How the monsters were made: the formation of the most massive black holes in the Universe

It is currently believed that at the centre of every massive galaxy in the Universe, there lies a super-massive black hole (SMBH). Some of these SMBH have now been measured to have as much mass as 10 billion Suns, all squeezed into a volume similar to that of our own solar-system. When these monster SMBH grow by eating in matter that has fallen into their surroundings, they can release huge amounts of energy in the process. This makes them the most extreme and energetic objects in our Universe. While extraordinary and fascinating objects in their own right, these SMBH are also believed to play an important role in the evolution of their host galaxies, including those like our own Milky Way. So if we want to completely understand the origins of our galaxy, understanding how these monsters came to form and evolve is crucial. The goal of the HIZRAD project was to help build a complete picture of the early stages of SMBH formation - answering the questions of how, when and where the most extreme objects in our Universe were formed.

The project made use extensive new radio sky survey from the pan-European radio telescope, the Low Frequency Array (LOFAR), to study actively growing black holes, or Active Galactic Nuclei (AGN), throughout cosmic history. The unique power of these new radio observations is that they can peer through the gas and dust that obscure other signs of activity, meaning that LOFAR is able to reveal AGN activity that has previously been hidden from us. However, while LOFAR offers an enormous leap in our ability to discover these new AGN deep into the earliest stages of cosmic history, it cannot provide a complete picture alone. There is crucial information about these AGN that cannot be learned from their radio emission and so we must combine these data with other measurements across the electromagnetic spectrum in order to unlock their full potential.

The overall objective of the HIZRAD project was to answer the question; what was the accretion history of super-massive black holes in the early Universe? Specifically, we sought to discover news samples of the most extreme SMBH right at the very earliest stages of cosmic history and to measure how this population evolved over the early history of the Universe. We aimed to combine the LOFAR surveys with the best available complementary data from optical and infrared telescopes, including a a state-of-the-art optical survey of radio detected galaxies due to start early in the project.

Modern astronomical surveys are now so sensitive that they can contain galaxies in their millions or even billions. Finding the rare and extreme SMBH we want to study is therefore like the proverbial search for the needle amongst a very large haystack. The initial phase of the HIZRAD project focused on the vital step of combining all the available information in our optical surveys to estimate the distance to each galaxy, allowing us to identify the most distant for further study. The approach we used combines multiple different methods, including state-of-the-art machine learning techniques, to produce the most accurate and reliable distance measurements possible. The first phase of the work was split into two projects, one which studied a small patch of sky with very detailed and sensitive measurements, and a second that covered almost the full sky (outside of our own Milky Way) but with more limited data available for each galaxy. These projects resulted in two published journal articles, each also producing a substantial dataset suitable for exploitation by the wider community to address a wide range of scientific objectives.

The second phase of this project sought to discover and study new samples of the most distant active SMBH using brand new observations from the WEAVE-LOFAR spectroscopic survey. However, the Covid-19 pandemic struck at a particularly critical time in the final stages of shipping and installation of the WEAVE instrument that will perform this observational survey, substantially delaying this new dataset. We instead focused effort on providing a complete census of the radio properties of the currently known SMBH population in the early Universe and to combine this data with the dataset produced in the first phase of the project to discover new samples of distant SMBH. This phase of the project also resulted in two published journal articles. In the first of these, we present the first systematic study of the low-frequency radio properties of the known active SMBH that reside in the first two billion years of cosmic history. This work revealed that 36% of this population are detected in the LOFAR radio surveys, a factor of 5-10 more than previous large sky radio surveys. Further exploration of the evolution of their radio properties as a function of distance and other physical properties revealed a number of previously unobserved physical trends. The second journal article presents the discovery of 20 newly discovered active SMBH in the early Universe (and the independent confirmation of 4), nearly doubling the number of these sources known to host luminous radio jets.

Finally, although the WEAVE instrument originally intended for use in this project was significantly delayed, throughout the project we also worked on the scientific and technical preparation for the WEAVE Surveys. The effort has been critical in the preparations for WEAVE and for ensuring the future impact of the project through the success of the forthcoming WEAVE-LOFAR survey.

The datasets produced by this project represent progress beyond the previous state-of-the-art in a range of ways. Firstly, the techniques employed in the first phase of the project are at the forefront of the field, including the novel application of machine learning techniques to extremely large datasets. The datasets produced by this project offer distance estimates predicted to be of high quality for almost 1 billion galaxies, ranging from those in the very nearby Universe out to some of the most distant ever discovered. This dataset therefore offers one of the most extensive samples of redshifts (i.e. distance) ever produced. The datasets produced in this project have already been exploited to produce over 20 published research articles and they will continue to provide an extremely valuable resource both to the worldwide community.

In the second phase of the project, the discovery and analysis of 24 radio bright active SMBH in the earliest epoch of the Universe more than doubles the sample of this type of object currently known, substantially improving on the previous state-of-the-art. Furthermore, the techniques employed demonstrate the proof of concept that can be applied to future datasets that can address a range of new scientific objectives.

The project has also been crucial in the future success of WEAVE-LOFAR, which will advance the state-of-the-art by providing optical spectra for over a million LOFAR radio sources. These observations will provide precise distance information and enable measurements of fundamental physical properties that are highly complementary to the datasets produced by this project. The enormous samples provided by this combination of datasets are essential if we are to study the full diversity of the SMBH population and discover the rarest and most extreme sources - those which truly test the limits of our understanding.