Cosmology from the integrated shear 3-point correlation function: simulated likelihood analyses with machine-learning emulators
Abstract
The integrated shear 3-point correlation function measures the correlation between the local shear 2-point function and the 1-point shear aperture mass in patches of the sky. Unlike other higher-order statistics, can be efficiently measured from cosmic shear data, and it admits accurate theory predictions on a wide range of scales as a function of cosmological and baryonic feedback parameters. Here, we develop and test a likelihood analysis pipeline for cosmological constraints using . We incorporate treatment of systematic effects from photometric redshift uncertainties, shear calibration bias and galaxy intrinsic alignments. We also develop an accurate neural-network emulator for fast theory predictions in MCMC parameter inference analyses. We test our pipeline using realistic cosmic shear maps based on -body simulations with a DES Y3-like footprint, mask and source tomographic bins, finding unbiased parameter constraints. Relative to -only, adding can lead to improvements on the constraints of parameters like (or ) and . We find no evidence in constraints of a significant mitigation of the impact of systematics. We also investigate the impact of the size of the apertures where is measured, and of the strategy to estimate the covariance matrix (-body vs. lognormal). Our analysis solidifies the strong potential of the statistic and puts forward a pipeline that can be readily used to improve cosmological constraints using real cosmic shear data.
Keywords
Cite
@article{arxiv.2304.01187,
title = {Cosmology from the integrated shear 3-point correlation function: simulated likelihood analyses with machine-learning emulators},
author = {Zhengyangguang Gong and Anik Halder and Alexandre Barreira and Stella Seitz and Oliver Friedrich},
journal= {arXiv preprint arXiv:2304.01187},
year = {2023}
}
Comments
21 pages, 11 figures, 3 tables. Comments welcome