Cracking a Mystery of Massive Black Holes and Quasars

Quasar Illustration

A quasar – the most luminous persistent source of light in the universe. Credit: NASA

A discovery that provides new insight into how galaxies evolve.

At the center of galaxies, like our own

Distribution of Gas Across Scales

Distribution of gas across scales, with the gas density increasing from purple to yellow. The top left panel shows a large region containing tens of galaxies (6 million light-years across). Subsequent panels zoom in progressively into the nuclear region of the most massive galaxy and down to the vicinity of the central supermassive black hole. Gas clumps and filaments fall from the inner edge of the central cavity occasionally feeding the black hole. Credit: Anglés-Alcázar et al. 2021, ApJ, 917, 53.

Anglés-Alcázar, who is also an Associate Research Scientist at the Flatiron Institute Center for Computational Astrophysics, says a challenge in answering these questions has been creating models powerful enough to account for the numerous forces and factors that play into the process. Previous works have looked either at very large scales or the very smallest of scales, “but it has been a challenge to study the full range of scales connected simultaneously.”

Galaxy formation, Anglés-Alcázar says, starts with a halo of dark matter that dominates the mass and gravitational potential in the area and begins pulling in gas from its surroundings. Stars form from the dense gas, but some of it must reach the center of the galaxy to feed the [embedded content]

The new simulations provide key insights into the nature of quasars, showing that strong gravitational forces from stars can twist and destabilize the gas across scales, and drive sufficient gas influx to power a luminous quasar at the epoch of peak galaxy activity.

In visualizing this series of events, it is easy to see the complexities of modeling them, and Anglés-Alcázar says it is necessary to account for the myriad components influencing black hole evolution.

“Our simulations incorporate many of the key physical processes, for example, the hydrodynamics of gas and how it evolves under the influence of pressure forces, gravity, and feedback from massive stars. Powerful events such as supernovae inject a lot of energy into the surrounding medium and this influences how the galaxy evolves, so we need to incorporate all of these details and physical processes to capture an accurate picture.”

Building on previous work from the FIRE (“Feedback In Realistic Environments”) project, Anglés-Alcázar explains the new technique outlined in the paper that greatly increases model resolution and allows for following the gas as it flows across the galaxy with more than a thousand times better resolution than previously possible,

“Other models can tell you a lot of details about what’s happening very close to the black hole, but they don’t contain information about what the rest of the galaxy is doing, or even less, what the environment around the galaxy is doing. It turns out, it is very important to connect all of these processes at the same time, this is where this new study comes in.”

The computing power is similarly massive, Anglés-Alcázar says, with hundreds of central processing units (CPUs) running in parallel that could have easily taken the length of millions of CPU hours.

“This is the first time that we have been able to create a simulation that can capture the full range of scales in a single model and where we can watch how gas is flowing from very large scales all the way down to the very center of the massive galaxy that we are focusing on.”

For future studies of large statistical populations of galaxies and massive black holes, we need to understand the full picture and the dominant physical mechanisms for as many different conditions as possible, says Anglés-Alcázar.

“That is something we are definitely excited about. This is just the beginning of exploring all of these different processes that explain how black holes can form and grow under different regimes.”

For more on this research, read New Simulation Reveals How Galaxies Feed Their Supermassive Black Holes.

Reference: “Cosmological simulations of quasar fueling to sub-parsec scales using Lagrangian hyper-refinement” by Daniel Anglés-Alcázar, Eliot Quataert, Philip F. Hopkins, Rachel S. Somerville, Christopher C. Hayward, Claude-André Faucher-Giguère, Greg L. Bryan, Dušan Kereš, Lars Hernquist and James M. Stone, 17 August 2021, Astrophysical Journal.
DOI: 10.3847/1538-4357/ac09e8

In addition to Anglés-Alcázar, the study includes authors from the FIRE and SMAUG (“Simulating Multiscale Astrophysics to Understand Galaxies”) collaborations: Eliot Quataert (University of California Berkeley and

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