TY - JOUR
T1 - ARTIST
T2 - fast radiative transfer for large-scale simulations of the epoch of reionization
AU - Molaro, Margherita
AU - Dave, Romeel
AU - Hassan, Sultan
AU - Santos, Mario G.
AU - Finlator, Kristian
PY - 2019/11/11
Y1 - 2019/11/11
N2 - We introduce the ‘Asymmetric Radiative Transfer In Shells Technique’ (ARTIST), a new method for photon propagation on large scales that explicitly conserves photons, propagates photons at the speed of light, approximately accounts for photon directionality, and closely reproduces results of more detailed radiative transfer (RT) methods. Crucially, it is computationally fast enough to evolve the large cosmological volumes required to predict the 21cm power spectrum on scales that will be probed by future experiments targeting the epoch of reionization (EoR). Most seminumerical models aimed at predicting the EoR 21cm signal on these scales use an excursion set formalism (ESF) to model the gas ionization, which achieves computational viability by making a number of approximations. While ARTIST is still roughly two orders of magnitude slower than ESF, it does allow to model the EoR without the need for such approximations. This is particularly important when considering a wide range of reionization scenarios for which ARTIST would help limit the assumptions made. By implementing our RT method within the seminumerical code SIMFAST21, we show that ARTIST predicts a significantly different evolution for the EoR ionization field compared to the code’s native ESF. In particular, ARTIST predicts up to a factor of two difference in the power spectra, depending on the physical parameters assumed. Its application to large-scale EoR simulations will therefore allow more physically motivated constraints to be obtained for key EoR parameters. In particular, it will remove the need for the artificial rescaling of the escape fraction.
AB - We introduce the ‘Asymmetric Radiative Transfer In Shells Technique’ (ARTIST), a new method for photon propagation on large scales that explicitly conserves photons, propagates photons at the speed of light, approximately accounts for photon directionality, and closely reproduces results of more detailed radiative transfer (RT) methods. Crucially, it is computationally fast enough to evolve the large cosmological volumes required to predict the 21cm power spectrum on scales that will be probed by future experiments targeting the epoch of reionization (EoR). Most seminumerical models aimed at predicting the EoR 21cm signal on these scales use an excursion set formalism (ESF) to model the gas ionization, which achieves computational viability by making a number of approximations. While ARTIST is still roughly two orders of magnitude slower than ESF, it does allow to model the EoR without the need for such approximations. This is particularly important when considering a wide range of reionization scenarios for which ARTIST would help limit the assumptions made. By implementing our RT method within the seminumerical code SIMFAST21, we show that ARTIST predicts a significantly different evolution for the EoR ionization field compared to the code’s native ESF. In particular, ARTIST predicts up to a factor of two difference in the power spectra, depending on the physical parameters assumed. Its application to large-scale EoR simulations will therefore allow more physically motivated constraints to be obtained for key EoR parameters. In particular, it will remove the need for the artificial rescaling of the escape fraction.
KW - radiative transfer
KW - dark ages, reionization, first stars
U2 - 10.1093/mnras/stz2171
DO - 10.1093/mnras/stz2171
M3 - Journal article
SN - 0035-8711
VL - 489
SP - 5594
EP - 5611
JO - Royal Astronomical Society. Monthly Notices
JF - Royal Astronomical Society. Monthly Notices
IS - 4
ER -