Carbon and oxygen abundance gradients in NGC300 and M33 from optical recombination lines

TL;DR

This study measures detailed chemical abundance gradients in NGC 300 and M33 using optical recombination lines, revealing new insights into their chemical evolution and gradient behaviors.

Contribution

It provides the first C/H gradient for NGC 300 and refines the M33 gradient, using direct temperature measurements and recombination lines, advancing understanding of galactic chemical distributions.

Findings

C/H gradients are steeper than O/H, resulting in negative C/O gradients.

C/H gradient slopes correlate with galaxy luminosity (M_V).

Hii regions near R_25 show C/O ratios similar to dwarf galaxies.

Abstract

We present deep spectrophotometry of several Hii regions in the nearby low-mass spiral galaxies NGC 300 and M33. The data have been taken with UVES and OSIRIS spectrographs attached to the 8m VLT and 10.4m GTC telescopes, respectively. We have derived precise values of the physical conditions for each object making use of several emission line-intensity ratios. In particular, we have obtained direct determinations of the electron temperature in all the observed objects. We detect pure recombination lines (RLs) of Cii and Oii in several of the Hii regions, permitting to derive their C/H and C/O ratios. We have derived the radial abundance gradient of O for each galaxy making use of collisionally excited lines (CELs) and RLs, as well as the C and N gradients using RLs and CELs, respectively. We obtain the first determination of the C/H gradient of NGC 300 and improve its determination in the case of M33. In both galaxies, the C/H gradients are steeper that those of O/H, leading to negative C/O gradients. Comparing with similar results for other spiral galaxies, we find a strong correlation between the slope of the C/H gradient and M_V. We find that some Hii regions located close to the isophotal radius (R_25) of NGC 300 and M33 show C/O ratios more similar to those typical of dwarf galaxies than those of Hii regions in the discs of more massive spirals. This may be related to the absence of flattening of the gradients in the external parts of NGC 300 and M33. Finally, we find very similar N/H gradients in both galaxies and a fair correlation between the slope of the N/H gradient and M_V comparing with similar data for a sample of spiral galaxies.