Enhancing Cosmological Constraints by Two-dimensional $β$-cosmic-web Weighted Angular Correlation Functions
Abstract
We investigate the potential of $\beta$-cosmic-web weighted angular correlation functions to improve the cosmological constraints. Using SDSS DR12 CMASS-NGC galaxies and simulated mock catalogs with $\Omega_m$ varying in the range of 0.25-0.40, we quantify the discriminative power of different statistics via $\Delta \chi^2$ measurements. Our results demonstrate significant improvements when incorporating weighted statistics. Especially, adding the $\bar{D}_{\rm nei}$-weighting statistics enhances $\Delta \chi^2$ by 39%-130%, while adding the $1/\bar{D}_{\rm nei}$-weighted statistics yields 229%-336% gains over solely using the traditional angular statistics. These findings align with 3D correlation function studies \cite{Yin+etal+2024}, confirming the superior performance of $\beta$-cosmic-web weighted statistics. The thin-redshift-slice approach makes our method particularly relevant for slitless surveys (such as Euclid, CSST) where redshift errors challenge traditional 3D analyses. This work also establishes the first theoretical framework for marked statistics in 2D angular clustering.