Substructure in the cold front cluster Abell 3667

TL;DR

This study provides detailed evidence of substructure in Abell 3667, linking optical galaxy distributions with X-ray features, and highlights the importance of extensive optical data for understanding cluster mergers.

Contribution

The paper presents the largest spectroscopic dataset for Abell 3667, revealing complex substructure and merger activity through combined spatial and velocity analyses.

Findings

Significant substructure detected in galaxy distribution and velocities.

Cluster comprises two major components offset by ~500 km/s.

Cold front linked to ongoing cluster merger activity.

Abstract

We present evidence for the existence of significant substructure in the cold front cluster Abell 3667 based on multi-object spectroscopy taken with the 3.9m Anglo Australian Telescope. This paper is the second in a series analyzing the relationship between cold fronts observed in Chandra X-ray images and merger activity observed at optical wavelengths. We have obtained 910 galaxy redshifts in the field of Abell 3667 out to 3.5 Mpc, of which 550 are confirmed cluster members, more than doubling the number of spectroscopically confirmed members previously available and probing some 3 mag down the luminosity function. From this sample, we derive a cluster redshift of z=0.0553 +/-0.0002 and velocity dispersion of 1056 +/- 38 km/s and use a number of statistical tests to search for substructure. We find significant evidence for substructure in the spatial distribution of member galaxies and also in the localized velocity distributions and, in spite of this evidence, find the global velocity distribution does not deviate significantly from a Gaussian. Using combined spatial and velocity information, we find the cluster can be separated into two major structures, with roughly equal velocity dispersions, but offset in peculiar velocity from each other by ~500 km/s, and a number of minor substructures. We propose two scenarios which explain the radio and X-ray observations. Our data show the cold front is directly related to cluster merger activity, and also highlights the extent of optical data required to unambiguously detect the presence of substructure.