Transcript Galaxies in low density environments Michael Balogh University of Durham Nature vs. Nurture: galaxy formation and environment Michael Balogh University of Durham.

Galaxies in low density
environments
Michael Balogh
University of Durham
Nature vs. Nurture: galaxy
formation and environment
Michael Balogh
University of Durham
Outline
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Review of cluster galaxy properties
Theoretical expectations
First clues: clusters at intermediate redshift
New results: tracing star formation in all
environments in the local Universe
• Future work
Cluster Galaxies: background
• Segregation of
luminosities,
morphologies, and
emission line fraction
well-known
• Early-types consistent
with passive evolution
since z>2
• Small fraction of
actively star-forming
galaxies
Nature or Nurture?
• Nature? Elliptical galaxies only form in
protoclusters at high redshift. Rest of
population is due to infall.
• or Nurture? Galaxy evolution proceeds along
a different path within dense environments.
Butcher-Oemler effect
• Concentrated clusters at
high redshift have more
blue galaxies than
concentrated clusters at
low redshift
Butcher & Oemler (1984)
Butcher-Oemler effect
• A lot of scatter
– appears to be mostly due
to correlation with
cluster richness
• still room to worry
about cluster selection?
Margoniner et al. (2001)
Butcher-Oemler effect
SDSS: Goto et al. (2003)
• Many of blue galaxies
turned out to have poststarburst spectra (Dressler &
Gunn 1992; Couch & Sharples 1987)
• Suggested nurture:
– ram-pressure stripping
(Gunn & Gott 1972)
– tidal effects (Byrd & Valtonen
1990)
– harassment? (Moore et al.
1999)
But: Field galaxy evolution
• But field population also
evolves strongly (Lilly et al.
1996)
• Post-starburst galaxies
equally abundant in the field
(Zabludoff et al. 1996; Goto et al.
2003)
• So: does BO effect really
point to cluster-specific
physics, or just the evolving
field and infall rate (Ellingson
et al. 2001)?
Steidel et al. (1999)
If it is “nurture”…
Groups
Clusters
• Could cosmic SFR
evolution be a
consequence of
environment?
• Only if star formation
rates are low in groups
and low-density
environments as well as
clusters
Galaxy formation theory
Cole et al. (2000), Kauffmann et al.
(1999); Somerville et al. (1999) and
many others
Galaxy formation cartoon
Feedback
Radiative
cooling
Radiative
cooling
Feedback
Theory
1. Typical galaxy forms
stars at decaying rate
Rocha-Pinto et al. (2000)
Theory
z=5
1. Typical galaxy forms
stars at exponentially
decaying rate
2. Galaxies in dense
regions form earlier
z=0
Benson et al. (2002)
Theory
Feedback
Radiative
cooling
Radiative
cooling
Feedback
1. Typical galaxy forms
stars at exponentially
decaying rate
2. Galaxies in dense
regions form earlier
3. “Strangulation”:
Galaxies in dense
environments lose hot
halo
Larson et al. (1980)
Theory: predictions
• no ram-pressure stripping, harrassment
included, yet achieve reasonable match to
observed clusters (Diaferio et al. 2001; Okamoto et al. 2003)
• isolated galaxies should be at centre of
cooling flow, hence forming stars
• Galaxies in clusters should be forming stars
at a lower rate than those in the field
Observations: z~0.3
CNOC clusters (with Morris, Carlberg, Yee,
Ellingson, Schade)
AAT spectroscopy (with Couch, Bower)
Observations: z~0.3
Morph-density relation
Field
CNOC clusters
• Average SFR varies
gradually with radius
• low average SFR even
beyond virial radius
• Gradient much steeper
than expected from
morphology-density
relation
Balogh et al. (1998)
Observations: z~0.3
• Strangulation model:
– infall rate + assumed
decay rate of star
formation => radial
gradient in SFR
• Radial gradients in
CNOC clusters suggest
t ~2 Gyr
Balogh, Navarro & Morris (2000)
Nod & Shuffle: LDSS++
band-limiting filter +
microslit = ~800
galaxies per 7’ field
observed 4 clusters
at z~0.3
Ha in Rich Clusters at
z~0.3
(Field)
• Number of emission
lines galaxies is low in
all clusters
• However, shape of
luminosity function
similar to field:
– consistent with shift in
normalisation; not in
Ha luminosity
Couch et al. (2001)
Balogh et al. (2002)
Observations: z~0
2dFGRS (with Bower, Lewis, Eke, Couch et al.)
SDSS (with Nichol, Miller, Gomez et al.)
Observations: z~0
• Analysis of 2dFGRS
– Ha equivalent widths,
within 20 Mpc of known
clusters
– dependence of mean
SFR on local density
– “critical density”?
Lewis, Balogh et al. (2002)
Observations: z~0
R > 2 R200
• Analysis of 2dFGRS
– Ha equivalent widths,
within 20 Mpc of known
clusters
– dependence of mean
SFR on local density
– “critical density”?
– independent of distance
to cluster
Lewis, Balogh et al. (2002)
Observations: z~0
Star Formation Rate (Mo/yr)
• Analysis of SDSS
Field 75th percentile
75th percentile
– same trend observed in
SFR from Ha fluxes
– same value of “critical
density”
Field median
Median
Distance from Cluster Centre (R/Rvirial)
Gomez et al. (2003)
New results: combining the
SDSS and 2dFGRS
• Combined sample of 24,968 galaxies at
0.05<z<0.1 (Balogh, Eke et al. MNRAS submitted)
• Volume limited: Mr<-20.6 (SDSS); Mb<-19.5
• 3 measures of environment:
– “traditional” projected distance to 5th nearest
neighbour
– 3-dimensional density on 1 and 5 Mpc scales
– velocity dispersion of embedding cluster or
group
Bimodality
• SDSS colours show two
distinct populations
• Red population may be
the result of major
mergers at high redshift,
followed by passive
evolution
(u-r)0
Baldry et al. (2003)
Bimodality
• Same is seen in Ha
distribution: SFR is
not continuous
• galaxies do not have
arbitrarily low SFR
• So mean/median do
not necessarily trace a
change in SFR
The star-forming population
• Amongst the starforming population,
there is no trend in
mean SFR with
density!
