We compute the bispectra of the 21cm signal during the Epoch of Reionization
for three different reionization scenarios that are based on a dark matter
N-body simulation combined with a self-consistent, semi-numerical model of
galaxy evolution and reionization. Our reionization scenarios differ in their
trends of ionizing escape fractions ($f_esc$) with the underlying
galaxy properties and cover the physically plausible range, i.e.
$f_esc$ effectively decreasing, being constant, or increasing with
halo mass. We find the 21cm bispectrum to be sensitive to the resulting
ionization topologies that significantly differ in their size distribution of
ionized and neutral regions throughout reionization. From squeezed to stretched
triangles, the 21cm bispectra features a change of sign from negative to
positive values, with ionized and neutral regions representing below-average
and above-average concentrations contributing negatively and positively,
respectively. The position of the change of sign provides a tracer of the size
distribution of the ionized and neutral regions, and allows us to identify
three major regimes that the 21cm bispectrum undergoes during reionization. In
particular the regime during the early stages of reionization, where the 21cm
bispectrum tracks the peak of the size distribution of the ionized regions,
provides exciting prospects for pinning down reionization with the forthcoming
Square Kilometre Array.
Description
The 21cm bispectrum during reionization: a tracer of the ionization topology
%0 Generic
%1 hutter2019bispectrum
%A Hutter, Anne
%A Watkinson, Catherine A.
%A Seiler, Jacob
%A Dayal, Pratika
%A Sinha, Manodeep
%A Croton, Darren J.
%D 2019
%K library
%T The 21cm bispectrum during reionization: a tracer of the ionization
topology
%U http://arxiv.org/abs/1907.04342
%X We compute the bispectra of the 21cm signal during the Epoch of Reionization
for three different reionization scenarios that are based on a dark matter
N-body simulation combined with a self-consistent, semi-numerical model of
galaxy evolution and reionization. Our reionization scenarios differ in their
trends of ionizing escape fractions ($f_esc$) with the underlying
galaxy properties and cover the physically plausible range, i.e.
$f_esc$ effectively decreasing, being constant, or increasing with
halo mass. We find the 21cm bispectrum to be sensitive to the resulting
ionization topologies that significantly differ in their size distribution of
ionized and neutral regions throughout reionization. From squeezed to stretched
triangles, the 21cm bispectra features a change of sign from negative to
positive values, with ionized and neutral regions representing below-average
and above-average concentrations contributing negatively and positively,
respectively. The position of the change of sign provides a tracer of the size
distribution of the ionized and neutral regions, and allows us to identify
three major regimes that the 21cm bispectrum undergoes during reionization. In
particular the regime during the early stages of reionization, where the 21cm
bispectrum tracks the peak of the size distribution of the ionized regions,
provides exciting prospects for pinning down reionization with the forthcoming
Square Kilometre Array.
@misc{hutter2019bispectrum,
abstract = {We compute the bispectra of the 21cm signal during the Epoch of Reionization
for three different reionization scenarios that are based on a dark matter
N-body simulation combined with a self-consistent, semi-numerical model of
galaxy evolution and reionization. Our reionization scenarios differ in their
trends of ionizing escape fractions ($f_\mathrm{esc}$) with the underlying
galaxy properties and cover the physically plausible range, i.e.
$f_\mathrm{esc}$ effectively decreasing, being constant, or increasing with
halo mass. We find the 21cm bispectrum to be sensitive to the resulting
ionization topologies that significantly differ in their size distribution of
ionized and neutral regions throughout reionization. From squeezed to stretched
triangles, the 21cm bispectra features a change of sign from negative to
positive values, with ionized and neutral regions representing below-average
and above-average concentrations contributing negatively and positively,
respectively. The position of the change of sign provides a tracer of the size
distribution of the ionized and neutral regions, and allows us to identify
three major regimes that the 21cm bispectrum undergoes during reionization. In
particular the regime during the early stages of reionization, where the 21cm
bispectrum tracks the peak of the size distribution of the ionized regions,
provides exciting prospects for pinning down reionization with the forthcoming
Square Kilometre Array.},
added-at = {2019-07-11T05:41:59.000+0200},
author = {Hutter, Anne and Watkinson, Catherine A. and Seiler, Jacob and Dayal, Pratika and Sinha, Manodeep and Croton, Darren J.},
biburl = {https://www.bibsonomy.org/bibtex/2a4ddc3922a99618856f8793681fcf7b1/gpkulkarni},
description = {The 21cm bispectrum during reionization: a tracer of the ionization topology},
interhash = {7cfc5bfa848b513317e335bd43398ab8},
intrahash = {a4ddc3922a99618856f8793681fcf7b1},
keywords = {library},
note = {cite arxiv:1907.04342Comment: 16 pages, 7 figures, submitted to MNRAS, comments welcome},
timestamp = {2019-07-11T05:41:59.000+0200},
title = {The 21cm bispectrum during reionization: a tracer of the ionization
topology},
url = {http://arxiv.org/abs/1907.04342},
year = 2019
}