Three-Dimensional Reconstruction of Weak Lensing Mass Maps with a Sparsity Prior. I. Cluster Detection

Abstract

We propose a novel method to reconstruct high-resolution three-dimensional mass maps using data from photometric weak-lensing surveys. We apply an adaptive LASSO algorithm to perform a sparsity-based reconstruction on the assumption that the underlying cosmic density field is represented by a sum of Navarro-Frenk-White halos. We generate realistic mock galaxy shape catalogues by considering the shear distortions from isolated halos for the configurations matched to Subaru Hyper Suprime-Cam Survey with its photometric redshift estimates. We show that the adaptive method significantly reduces line-of-sight smearing that is caused by the correlation between the lensing kernels at different redshifts. Lensing clusters with lower mass limits of 1014.0 h-1M, 1014.7 h-1M, 1015.0 h-1M can be detected with 1.5-σ confidence at the low (z<0.3), median (0.3≤ z< 0.6) and high (0.6≤ z< 0.85) redshifts, respectively, with an average false detection rate of 0.022 deg-2. The estimated redshifts of the detected clusters are systematically lower than the true values by z 0.03 for halos at z≤ 0.4, but the relative redshift bias is below 0.5\% for clusters at 0.4<z≤ 0.85. The standard deviation of the redshift estimation is 0.092. Our method enables direct three-dimensional cluster detection with accurate redshift estimates.