• Same is seen in z~0.5
cluster Ha luminosity
functions
• Rules out slow-decay
models
Correlation with density
• The fraction of
star-forming
galaxies varies
strongly with
density
2dFGRS
• Correlation at all
densities; still a
flattening near the
critical value
Isolated Galaxies
All galaxies
Bright galaxies
• Selection of isolated
galaxies:
– non-group members,
with low densities on
1 and 5.5 Mpc scales
• ~30% of isolated
galaxies show
negligible SF
– challenge for models?
– environment must not
be only driver of
evolution.
Isolated Galaxies
• Fraction of SF galaxies in
lowest density
environments is not much
larger than the average
Average value
in full sample
– So strong evolution in
global average cannot be
due only to a change in
densities
Large scale structure
2dFGRS
200<s<400 km/s
s>500 km/s
• Some dependence
on cluster velocity
dispersion?
• More obvious in
2dF catalogue than
in SDSS
Large scale structure
r5.5 (Mpc-3)
0.050
0.010
0.005
• Emission-line
fraction appears to
depend on 1 Mpc
scales and on 5.5
Mpc scales.
Increasing fraction of Ha emitters
Nature vs. Nurture
• Nurture: clusters
directly affect SFR?
z~0.3
z~0.1
– rule out long-timescale
processes
(strangulation)
– trends at low densities
and large scales rule
out ram-pressure
stripping as dominant
effect
Nature vs. Nurture
Blue galaxies only: (g-r)<0.7
• Nurture: clusters
directly affect SFR?
– short timescale?
• few (<0.1 %) E+As
• normal SFR for colour
• however, these don’t
provide strong
constraints: it is possible
to generate entire nonSF population in this
way
Nature vs. Nurture
Passive spirals in SDSS
• Nurture: clusters directly
affect SFR?
– short timescale?
• morphology is longer lived
• maybe passive spirals are
more common in clusters
(Goto et al. 2003; also
Poggianti et al. 1999;
Balogh et al. 2002;
McIntosh et al. 2002)
Goto et al. (2003)
Nature vs. Nurture
• Nature:
1. Dense regions just form a little earlier?
• would expect to see lower SFR among active population in
high-z clusters: not observed
2. Early-type population formed at high redshift?
• would have to be a substantial fraction of today’s cluster
population: so why does the fraction of SF galaxies evolve?
(or does it?)
Most likely scenario (for
bright galaxies)?
• Probably several effects: brightest ellipticals
likely result of initial conditions
• Galaxy-galaxy interactions:
–
–
–
–
–
more common in dense regions
change SFR on short timescale
effective in small groups
evolve strongly with redshift
only environment known to effectively transform
SFR of a galaxy (e.g. Lambas et al. 2002)
Future Work
Groups at z~0.5 (Dave Wilman, R. Bower,
J. Mulchaey, A. Oemler, R. Carlberg et al.)
Groups at z~0.5
• Based on the CNOC2 redshift survey. Group selection and inital look at
properties described in Carlberg et al. (2001)
• Follow-up observations with
Magellan to gain higher
completeness and depth
• HST data for all groups
• Also infrared data from WHT
The Future: Groups at z~0.5
25
20
15
10
5
0
Mean EW [OII] (Å)
30
• Deep Magellan
spectroscopy and
HST imaging of
~30 groups at
z~0.5
• trace SFR with
[OII]
0
0.3
0.6
0.9
1.2
1.5
Distance from centre ( Mpc)
Wilman et al. in prep
Groups at z~0.5
• Preliminary results suggest SFR
distribution in z~0.5 groups is
different from that in clusters:
enhanced SFR due to
interactions?
Conclusions
• Distribution of star formation rates is
bimodal, not continuous (unlike
morphology?)
• SFR distribution among active population is
independent of environment
• Fraction of SF galaxies depends on local and
large-scale densities (?)
• Galaxy-galaxy interactions are the most likely
cause of observed segregation
True/observed emission line fraction
Projection Effects?
projected population
at field density
projected population 10
times more dense than
field
• Is star-forming
population all
projected??
• No: at high density,
contrast is high, and
area is small
– at low density, trend is
weak, so signal not
diluted by projection
Balogh et al. (2003)
Theory: SF in clusters and
field
Star formation
rate
• Age effect only?
Time
Theory: SF in clusters and
field
cluster
• Age effect only?
Star formation
rate
– Then SFR in clusters
should be lower at any
epoch
Time
Theory: SF in clusters and
field
• Strangulation?
cluster
Star formation
rate
– SF decays more quickly
in clusters, so should
still be lower
Time
Theory: SF in clusters and
field
• Truncation?
cluster
Star formation
rate
– Then star-forming
galaxies should all look
the same
Time
Abell 2390 (z~0.23)
3.6 arcmin
R image from
CNOC survey
(Yee et al. 1996)
Ha in Abell 2390
Balogh & Morris 2000
3.6 arcmin
The Future: Environment at
z~1.5
• Proposed VLT (FORS2)
observations of radio-loud
quasar/galaxy environments
at z=1.5
• Use narrow-band
filters+grism to obtain ~100
[OII] emitters per 7’ field
(even in absence of a cluster)
z=1.44