Precise cosmological constraints from BOSS galaxy clustering with a simulation-based emulator of the wavelet scattering transform
Georgios Valogiannis, Sihan Yuan, Cora Dvorkin
Abstract
We perform a reanalysis of the BOSS CMASS DR12 galaxy dataset using a simulation-based emulator for the wavelet scattering transform (WST) coefficients. Moving beyond our previous works, which laid the foundation for the first galaxy clustering application of this estimator, we construct a neural net-based emulator for the cosmological dependence of the WST coefficients and the 2-point correlation function multipoles, trained from the state-of-the-art suite of abacussummit simulations combined with a flexible halo occupation distribution (HOD) galaxy model. In order to confirm the accuracy of our pipeline, we subject it to a series of thorough internal and external mock parameter recovery tests, before applying it to reanalyze the CMASS observations in the redshift range $0.46<z<0.57$. We find that a joint $\mathrm{WST}+2$-point correlation function likelihood analysis allows us to obtain marginalized $1\ensuremath{\sigma}$ errors on the $\mathrm{\ensuremath{\Lambda}}\mathrm{CDM}$ parameters that are tighter by a factor of 2.5--6, compared to the 2-point correlation function, and by a factor of 1.4--2.5 compared to the WST-only results. This corresponds to a competitive 0.9%, 2.3% and 1% level of determination for parameters ${\ensuremath{\omega}}_{c}$, ${\ensuremath{\sigma}}_{8}&{n}_{s}$, respectively, and also to a 0.7% and 2.5% constraint on derived parameters h and $f(z){\ensuremath{\sigma}}_{8}(z)$, in agreement with the Planck 2018 results. Our results reaffirm the constraining power of the WST and highlight the exciting prospect of employing higher-order statistics in order to fully exploit the power of upcoming stage-IV spectroscopic observations.