Weak-Lensing Detection of Intercluster Filaments in Three Nearby Cluster Systems

TL;DR

This paper demonstrates the first robust weak-lensing detections of intercluster filaments in three nearby galaxy systems, revealing their properties and validating the detection method using simulations and null tests.

Contribution

It introduces a matched-filter technique for detecting dark matter filaments via weak lensing and applies it to real data, achieving the first robust detections of intercluster bridges.

Findings

Detected six intercluster filaments with >5σ significance.

Measured filament convergence and width consistent with simulations.

Validated detection method with mock catalogs and null tests.

Abstract

Direct detection of intercluster filaments is challenging due to their low surface density, resulting in a weak deflection field. We present weak-lensing detections of intercluster filaments using wide-field Dark Energy Camera (DECam) observations from the Local Volume Complete Cluster Survey (LoVoCCS). A matched-filter method was applied to identify filamentary structures in three nearby ($z < 0.1$) systems centered on Abell 401, Abell 2029, and Abell 3558. We discover two prominent filaments ($\geq 4\sigma$) in each system, with the strongest detections ($6.4\sigma - 7.3\sigma$) around Abell 401 and Abell 2029. In particular, we report the first robust weak-lensing detections $(>5 \sigma)$ of the intercluster bridges connecting the cluster pairs Abell 401/399, Abell 2029/2033, Abell 2029/SIG, and Abell 3558/3556. Adopting a filament convergence model motivated by numerical simulations, we infer the maximum convergence ($\kappa_0$) and characteristic width ($h_{\mathrm{c}}$) for all six filaments, yielding $\kappa_0 \sim 0.015 - 0.053$ and $h_{\mathrm{c}} \sim 0.11 - 0.45 \ \mathrm{Mpc}$. The performance of the matched-filter technique is validated using mock shear catalogs and further tested on a null field around Abell 2351. We also explore the potential of using the B-mode lensing signal of filaments to suppress cluster-induced shear contamination. These results demonstrate the feasibility of directly mapping dark matter filaments with current and future wide-field weak-lensing datasets.