Shocked poststarbust galaxy survey. I. Candidate post-starbust galaxies with emission line ratios consistent with shocks
Date
2016-06
Authors
Alatalo, Katherine
Cales, Sabrina L.
Rich, Jeffrey A.
Appleton, Philip N.
Kewley, Lisa
Lacy, Mark
Lanz, Lauranne
Medling, Anne M.
Nyland, Kristina
Journal Title
Journal ISSN
Volume Title
Publisher
American Astronomical Society
Abstract
There are many mechanisms by which galaxies can transform from blue, star-forming spirals, to red, quiescent
early-type galaxies, but our current census of them does not form a complete picture. Recent observations of
nearby case studies have identified a population of galaxies that quench “quietly.” Traditional poststarburst
searches seem to catch galaxies only after they have quenched and transformed, and thus miss any objects with
additional ionization mechanisms exciting the remaining gas. The Shocked POststarburst Galaxy Survey (SPOGS)
aims to identify transforming galaxies, in which the nebular lines are excited via shocks instead of through star
formation processes. Utilizing the Oh-Sarzi-Schawinski-Yi (OSSY) measurements on the Sloan Digital Sky
Survey Data Release 7 catalog, we applied Balmer absorption and shock boundary criteria to identify 1067 SPOG
candidates (SPOGs*) within z = 0.2. SPOGs* represent 0.2% of the OSSY sample galaxies that exceed the
continuum signal-to-noise cut (and 0.7% of the emission line galaxy sample). SPOGs* colors suggest that they are
in an earlier phase of transition than OSSY galaxies that meet an “E+A” selection. SPOGs* have a 13% 1.4 GHz
detection rate from the Faint Images of the Radio Sky at Twenty Centimeters Survey, higher than most
other subsamples, and comparable only to low-ionization nuclear emission line region hosts, suggestive of
the presence of active galactic nuclei (AGNs). SPOGs* also have stronger Na I D absorption than predicted from
the stellar population, suggestive of cool gas being driven out in galactic winds. It appears that SPOGs* represent
an earlier phase in galaxy transformation than traditionally selected poststarburst galaxies, and that a
large proportion of SPOGs* also have properties consistent with disruption of their interstellar media, a key
component to galaxy transformation. It is likely that many of the known pathways to transformation undergo a
SPOG phase. Studying this sample of SPOGs* further, including their morphologies, AGN properties, and
environments, has the potential for us to build a more complete picture of the initial conditions that can lead to a
galaxy evolving.
Description
Keywords
galaxies, active, evolution, statistics
Citation
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Source
The Astrophysical Journal Supplement Series
Type
Journal article
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Access Statement
Open Access