A Theoretical Interpretation of the Black Hole Fundamental Plane

Abstract

We examine the origin and evolution of correlations between properties of supermassive black holes (BHs) and their host galaxies using simulations of major galaxy mergers, including the effects of gas dissipation, cooling, star formation, and BH accretion and feedback. We demonstrate that the simulations predict the existence of a BH 'fundamental plane' (BHFP), of the form MBH sigma(3.0+-0.3)*Re(0.43+-0.19) or MBH Mbulge(0.54+-0.17)*sigma(2.2+-0.5), similar to relations found observationally. The simulations indicate that the BHFP can be understood roughly as a tilted intrinsic correlation between BH mass and spheroid binding energy, or the condition for feedback coupling to power a pressure-driven outflow. While changes in halo circular velocity, merger orbital parameters, progenitor disk redshifts and gas fractions, ISM gas pressurization, and other parameters can drive changes in e.g. sigma at fixed Mbulge, and therefore changes in the MBH-sigma or MBH-Mbulge relations, the BHFP is robust. Given the empirical trend of decreasing Re for a given Mbulge at high redshift, the BHFP predicts that BHs will be more massive at fixed Mbulge, in good agreement with recent observations. This evolution in the structural properties of merger remnants, to smaller Re and larger sigma (and therefore larger MBH, conserving the BHFP) at a given Mbulge, is driven by the fact that bulge progenitors have characteristically larger gas fractions at high redshifts. Adopting the observed evolution of disk gas fractions with redshift, our simulations predict the observed trends in both Re(Mbulge) and MBH(Mbulge).

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…