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Transcript 
RESOLVED ANALYSIS OF THE ISM
AND STAR FORMATION
PROPERTIES OF SPIRAL GALAXIES
IN DIFFERENT ENVIRONMENTS
Angus Mok
Supervisor: Christine Wilson
McMaster University
Molecular Gas in Galactic Environments - 2016
Environmental Effects
• Denser environments
dominated by quiescent
galaxies (Blanton & Moustakas
2009)
• HI-deficient galaxies rises
towards the centre of
clusters (Solanes+ 2001)
• Possible Mechanisms:
• Starvation (Larson+ 1980)
• Ram pressure stripping
(Gunn & Gott 1972)
HI in M81 Group of Galaxies (Yun+ 1994)
• Gravitational harassment
Molecular Gas in Galactic Environments - 2016
Environmental Effects
• Effects on molecular gas
content less clear
• Virgo spirals are not as
H2 deficient as would be
expected from their HI
deficiencies (Kenny & Young
1989)
• Recent results suggests
NGC 4522 in the Virgo Cluster (HST http://www.spacetelescope.org/images/heic0911b/)
some H2 deficiency in
Virgo spirals (Fumagalli+
2009, Boselli+ 2014)
Molecular Gas in Galactic Environments - 2016
Virgo Cluster
• Nearest cluster to us, at a distance of ~16.7 Mpc
• Rich with infalling spiral galaxies
Virgo Cluster (APOD - http://apod.nasa.gov/apod/ap110422.html)
Molecular Gas in Galactic Environments - 2016
Nearby Galaxies Legacy Survey (NGLS)
• Sample of 155 HI-flux
selected galaxies in the
nearby universe (Wilson+
2012)
• All: Hα, JCMT
• Some: VLA, Herschel,
Spitzer
NGC 4567 and 4568 (http://www.sdss.org/ )
Molecular Gas in Galactic Environments - 2016
CO(3-2) Observations
• Sample of 98 gas-rich
spiral galaxies from the
NGLS and follow-up
surveys
• Map the CO(3-2)
transition using HARP
on the JCMT
• 19 mK (TA*) out to at least
D25/2 at 20 km/s
• 14.5” angular resolution
NGC 4567 and 4568, with CO (3-2) contours overlaid
Molecular Gas in Galactic Environments - 2016
VLA HI Observations
• 30 galaxies
• D-array (~60”
resolution)
• Pilot VLA program in
2007 (AW701) - 9 spirals
• Follow-up program (15B111) - 5 spirals
• VLA Imaging of Virgo
in Atomic Gas (VIVA)
Survey (Chung+2009)
• 16 spirals
• High resolution
Molecular Gas in Galactic Environments - 2016
Integrated Galaxy Properties
• 44% of the spiral
galaxies are CO
detected
• Use technique of
survival analysis to
incorporate upper limits
• Virgo galaxies show
an enhancement in
their molecular gas
content
• Environment aiding in
conversion to H2
Cumulative distribution functions for the 3 environments
(Figure 1 from Mok+ 2016)
Molecular Gas in Galactic Environments - 2016
Integrated Galaxy Properties
• 44% of the spiral
galaxies are CO
detected
• Use technique of
survival analysis to
incorporate upper limits
• Virgo galaxies show
an enhancement in
their molecular gas
content
• Environment aiding in
conversion to H2
Cumulative distribution functions for the 3 environments
(Figure 1 from Mok+ 2016)
Molecular Gas in Galactic Environments - 2016
Gas Depletion Times
• Combine with Hα star
formation rate data
(Sánchez-Gallego+ 2012)
• Longer molecular gas
depletion times in the
Virgo sample
• Environmental effects
(heating process, pressure,
stabilization in disk)
• No differences found in the
HI gas depletion times
Cumulative distribution functions for the 3 environments
(Figure 2 from Mok+ 2016)
Molecular Gas in Galactic Environments - 2016
Radial Trends
• Create radial annuli
around the center of
each galaxy
• From the HI data,
disk size appears to
be smaller for Virgo
galaxies after
normalization by
R25
HI radial averages for the galaxies in our sample,
normalized by R25 and subdivided by environment
Molecular Gas in Galactic Environments - 2016
Radial Trends (CO)
• Applied the same
process to CO data,
including
normalization by R25
• No signs of a
truncation in the H2
disks of Virgo
galaxies
H2 radial averages for the galaxies in our sample,
normalized by R25 and subdivided by environment
Molecular Gas in Galactic Environments - 2016
Next Steps
• Combine H2 and HI
data
• Create ratio maps to
distinguish between
different scenarios
• Incorporate available Hα
SFR maps
• Determine resolved star
formation rates and gas
depletion times in radial
bins
• Pixel by pixel analysis (KS
laws, gas depletion times)
Hα map of NGC 4567 and NGC 4568 with CO(3-2)
contours overlaid
Molecular Gas in Galactic Environments - 2016
Conclusion
• Created a large sample
of gas-rich nearby spiral
galaxies in different
environments
• Enhancement in the
molecular gas content
and molecular gas
depletion times for Virgo
galaxies
• No signs of a truncation
in the CO disks for the
Virgo galaxies, compared
to their HI disks
HI moment map of NGC 4567 and NGC 4568 with CO
(3-2) contours overlaid
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