Starbursts and torus evolution in AGN

TL;DR

This paper proposes an evolutionary model for AGN tori and starbursts based on recent observations, describing how gas dynamics and star formation influence the lifecycle of the torus over hundreds of millions of years.

Contribution

It introduces an analytical model linking observed gas and starburst properties to the evolutionary phases of AGN tori, highlighting the role of external mass accretion rates.

Findings

Thick, collisional tori can last over 100 million years.

Star formation efficiency in tori is about 10%.

Torus evolution involves transitions from turbulent to thin states.

Abstract

Recent VLT SINFONI observations of the close environments (~30pc) of nearby AGNs have shown that thick gas tori and starbursts with ages between 10 and 150Myr are frequently found. By applying these observations to a previously established analytical model of clumpy accretion disks, we suggest an evolutionary sequence for starburst and AGN phases. Whereas the observed properties of the gas tell us about the current state of the torus, the starburst characteristics provide information on the history of the torus. In the suggested evolution, a torus passes through 3 different phases predetermined by an external mass accretion rate. Started by an initial, short, and massive gas infall, a turbulent and stellar wind-driven Q~1 disk is formed in which the starburst proceeds. Once the supernovae explode the intercloud medium is removed, leaving a massive, geometrically thick, collisional disk with a decreasing, but still high-mass accretion rate. When the mass accretion rate has significantly decreased, the collisional torus becomes thin and transparent as the circumnuclear disk in the Galactic center of the Milky Way. Variations on this scenario are possible either when there is a second short and massive gas infall, in which case the torus may switch back into the starburst mode, or when there is no initial short massive gas infall. All observed tori up to now have been collisional and thick. The observations show that this phase can last more than 100Myr. During this phase the decrease in the mass accretion rate within the torus is slow (a factor of 4 within 150Myr). The collisional tori also form stars, but with an efficiency of about 10% when compared to a turbulent disk.