# Exponentially growing bubbles around early super massive black holes

**Authors:** R. Gilli, F. Calura, A. D'Ercole, C. Norman

arXiv: 1703.05961 · 2017-07-12

## TL;DR

This paper models the growth and impact of outflows driven by early supermassive black holes, revealing exponential expansion dynamics and matching observed thermal energies around quasars at high redshift.

## Contribution

It provides analytic solutions for outflow evolution driven by exponentially growing black holes and compares predictions with observational data at z=6.

## Key findings

- Outflow radius grows exponentially with time, with specific e-folding times.
- Final bubble sizes depend on halo mass, not seed black hole mass.
- Predicted thermal energies align with Sunyaev-Zeldovich observations.

## Abstract

We addressed the so far unexplored issue of outflows induced by exponentially growing power sources, focusing on early supermassive black holes (BHs). We assumed that these objects grow to $10^9\;M_{\odot}$ by z=6 by Eddington-limited accretion and convert 5% of their bolometric output into a wind. We first considered the case of energy-driven and momentum-driven outflows expanding in a region where the gas and total mass densities are uniform and equal to the average values in the Universe at $z>6$. We derived analytic solutions for the evolution of the outflow, finding that, for an exponentially growing power with e-folding time $t_{Sal}$, the late time expansion of the outflow radius is also exponential, with e-folding time of $5t_{Sal}$ and $4t_{Sal}$ in the energy-driven and momentum-driven limit, respectively.   We then considered energy-driven outflows produced by QSOs at the center of early dark matter halos of different masses and powered by BHs growing from different seeds. We followed the evolution of the source power and of the gas and dark matter density profiles in the halos from the beginning of the accretion until $z=6$. The final bubble radius and velocity do not depend on the seed BH mass but are instead smaller for larger halo masses. At z=6, bubble radii in the range 50-180 kpc and velocities in the range 400-1000 km s$^{-1}$ are expected for QSOs hosted by halos in the mass range $3\times10^{11}-10^{13}\;M_{\odot}$.   By the time the QSO is observed, we found that the total thermal energy injected within the bubble in the case of an energy-driven outflow is $E_{th}\sim5 \times 10^{60}$ erg. This is in excellent agreement with the value of $E_{th}=(6.2\pm 1.7)\times 10^{60}$ erg measured through the detection of the thermal Sunyaev-Zeldovich effect around a large population of luminous QSOs at lower redshift. [abridged]

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1703.05961/full.md

## References

88 references — full list in the complete paper: https://tomesphere.com/paper/1703.05961/full.md

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Source: https://tomesphere.com/paper/1703.05961