Position-Dependent Correlation Function of Weak Lensing Convergence

Abstract

We provide a systematic study of the position-dependent correlation function in weak lensing convergence maps and its relation to the squeezed limit of the three-point correlation function (3PCF) using state-of-the-art numerical simulations. We relate the position-dependent correlation function to its harmonic counterpart, i.e., the position-dependent power spectrum or equivalently the integrated bispectrum. We use a recently proposed improved fitting function, BiHalofit, for the bispectrum to compute the theoretical predictions as a function of source redshifts. In addition to low redshift results (zs=1.0-2.0), we also provide results for maps inferred from lensing of the cosmic microwave background, i.e., zs=1100. We include a Euclid-type realistic survey mask and noise. In agreement with the recent studies on the position-dependent power spectrum, we find that the results from simulations are consistent with the theoretical expectations when appropriate corrections are included. Performing a rough estimate, we find that the (S/N) for the detection of the position-dependent correlation function from Euclid-type mask with fsky=0.35, can range between 6-12 depending on the value of the intrinsic ellipticity distribution parameter σε = 0.3-1.0. For reconstructed maps using an ideal CMB survey the (S/N) ≈ 1.8. We also found that a 10\% deviation in σ8 can be detected using IB for the optimistic case of σε=0.3 with a (S/N) ≈ 5. The (S/N) for such detection in case of M is lower.