Stellar population gradients in the cores of nearby field E+A galaxies

TL;DR

This study uses integral field spectroscopy to detect stellar population gradients in the cores of nearby E+A galaxies, revealing evidence of recent mergers and central star formation in a low-redshift sample.

Contribution

First robust detection of Balmer line gradients in the centers of local E+A galaxies using integral field spectroscopy at low redshift.

Findings

Most galaxies show compact, centrally-concentrated Balmer absorption.

Evidence supports models of mergers funneling gas into galaxy cores.

Galaxies are likely in late merger stages with coalesced progenitors.

Abstract

We have selected a sample of local E+A galaxies from the Sloan Digital Sky Survey (SDSS) Data Release 7 for follow up integral field spectroscopy with the Wide Field Spectrograph (WiFeS) on the ANU 2.3-m telescope. The sample was selected using the Halpha line in place of the [OII]3727 line as the indicator of on-going star formation (or lack thereof). This allowed us to select a lower redshift sample of galaxies than available in the literature since the [OII]3727 falls off the blue end of the wavelength coverage in the SDSS for the very lowest redshift objects. This low redshift selection means that the galaxies have a large angular to physical scale which allows us to resolve the central ~1kpc region of the galaxies; the region where stellar population gradients are expected. Such observations have been difficult to make using other higher redshift samples because even at redshifts z~0.1 the angular to physical scale is similar to the resolution provided by ground based seeing. Our integral field spectroscopy has enabled us to make the first robust detections of Balmer line gradients in the centres of E+A galaxies. Six out of our sample of seven, and all the galaxies with regular morphologies, are observed to have compact and centrally-concentrated Balmer line absorption. This is evidence for compact young cores and stellar population gradients which are predicted from models of mergers and tidal interactions which funnel gas into the galaxy core. Given the generally isolated nature of our sample this argues for the galaxies being seen in the late stage of a merger where the progenitors have already coalesced.