Towards an understanding of the evolution of the scaling relations for supermassive black holes

TL;DR

This paper investigates how supermassive black hole-galaxy scaling relations evolve over cosmic time using simulations and analytical models, revealing stable relations with halo binding energy but evolving ratios with galaxy mass.

Contribution

It demonstrates that certain black hole scaling relations remain constant over time while others evolve, supported by simulation and analytical modeling.

Findings

Simulation reproduces observed local relations and their evolution.

Relations with halo binding energy do not evolve with redshift.

Mass ratios increase with redshift for massive galaxies.

Abstract

The growth of the supermassive black holes (BHs) that reside at the centres of most galaxies is intertwined with the physical processes that drive the formation of the galaxies themselves. The evolution of the relations between the mass of the BH, m_BH, and the properties of its host therefore represent crucial aspects of the galaxy formation process. We use a cosmological simulation, as well as an analytical model, to investigate how and why the scaling relations for BHs evolve with cosmic time. We find that a simulation that reproduces the observed redshift zero relations between m_BH and the properties of its host galaxy, as well as the thermodynamic profiles of the intragroup medium, also reproduces the observed evolution in the ratio m_BH/m_s for massive galaxies, although the evolution of the m_BH/sigma relation is in apparent conflict with observations. The simulation predicts that the relations between m_BH and the binding energies of both the galaxy and its dark matter halo do not evolve, while the ratio m_BH/m_halo increases with redshift. The simple, analytic model of Booth & Schaye (2010), in which the mass of the BH is controlled by the gravitational binding energy of its host halo, quantitatively reproduces the latter two results. Finally, we can explain the evolution in the relations between m_BH and the mass and binding energy of the stellar component of its host galaxy for massive galaxies (m_s~10^11 M_sun) at low redshift (z<1) if these galaxies grow primarily through dry mergers.