We report on a sample of 51 nearby, star-forming galaxies observed with the
Cosmic Origin Spectrograph on the Hubble Space Telescope. We calculate Si II
kinematics and densities arising from warm gas entrained in galactic outflows.
We use multi-wavelength ancillary data to estimate stellar masses (M$_\ast$),
star-formation rates (SFR), and morphologies. We derive significant
correlations between outflow velocity and SFR$^0.1$, M$_\ast^0.1$
and v$_circ^1/2$. Some mergers drive outflows faster than these
relations prescribe, launching the outflow faster than the escape velocity.
Calculations of the mass outflow rate reveal strong scaling with SFR$^\sim
1/2$ and M$_\ast^1/2$. Additionally, mass-loading efficiency factors
(mass outflow rate divided by SFR) scale approximately as M$_\ast^-1/2$. Both
the outflow velocity and mass-loading scaling suggest that these outflows are
powered by supernovae, with only 0.7% of the total supernovae energy converted
into the kinetic energy of the warm outflow. Galaxies lose some gas if
log(M$_\ast$/M$_ødot$) < $9.5$, while more massive galaxies retain all of
their gas, unless they undergo a merger. This threshold for gas loss can
explain the observed shape of the mass-metallicity relation.
Description
[1412.2139] Scaling Relations Between Warm Galactic Outflows and Their Host Galaxies
%0 Generic
%1 chisholm2014scaling
%A Chisholm, John
%A Tremonti, Christina A.
%A Leitherer, Claus
%A Chen, Yanmei
%A Wofford, Aida
%A Lundgren, Britt
%D 2014
%K galactic nearby outflows relations warm
%T Scaling Relations Between Warm Galactic Outflows and Their Host Galaxies
%U http://arxiv.org/abs/1412.2139
%X We report on a sample of 51 nearby, star-forming galaxies observed with the
Cosmic Origin Spectrograph on the Hubble Space Telescope. We calculate Si II
kinematics and densities arising from warm gas entrained in galactic outflows.
We use multi-wavelength ancillary data to estimate stellar masses (M$_\ast$),
star-formation rates (SFR), and morphologies. We derive significant
correlations between outflow velocity and SFR$^0.1$, M$_\ast^0.1$
and v$_circ^1/2$. Some mergers drive outflows faster than these
relations prescribe, launching the outflow faster than the escape velocity.
Calculations of the mass outflow rate reveal strong scaling with SFR$^\sim
1/2$ and M$_\ast^1/2$. Additionally, mass-loading efficiency factors
(mass outflow rate divided by SFR) scale approximately as M$_\ast^-1/2$. Both
the outflow velocity and mass-loading scaling suggest that these outflows are
powered by supernovae, with only 0.7% of the total supernovae energy converted
into the kinetic energy of the warm outflow. Galaxies lose some gas if
log(M$_\ast$/M$_ødot$) < $9.5$, while more massive galaxies retain all of
their gas, unless they undergo a merger. This threshold for gas loss can
explain the observed shape of the mass-metallicity relation.
@misc{chisholm2014scaling,
abstract = {We report on a sample of 51 nearby, star-forming galaxies observed with the
Cosmic Origin Spectrograph on the Hubble Space Telescope. We calculate Si II
kinematics and densities arising from warm gas entrained in galactic outflows.
We use multi-wavelength ancillary data to estimate stellar masses (M$_\ast$),
star-formation rates (SFR), and morphologies. We derive significant
correlations between outflow velocity and SFR$^{\sim 0.1}$, M$_\ast^{\sim 0.1}$
and v$_\text{circ}^{\sim 1/2}$. Some mergers drive outflows faster than these
relations prescribe, launching the outflow faster than the escape velocity.
Calculations of the mass outflow rate reveal strong scaling with SFR$^{\sim
1/2}$ and M$_\ast^{\sim 1/2}$. Additionally, mass-loading efficiency factors
(mass outflow rate divided by SFR) scale approximately as M$_\ast^{-1/2}$. Both
the outflow velocity and mass-loading scaling suggest that these outflows are
powered by supernovae, with only 0.7% of the total supernovae energy converted
into the kinetic energy of the warm outflow. Galaxies lose some gas if
log(M$_\ast$/M$_\odot$) < $9.5$, while more massive galaxies retain all of
their gas, unless they undergo a merger. This threshold for gas loss can
explain the observed shape of the mass-metallicity relation.},
added-at = {2014-12-09T10:35:29.000+0100},
author = {Chisholm, John and Tremonti, Christina A. and Leitherer, Claus and Chen, Yanmei and Wofford, Aida and Lundgren, Britt},
biburl = {https://www.bibsonomy.org/bibtex/2f36d6c63f447fe315519e79aecff1a30/miki},
description = {[1412.2139] Scaling Relations Between Warm Galactic Outflows and Their Host Galaxies},
interhash = {b62a2baa5091e376b5ad44937539ea21},
intrahash = {f36d6c63f447fe315519e79aecff1a30},
keywords = {galactic nearby outflows relations warm},
note = {cite arxiv:1412.2139Comment: 28 pages, 15 figures, submitted to ApJ},
timestamp = {2014-12-09T10:35:29.000+0100},
title = {Scaling Relations Between Warm Galactic Outflows and Their Host Galaxies},
url = {http://arxiv.org/abs/1412.2139},
year = 2014
}