Multiband photometric decomposition of nuclear stellar disks

TL;DR

This study uses HST imaging to analyze the photometric properties of nuclear stellar disks in three Virgo cluster galaxies, providing insights into their formation process.

Contribution

It presents a detailed photometric decomposition of nuclear stellar disks, constraining their formation history and ruling out inside-out formation scenarios.

Findings

Nuclear disks have consistent scale length, inclination, and orientation across multiple passbands.

No color gradients detected, indicating homogeneous star formation.

Results support a uniform, dissipational formation process for these disks.

Abstract

Small and bright stellar disks with scale lengths of few tens of parsec are known to reside in the center of galaxies. They are believed to have formed in a dissipational process as the end result of star formation in gas either accreted in a merging (or acquisition) event or piled up by the secular evolution of a nuclear bar. Only few of them have been studied in detail to date. Using archival Hubble Space Telescope (HST) imaging, we investigated the photometric parameters of the nuclear stellar disks hosted by three early-type galaxies in the Virgo cluster, NGC 4458, NGC4478, and NGC4570. We aimed at constraining the process of formation of their stars. The central surface brightness, scale length, inclination, and position angle of the nuclear disks were derived by adopting the photometric decomposition method introduced by Scorza & Bender and assuming the disks to be infinitesimally thin and exponential. The location, orientation, and size of the nuclear disks is the same in all the images obtained with the Wide Field Planetary Camera 2 and Advanced Camera for Survey and available in the HST Science Archive. The scale length, inclination, and position angle of each disk are constant within the errors in the observed U, B, V, and I passbands, independently of their values and of the properties of the host spheroid. We interpret the absence of color gradients in the stellar population of the nuclear disks as the signature that star formation homogeneously occurred all through their extension. A inside-out formation scenario is, instead, expected to produce color gradients and therefore is ruled out.