is still under debate, with radiation from quasars being considered as a promising candidate. By integrating the above luminosity function, we found that quasars emit 1028 photons per second in a unit volume of 1 light-year on a side in the early universe. This is less than 1% of the photons needed to maintain the ionized state of the intergalactic space at that time, and thus indicates that quasars made only a minor contribution to cosmic reionization. Other energy sources are critically needed, which, according to other recent observations, may be the integrated radiation from massive hot stars in forming galaxies.