Proximity zones of quasars with redshifts $z 6$ are unique probes of
the growth of supermassive black holes. But simultaneously explaining proximity
zone sizes and black hole masses at this redshift has proved to be challenging
because of the very short quasar lifetimes implied by the proximity zones. We
study the robustness of some of the assumptions that are usually made to infer
quasar lifetimes from proximity zone sizes. We show that thanks to the short
equilibration time of gas inside the proximity zones, small proximity zones can
be readily explained by quasars that vary in brightness with a short duty cycle
of $f_duty0.1$ and short bright periods of $t_on\sim
10^4$ yr, even for long lifetimes. We further show that reconciling this with
black hole mass estimates requires the black hole to continue to grow and
accrete during its obscured phase. The consequent obscured fractions of
$\gtrsim$ 0.7 or higher are consistent with low-redshift measurements and
models of black hole accretion. Further, the large dynamic range of our
simulation, and its calibration to the Lyman-$\alpha$ forest, allows us to
investigate the influence of the large-scale topology of reionization and the
quasar's host halo mass on proximity zones. We find that incomplete
reionization can impede the growth of proximity zones and make them smaller up
to 30%, but the quasar host halo mass only affects proximity zones weakly and
indirectly. Our work suggests that high-redshift proximity zones can be an
effective tool to study quasar variability and black hole growth.
Description
The need for obscured supermassive black hole growth to explain quasar proximity zones in the epoch of reionization
%0 Generic
%1 satyavolu2022obscured
%A Satyavolu, Sindhu
%A Kulkarni, Girish
%A Keating, Laura C.
%A Haehnelt, Martin G.
%D 2022
%K library
%T The need for obscured supermassive black hole growth to explain quasar
proximity zones in the epoch of reionization
%U http://arxiv.org/abs/2209.08103
%X Proximity zones of quasars with redshifts $z 6$ are unique probes of
the growth of supermassive black holes. But simultaneously explaining proximity
zone sizes and black hole masses at this redshift has proved to be challenging
because of the very short quasar lifetimes implied by the proximity zones. We
study the robustness of some of the assumptions that are usually made to infer
quasar lifetimes from proximity zone sizes. We show that thanks to the short
equilibration time of gas inside the proximity zones, small proximity zones can
be readily explained by quasars that vary in brightness with a short duty cycle
of $f_duty0.1$ and short bright periods of $t_on\sim
10^4$ yr, even for long lifetimes. We further show that reconciling this with
black hole mass estimates requires the black hole to continue to grow and
accrete during its obscured phase. The consequent obscured fractions of
$\gtrsim$ 0.7 or higher are consistent with low-redshift measurements and
models of black hole accretion. Further, the large dynamic range of our
simulation, and its calibration to the Lyman-$\alpha$ forest, allows us to
investigate the influence of the large-scale topology of reionization and the
quasar's host halo mass on proximity zones. We find that incomplete
reionization can impede the growth of proximity zones and make them smaller up
to 30%, but the quasar host halo mass only affects proximity zones weakly and
indirectly. Our work suggests that high-redshift proximity zones can be an
effective tool to study quasar variability and black hole growth.
@misc{satyavolu2022obscured,
abstract = {Proximity zones of quasars with redshifts $z \gtrsim 6$ are unique probes of
the growth of supermassive black holes. But simultaneously explaining proximity
zone sizes and black hole masses at this redshift has proved to be challenging
because of the very short quasar lifetimes implied by the proximity zones. We
study the robustness of some of the assumptions that are usually made to infer
quasar lifetimes from proximity zone sizes. We show that thanks to the short
equilibration time of gas inside the proximity zones, small proximity zones can
be readily explained by quasars that vary in brightness with a short duty cycle
of $f_\mathrm{duty}\sim 0.1$ and short bright periods of $t_\mathrm{on}\sim
10^4$ yr, even for long lifetimes. We further show that reconciling this with
black hole mass estimates requires the black hole to continue to grow and
accrete during its obscured phase. The consequent obscured fractions of
$\gtrsim$ 0.7 or higher are consistent with low-redshift measurements and
models of black hole accretion. Further, the large dynamic range of our
simulation, and its calibration to the Lyman-$\alpha$ forest, allows us to
investigate the influence of the large-scale topology of reionization and the
quasar's host halo mass on proximity zones. We find that incomplete
reionization can impede the growth of proximity zones and make them smaller up
to 30%, but the quasar host halo mass only affects proximity zones weakly and
indirectly. Our work suggests that high-redshift proximity zones can be an
effective tool to study quasar variability and black hole growth.},
added-at = {2022-09-20T06:47:27.000+0200},
author = {Satyavolu, Sindhu and Kulkarni, Girish and Keating, Laura C. and Haehnelt, Martin G.},
biburl = {https://www.bibsonomy.org/bibtex/2de10efa8530bac373393a490141fce27/gpkulkarni},
description = {The need for obscured supermassive black hole growth to explain quasar proximity zones in the epoch of reionization},
interhash = {e4e0ae5fe408060d7153276623f3486a},
intrahash = {de10efa8530bac373393a490141fce27},
keywords = {library},
note = {cite arxiv:2209.08103Comment: 19 pages, 17 figures, submitted to MNRAS, comments welcome},
timestamp = {2022-09-20T06:47:27.000+0200},
title = {The need for obscured supermassive black hole growth to explain quasar
proximity zones in the epoch of reionization},
url = {http://arxiv.org/abs/2209.08103},
year = 2022
}