Differences between CO- and calcium triplet-derived velocity dispersions in spiral galaxies: evidence for central star formation?

TL;DR

This study compares stellar velocity dispersions derived from near-infrared CO band-heads and optical calcium triplet lines in spiral galaxies, revealing a consistent discrepancy likely linked to dust and young stellar populations.

Contribution

It provides the first detailed analysis of sigma discrepancies in spiral galaxies, showing that CO-based dispersions are systematically lower than optical measurements, and explores potential causes.

Findings

sigma_CO is on average 14.3% lower than sigma_CaT in spirals

a linear relation between sigma_opt and sigma_CO is established

discrepancy correlates with infrared luminosity, suggesting dust influence

Abstract

We examine the stellar velocity dispersions (sigma) of a sample of 48 galaxies, 35 of which are spirals, from the Palomar nearby galaxy survey. It is known that for ultra-luminous infrared galaxies (ULIRGs) and merger remnants thesigma derived from the near-infrared CO band-heads is smaller than that measured from optical lines, while no discrepancy between these measurements is found for early-type galaxies. No such studies are available for spiral galaxies - the subject of this paper. We used cross-dispersed spectroscopic data obtained with the Gemini Near-Infrared Spectrograph (GNIRS), with spectral coverage from 0.85 to 2.5um, to obtain sigma measurements from the 2.29 $\mu$m CO band-heads (sigma_{CO}), and the 0.85 um calcium triplet (sigma_{CaT}). For the spiral galaxies in the sample, we found that sigma_{CO} is smaller than sigma_{CaT}, with a mean fractional difference of 14.3%. The best fit to the data is given by sigma_{opt} = (46.0+/-18.1) + (0.85+/-0.12)sigma_{CO}. This "sigma discrepancy" may be related to the presence of warm dust, as suggested by a slight correlation between the discrepancy and the infrared luminosity. This is consistent with studies that have found no sigma-discrepancy in dust-poor early-type galaxies, and a much larger discrepancy in dusty merger remnants and ULIRGs. That sigma_{CO}$ is lower than sigma_{opt} may also indicate the presence of a dynamically cold stellar population component. This would agree with the spatial correspondence between low sigma_{CO} and young/intermediate-age stellar populations that has been observed in spatially-resolved spectroscopy of a handful of galaxies.