How do supermassive black holes (SMBHs) turn their accretion “on” and “off”? How fast can they grow?
How is this related to their circumnuclear stellar and gaseous environments?
What are the consequences for the emergence of the first SMBHs and their co-evolution with galaxies?
The key to answering these and other questions is found in understanding SMBH accretion, in all possible modes and cosmic epochs.
Decades of intensive work have brought huge progress to our understanding of several key aspects of SMBH accretion and evolution, but mainly focused on systems accreting at modest rates, over timescales as long as hundreds of millions of years, which are relatively well-understood and by now easy to identify observationally. In contrast, recent progress in both theory and observations strongly support other, extreme modes of SMBH accretion, namely abrupt changes seen on timescales of weeks-to-months and the possibility of extremely fast, so-called "super-critical" accretion. Both of these extreme accretion scenarios may have observational characteristics that are very different from what we know from “normal” accreting SMBHs (AGN).
This multi-faceted research program is designed to reveal, survey, and characterize extreme modes of SMBH accretion, and to link it to what we know about normally-accreting SMBHs.
This is enabled by the most recent advancements in time-domain and multi-wavelength observational surveys, and informed by state of the art models.
The various research efforts pursued in this program include: (1) Responsive, multi-wavelength, and spectroscopic follow-up observations of hyper-variable accreting SMBHs, on timescales of days to weeks, to gainnew insights as to what starts or stops SMBH accretion; (2) Understanding how common these events are, and whether they share any distinctive properties, based on the huge set of multi-epoch spectroscopic dataset obtained through the SDSS-V survey; (3) Using "flaring" supermassive black holes as indicators of super-critical accretion (beyond the Eddington limit), in order to identify distinctive emission features across the electromagnetic spectrum; (4) A detailed study of highly accreting SMBHs in the local universe, as well as a new exploratory survey of extreme, advection-dominated SMBHs at significant redshifts. These and other new insights will be contextualized and compared with newly established, highly complete distributions of the black hole masses and accretion rates at both low and high redshifts, to understand the role of extreme accretion modes in the general SMBH population and the growth of the most massive black holes in the universe.