TY - JOUR
T1 - The ATLAS3D project - XIII. Mass and morphology of H I in early-type galaxies as a function of environment
AU - Serra, Paolo
AU - Oosterloo, Tom
AU - Morganti, Raffaella
AU - Alatalo, Katherine
AU - Blitz, Leo
AU - Bois, Maxime
AU - Bournaud, Frédéric
AU - Bureau, Martin
AU - Cappellari, Michele
AU - Crocker, Alison F.
AU - Davies, Roger L.
AU - Davis, Timothy A.
AU - de Zeeuw, P. T.
AU - Duc, Pierre-Alain
AU - Emsellem, Eric
AU - Khochfar, Sadegh
AU - Krajnović, Davor
AU - Kuntschner, Harald
AU - Lablanche, Pierre-Yves
AU - McDermid, Richard M.
AU - Naab, Thorsten
AU - Sarzi, Marc
AU - Scott, Nicholas
AU - Trager, Scott C.
AU - Weijmans, Anne-Marie
AU - Young, Lisa M.
PY - 2012/5/21
Y1 - 2012/5/21
N2 - We present the ATLAS3D H I survey of a volume-limited,
complete sample of 166 nearby early-type galaxies (ETGs) brighter than
MK=-21.5. The survey is mostly based on data taken with the
Westerbork Synthesis Radio Telescope, which enables us to detect H I
down to 5 × 106-5 × 107
M⊙ within the survey volume.
We detect ˜40 per cent of all ETGs outside the Virgo galaxy
cluster and ˜10 per cent of all ETGs inside it. This demonstrates
that it is common for non-cluster ETGs to host H I. The morphology of
the detected gas varies in a continuous way from regular, settled H I
discs and rings to unsettled gas distributions (including tidal or
accretion tails) and systems of clouds scattered around the galaxy. The
majority of the detections consist of H I discs or rings (1/4 of all
ETGs outside Virgo) so that if H I is detected in an ETG it is most
likely distributed on a settled configuration. These systems come in two
main types: small discs [? M⊙], which are confined within
the stellar body and share the same kinematics of the stars; and large
discs/rings [M(H I) up to 5 × 109 M⊙],
which extend to tens of kpc from the host galaxy and are in half of the
cases kinematically decoupled from the stars.
Neutral hydrogen seems to provide material for star formation in ETGs.
Galaxies containing H I within ˜1Re exhibit signatures
of on-going star formation in ˜70 per cent of the cases,
approximately five times more frequently than galaxies without central H
I. The interstellar medium (ISM) in the centre of these galaxies is
dominated by molecular gas, and in ETGs with a small gas disc the
conversion of H I into H2 is as efficient as in spirals.
The ETG H I mass function is characterized by M*˜ 2 ×
109 M⊙ and by a slope α˜-0.7.
Compared to spirals, ETGs host much less H I as a family. However, a
significant fraction of all ETGs are as H I-rich as spiral galaxies. The
main difference between ETGs and spirals is that the former lack the
high-column-density H I typical of the bright stellar disc of the
latter.
The ETG H I properties vary with environment density in a more
continuous way than suggested by the known Virgo versus non-Virgo
dichotomy. We find an envelope of decreasing M(H I) and M(H
I)/LK with increasing environment density. The gas-richest
galaxies live in the poorest environments (as found also with CO
observations), where the detection rate of star formation signatures is
higher. Galaxies in the centre of Virgo have the lowest H I content,
while galaxies at the outskirts of Virgo represent a transition region
and can contain significant amounts of H I, indicating that at least a
fraction of them has joined the cluster only recently after
pre-processing in groups. Finally, we find an H I morphology-density
relation such that at low environment density (measured on a local
scale) the detected H I is mostly distributed on large, regular discs
and rings, while more disturbed H I morphologies dominate environment
densities typical of rich groups. This confirms the importance of
processes occurring on a galaxy-group scale for the evolution of ETGs.
AB - We present the ATLAS3D H I survey of a volume-limited,
complete sample of 166 nearby early-type galaxies (ETGs) brighter than
MK=-21.5. The survey is mostly based on data taken with the
Westerbork Synthesis Radio Telescope, which enables us to detect H I
down to 5 × 106-5 × 107
M⊙ within the survey volume.
We detect ˜40 per cent of all ETGs outside the Virgo galaxy
cluster and ˜10 per cent of all ETGs inside it. This demonstrates
that it is common for non-cluster ETGs to host H I. The morphology of
the detected gas varies in a continuous way from regular, settled H I
discs and rings to unsettled gas distributions (including tidal or
accretion tails) and systems of clouds scattered around the galaxy. The
majority of the detections consist of H I discs or rings (1/4 of all
ETGs outside Virgo) so that if H I is detected in an ETG it is most
likely distributed on a settled configuration. These systems come in two
main types: small discs [? M⊙], which are confined within
the stellar body and share the same kinematics of the stars; and large
discs/rings [M(H I) up to 5 × 109 M⊙],
which extend to tens of kpc from the host galaxy and are in half of the
cases kinematically decoupled from the stars.
Neutral hydrogen seems to provide material for star formation in ETGs.
Galaxies containing H I within ˜1Re exhibit signatures
of on-going star formation in ˜70 per cent of the cases,
approximately five times more frequently than galaxies without central H
I. The interstellar medium (ISM) in the centre of these galaxies is
dominated by molecular gas, and in ETGs with a small gas disc the
conversion of H I into H2 is as efficient as in spirals.
The ETG H I mass function is characterized by M*˜ 2 ×
109 M⊙ and by a slope α˜-0.7.
Compared to spirals, ETGs host much less H I as a family. However, a
significant fraction of all ETGs are as H I-rich as spiral galaxies. The
main difference between ETGs and spirals is that the former lack the
high-column-density H I typical of the bright stellar disc of the
latter.
The ETG H I properties vary with environment density in a more
continuous way than suggested by the known Virgo versus non-Virgo
dichotomy. We find an envelope of decreasing M(H I) and M(H
I)/LK with increasing environment density. The gas-richest
galaxies live in the poorest environments (as found also with CO
observations), where the detection rate of star formation signatures is
higher. Galaxies in the centre of Virgo have the lowest H I content,
while galaxies at the outskirts of Virgo represent a transition region
and can contain significant amounts of H I, indicating that at least a
fraction of them has joined the cluster only recently after
pre-processing in groups. Finally, we find an H I morphology-density
relation such that at low environment density (measured on a local
scale) the detected H I is mostly distributed on large, regular discs
and rings, while more disturbed H I morphologies dominate environment
densities typical of rich groups. This confirms the importance of
processes occurring on a galaxy-group scale for the evolution of ETGs.
KW - galaxies: elliptical and lenticular
KW - cD
KW - galaxies: evolution
KW - galaxies: ISM
KW - radio lines: galaxies
UR - http://adsabs.harvard.edu/abs/2012MNRAS.422.1835S
U2 - 10.1111/j.1365-2966.2012.20219.x
DO - 10.1111/j.1365-2966.2012.20219.x
M3 - Article
SN - 0035-8711
VL - 422
SP - 1835
EP - 1862
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 3
ER -