Chemical abundances in the polar disk of NGC4650A: implications for cold accretion scenario

TL;DR

This study investigates the chemical composition of NGC 4650A's polar disk to evaluate if cold gas accretion from cosmic filaments explains its formation, finding low metallicity and flat gradients consistent with this scenario.

Contribution

It provides observational evidence supporting cold accretion as a formation mechanism for polar disks, through detailed metallicity measurements and analysis.

Findings

Polar disk has low metallicity (Z=0.2 Zsun).

Metallicity gradient is flat along the disk.

Results support cold accretion scenario.

Abstract

The aim of the present study is to test whether the cold accretion of gas through a "cosmic filament" Macci\`o et al. 2006 is a possible formation scenario for the polar disk galaxy NGC 4650A. If polar disks form from cold accretion of gas, the abundances of the HII regions may be similar to those of very late-type spiral galaxies, regardless of the presence of a bright central stellar spheroid, with total luminosity of few 10^9 Lsun. We use deep long slit spectra obtained with the FORS2 spectrograph at the VLT in the optical and near-infrared wavelength ranges for the brightest HII regions in the disk polar disk of NGC 4650A. The strongest emission lines ([OII] Hbeta, [OIII], Halpha) were used to derived oxygen abundances, metallicities and the global star formation rates for the disk. The deep spectra available allowed us to measure the Oxygen abundances (12 + log (O/H)) using the "Empirical method" based on intensities of the strongest emission lines, and the "Direct method", based on the determination of the electron temperature from the detection of weak auroral lines, as the [OIII] at 4363 Angstrom. The Oxygen abundance measured for the polar disk is then compared with those measured for different galaxy types of similar total luminosities, and then compared against the predictions of different polar ring formation scenarios. The average metallicity values for the polar disk in NGC 4650A is Z=0.2 Zsun, and it is lower that the values measured for ordinary spirals of similar luminosity. Moreover the gradient of the metallicity is flat along the polar disk major axis, which implies none or negligible metal enrichment from the stars in the older central spheroid. The low metallicity value in the polar disk NGC 4650A and the flat metallicity gradient are both consistent with a later infall of metal-poor gas, as expected in the cold accretion processes.