Integral field spectroscopy of a sample of nearby galaxies: II. Properties of the H ii regions

TL;DR

This study analyzes the spectroscopic properties of approximately 2600 H ii regions across 38 nearby galaxies using integral field spectroscopy, revealing universal patterns in metallicity and star formation gradients.

Contribution

Introduces an automatic detection and spectral extraction method for H ii regions, enabling detailed analysis of their properties and radial distributions across diverse galaxy types.

Findings

Oxygen abundance gradients are negative, indicating decreasing metallicity with radius.

Hα equivalent width shows positive gradients, suggesting increasing star formation activity outward.

Gradients are statistically consistent across different galaxy morphologies.

Abstract

In this work we analyze the spectroscopic properties of a large number of H ii regions, \sim2600, located in 38 galaxies. The sample of galaxies has been assembled from the face-on spirals in the PINGS survey and a sample described in M\'armol-Queralt\'o (2011, henceforth Paper I). All the galaxies were observed using Integral Field Spectroscopy with a similar setup, covering their optical extension up to \sim2.4 effective radii within a wavelength range from \sim3700 to \sim6900{\AA}. We develop a new automatic procedure to detect H ii regions, based on the contrast of the H{\alpha} intensity maps. Once detected, the procedure provides us with the integrated spectra of each individual segmented region. A well-tested automatic decoupling procedure has been applied to remove the underlying stellar population, deriving the main proper- ties of the strongest emission lines in the considered wavelength range (covering from [O ii] {\lambda}3727 to [S ii] {\lambda}6731). A final catalogue of the spectroscopic properties of these regions has been created for each galaxy. In the current study we focused on the understanding of the average properties of the H ii regions and their radial distributions. We find that the gas-phase oxygen abundance and the H{\alpha} equivalent width present negative and positive gradient, respectively. The distribution of slopes is statistically compatible with a random Gaussian distribution around the mean value, if the radial distances are measured in units of the respective effective radius. No difference in the slope is found for galaxies of different morphologies: barred/non-barred, grand-design/flocculent. Therefore, the effective radius is a universal scale length for gradients in the evolution of galaxies. Other properties have a larger variance across each object.