Fast Inflow Directly Feeding Black Hole Accretion Disk in Quasars

TL;DR

This paper reports the first clear observational evidence of cold gas inflows directly feeding the accretion disks of quasars, revealing a new method to study SMBH fueling mechanisms.

Contribution

It introduces the detection of highly redshifted broad absorption lines indicating inflowing gas, providing direct insight into quasar fueling processes.

Findings

Detected broad absorption lines from neutral hydrogen and helium in quasars.

Observed inflow velocities up to 5,000 km/s indicating rapid inward gas movement.

Photo-ionization modeling suggests dense, moderately ionized gas close to the SMBH.

Abstract

Quasars are high-luminosity active galactic nuclei believed to be powered by accretion of interstellar matter onto a super-massive black hole (SMBH) therein. Most of the observed energy is released in an accretion disk of inspiralling gas surrounding the SMBH. An enormous amount of fueling material is expected to be transported inwards. However, basic questions remain unanswered as to whether and how the accretion disks are supplied with external gas, since no disk-feeding inflow has hitherto been observed clearly. Here we report the discovery of highly redshifted broad absorption lines arising from neutral hydrogen and helium atoms in a small sample of quasars. Their absorption troughs show a broad range of Doppler velocities from zero extending continuously inward up to as high as $\sim 5,000$ km s$^{-1}$. We thus see through streams of cold gas moving with a radially inward velocity component that spans an immense gradient---a result of gravitational acceleration by the central SMBH. Extensive photo-ionization modeling for the archetypical object SDSS J103516.20+142200.6 indicates the inflowing gas to be dense, thick and moderately ionized, with a characteristic distance to the SMBH of $\sim 1,000$ gravitational radii, possibly overlapping or close to the outer accretion disk. Our results present the first compelling evidence for the long-sought inflow directly feeding quasars' accretion disks with external materials, likely originating from the dusty torus at a parsec scale. Our approach provides a new tool to probe the bulk of the so far elusive fueling inflows in quasars. Their studies may help address some of the fundamental questions concerning accretion physics, the onset and sustainment of quasar activity, and the SMBH growth at centers of most galaxies.