The Fundamental Plane of massive quiescent galaxies out to z~2

TL;DR

This study investigates the evolution of the Fundamental Plane of massive quiescent galaxies up to redshift 2, revealing its persistence and significant zero point evolution, with implications for galaxy formation history.

Contribution

It provides the first evidence for the existence of the Fundamental Plane at z~2 and quantifies its zero point evolution, incorporating color-based M/L corrections.

Findings

FP exists out to z~2 with increased scatter

Significant zero point evolution in M/L ratio from z~2 to z~0

Color correction reduces the apparent evolution, suggesting earlier formation redshift

Abstract

The Fundamental Plane (FP) of early-type galaxies, relating the effective radius, velocity dispersion, and surface brightness, has long been recognized as a unique tool for analyzing galaxy structure and evolution. With the discovery of distant quiescent galaxies and the introduction of high sensitivity near-infrared spectrographs, it is now possible to explore the FP out to z~2. In this Letter we study the evolution of the FP out to z~2 using kinematic measurements of massive quiescent galaxies ($M_{*}>10^{11} M_{\odot}$). We find preliminary evidence for the existence of an FP out to z~2. The scatter of the FP, however, increases from z~0 to z~2, even when taking into account the larger measurement uncertainties at higher redshifts. We find a strong evolution of the zero point from z~2 to z~0: $\Delta\log_{10}M/L_g\propto(-0.49\pm0.03)~z$. In order to assess whether our spectroscopic sample is representative of the early-type galaxy population at all redshifts, we compare their rest-frame g-z colors with those from a larger mass complete sample of quiescent galaxies. At z>1 we find that the spectroscopic sample is bluer. We use the color offsets to estimate a mass-to-light ratio (M/L) correction. The implied FP zero point evolution after correction is significantly smaller: $\Delta\log_{10}M/L_g\propto(-0.39\pm 0.02)~z$. This is consistent with an apparent formation redshift of $z_{\rm{form}}=6.62^{+3.19}_{-1.44}$ for the underlying population, ignoring the effects of progenitor bias. A more complete spectroscopic sample is required at z~2 to properly measure the M/L evolution from the FP evolution.