The 6dF Galaxy Survey: The Near-Infrared Fundamental Plane of Early-Type Galaxies

TL;DR

This study derives the near-infrared Fundamental Plane for approximately 10,000 early-type galaxies, analyzing its properties, scatter, and environmental dependencies to enhance understanding of galaxy structure and evolution.

Contribution

It presents the first large-scale near-infrared FP measurement for early-type galaxies, examining environmental and morphological effects on the FP and its residuals.

Findings

FP slope consistent across environments and morphologies

Intrinsic scatter in FP is about 23% in distance estimates

Field galaxies are on average 5% larger than cluster galaxies

Abstract

We determine the near-infrared Fundamental Plane (FP) for $\sim10^4$ early-type galaxies in the 6dF Galaxy Survey (6dFGS). We fit the distribution of central velocity dispersion, near-infrared surface brightness and half-light radius with a three-dimensional Gaussian model using a maximum likelihood method. For the 6dFGS $J$ band sample we find a FP with $R_{e}$\,$\propto$\,$\sigma_0^{1.52\pm0.03}I_{e}^{-0.89\pm0.01}$, similar to previous near-IR determinations and consistent with the $H$ and $K$ band Fundamental Planes once allowance is made for differences in mean colour. The overall scatter in $R_e$ about the FP is $\sigma_r$,=,29%, and is the quadrature sum of an 18% scatter due to observational errors and a 23% intrinsic scatter. Because of the distribution of galaxies in FP space, $\sigma_r$ is not the distance error, which we find to be $\sigma_d$,=,23%. Using group richness and local density as measures of environment, and morphologies based on visual classifications, we find that the FP slopes do not vary with environment or morphology. However, for fixed velocity dispersion and surface brightness, field galaxies are on average 5% larger than galaxies in higher-density environments, and the bulges of early-type spirals are on average 10% larger than ellipticals and lenticulars. The residuals about the FP show significant trends with environment, morphology and stellar population. The strongest trend is with age, and we speculate that age is the most important systematic source of offsets from the FP, and may drive the other trends through its correlations with environment, morphology and metallicity.