MACER improved: AGN feedback computed in rotating early-type galaxies at high resolution

TL;DR

This paper presents an improved high-resolution model of AGN feedback in rotating early-type galaxies, incorporating rotation, star formation regulation, and hot mode feedback, aligning well with various astronomical observations.

Contribution

The model extends previous work by including galaxy rotation, refined star formation criteria, and enhanced hot mode AGN feedback treatment, with parsec-scale resolution.

Findings

AGN activity and star formation occur mainly in central cold disks.

AGN duty cycle matches observational constraints like the Soltan argument.

Star formation is a few percent of initial stellar mass, mainly in circumnuclear disks.

Abstract

Based on our previous modeling of AGN feedback in isolated elliptical galaxies (Gan et al. 2014) using the MACER (Massive AGN Controlled Ellipticals Resolved) code, we extend and improve the model to include rotation, to limit star formation to regions of high density and low temperature, to facilitate angular momentum transfer via the Toomre instability in gaseous disks, and to improve the treatment of hot mode (low accretion rate) AGN feedback. The model galaxy now has an extended dark matter profile that matches with standard observations, but has a resolution of parsecs in the inner region and resolves the Bondi radius. We find that the results agree reasonably well with a panoply of observations: (1) both AGN activity and star formation are primarily in central cold gaseous disks, are bursty and mainly driven by the Toomre instability; (2)AGN duty cycle agrees well with the Soltan argument, i.e., the AGN spends most of its lifetime when it is in low luminosity (half of time with $L/L_{Edd}<7\times10^{-5}$), while emitting most of its energy when it is in high luminosity (half of radiant energy emitted with $L/L_{Edd}>0.06$); (3) the total star formation is $\sim$ few percents of the initial stellar mass, occurring in the bursts that would be associated with the observed E+A phenomenon. Most of the star formation occurs in the circumnuclear disk of a size <1 kpc, which is in agreement with recent observations; (4) the ISM X-ray luminosity varies within a reasonable range (median $L_{\rm X, ISM}=9.1\times10^{39}$ erg/s) in agreement with observations.