The Atlas3D project - VII. A new look at the morphology of nearby galaxies: the kinematic morphology-density relation

TL;DR

This study revises galaxy morphology classification by analyzing the kinematic properties of early-type galaxies, revealing environmental influences on galaxy evolution and proposing a new morphology-density relation based on kinematics.

Contribution

It introduces a kinematic morphology-density relation for early-type galaxies, replacing traditional classifications, and highlights environmental effects on galaxy evolution.

Findings

Fast rotators are often barred lenticulars with disky isophotes.

Slow rotators are rounder, spheroidal, and rare in low-density environments.

A smooth log-linear relation exists between spiral fraction and local density.

Abstract

We look at the morphology of fast and slow rotator early-type galaxies. Edge-on fast rotators are lenticular galaxies. They appear like spiral galaxies with the gas and dust removed, and in some cases are flat ellipticals with disky isophotes. Fast rotators are often barred and span the same full range of bulge fractions as spiral galaxies. The slow rotators are rounder and are generally consistent with being genuine, namely spheroidal-like, elliptical galaxies. We propose a revision to the tuning-fork diagram by Hubble as it gives a misleading description of ETGs. We study for the first time the kinematic morphology-density T-Sigma relation using fast and slow rotators to replace lenticulars and ellipticals. We find that our relation is cleaner than using classic morphology. Slow rotators are nearly absent at the lowest density environments [f(SR)<2%] and generally constitute a small fraction [f(SR)~4%] of the total galaxy population in the environments explored by our survey, with the exception of the densest core of the Virgo cluster [f(SR)~20%]. We find a clean log-linear relation between the fraction f(Sp) of spiral galaxies and the local galaxy surface density. The existence of a smooth kinematic T-Sigma relation in the field excludes processes related to the cluster environment as main contributors to the apparent conversion of spirals into fast-rotators in low-density environments. It shows that the segregation is driven by local effects at the small-group scale. Only at the largest densities in the Virgo core does the f(Sp) relation break down and steepens sharply, while the fraction of slow-rotators starts to significantly increase. This suggests that a different mechanism is at work there. (Abridged)