Presentation is loading. Please wait.

Presentation is loading. Please wait.

Galaxy Growth: The role of environment Simone Weinmann (MPA Garching) Collaborators: Guinevere Kauffmann, Frank van den Bosch, Anna Pasquali, Dan McIntosh,

Published byKerry Mitchell Modified over 8 years ago

Similar presentations

Presentation on theme: "Galaxy Growth: The role of environment Simone Weinmann (MPA Garching) Collaborators: Guinevere Kauffmann, Frank van den Bosch, Anna Pasquali, Dan McIntosh,"— Presentation transcript:

1 Galaxy Growth: The role of environment Simone Weinmann (MPA Garching) Collaborators: Guinevere Kauffmann, Frank van den Bosch, Anna Pasquali, Dan McIntosh, Xiaohu Yang, Houjun Mo Sept 17th, Galaxies in Real Life & Simulations

2 Environment affects galaxy evolution Distinguish centrals and satellites: centrals are the most massive galaxy in their group. Many environmental processes have been proposed. Perhaps the most natural one is starvation (or strangulation): Infalling gas is mainly accreted by the central galaxy. Satellites galaxies (slowly) starve. This is the only environmental process currently included in semi-analytical models. Is this good enough? What about the morphology-density relation? What about stripping of ISM, harassement... ?

3 The SDSS DR4 group catalogue (Yang et al. 07) Iterative group finder (Yang et al. 2005) Group masses estimated using the summed stellar mass for each group. Method has been carefully tested using Mock Galaxy Redshift Surveys constructed with the Conditional Luminosity Function. Our sample: ~ 280,000 galaxies in ~ 50,000 groups.

4 Relation between morphology and environment revisited Satellites more concentrated than centrals @ fixed stellar mass. Environment quantified to first order by distinguishing satellite and central galaxies in the group catalogue. Morphological indicator: Concentration (=R90/R50)

5 Ellipticals are not produced by environmental processes acting on satellites Relation between morphology and environment revisited Satellites more concentrated than centrals @ fixed stellar mass. However: Fraction of galaxies with C>3 is the same! Environment quantified to first order by distinguishing satellite and central galaxies in the group catalogue. Morphological indicator: Concentration (=R90/R50) ~

6 The average surface brightness profiles of C<3 galaxies (with log(M)~10.9) show: Satellites are fainter, and more so towards out- skirts. Explains increased C. What is the origin of this difference? Average radial profiles of SDSS galaxies bright faint

7 Average radial profiles of SDSS galaxies T The average colour profile of the same galaxies show: Colours of satellite galaxies redder across the disk. Central bulge-dominated region is unchanged. blue red

8 Average radial profiles of SDSS galaxies T Average stellar mass profiles show: Mass distribution in satellites and centrals is very similar. No major rearrangement of mass distribution by environmental process -> evidence against harassement, tidal stripping, disk instabilities.

9 Average radial profiles of SDSS galaxies T Average stellar mass profiles show: Mass distribution in satellites and centrals is very similar. No major rearrangement of mass distribution by environmental process -> evidence against harassement, tidal stripping, disk instabilities. Process affecting star formation can explain environmental dependencies of galaxy concentration!

10 Ram-pressure stripping of ISM vs. starvation

11 Starvation: Affects fuel for future star formation. Star formation decreases slowly (~ 2 Gyr)

12 Ram-pressure stripping of ISM vs. starvation Ram pressure stripping of ISM: Affects fuel for current star formation. Leads to fast decline of SF in affected regions.

13 How fast does the star formation decline? We model colour profiles using Bruzual & Charlot 03 SPS and different SF histories. Slow (e-folding time 2.5 Gyr) decrease of SFR reproduces satellite profile well! Colour difference increases with radius due to stronger reaction in young parts of galaxy. T model: infall 9 Gyr ago infall 1 Gyr ago data: blue red

14 How fast does the star formation decline? Truncation only 1 Gyr ago still leads to colours which are much too red. Alternative option: Fast truncation of star formation T average sat average cen blue red model results for different infall times

15 How fast does the star formation decline? Truncation only 1 Gyr ago still leads to colours which are much too red. Alternative option: Fast truncation of star formation Environmental processes do not lead to fast star formation truncation. T average sat average cen blue red model results for different infall times

16 Summary T Ellipticals not produced by environmental effects – violent environmental processes not needed. Remaining concentration differences can be explained by slowly decreasing SF Starvation is dominant environmental process and is able to explain what remains of "morphology - density relation" But: Starvation is clearly over-efficient in most SAMs. (Adressed by Font et al. 2008, Guo et al. in prep) Semi-analytical models have included the key environmental process.

17

Download ppt "Galaxy Growth: The role of environment Simone Weinmann (MPA Garching) Collaborators: Guinevere Kauffmann, Frank van den Bosch, Anna Pasquali, Dan McIntosh,"

Similar presentations

Star formation histories and environment Bianca M. Poggianti INAF – Osservatorio Astronomico di Padova WE ARE ALL AFTER THE BIG PICTURE: 1)To what extent,

Star formation histories and environment Bianca M. Poggianti INAF – Osservatorio Astronomico di Padova WE ARE ALL AFTER THE BIG PICTURE: 1)To what extent,
A simple model to explain the high gas content of galaxy UGC 8802 Ruixiang Chang Shanghai Astronomical Observatory Collaborators: Jinliang Hou Shiyin Shen.

A simple model to explain the high gas content of galaxy UGC 8802 Ruixiang Chang Shanghai Astronomical Observatory Collaborators: Jinliang Hou Shiyin Shen.
Color-magnitude relations of disk galaxies: observations vs. model predictions Ruixiang Chang ( Shanghai Astronomical Observatory ) Collaborators: Jinliang.

Color-magnitude relations of disk galaxies: observations vs. model predictions Ruixiang Chang ( Shanghai Astronomical Observatory ) Collaborators: Jinliang.
18 July 2015 1 Monte Carlo Markov Chain Parameter Estimation in Semi-Analytic Models Bruno Henriques Peter Thomas Sussex Survey Science Centre.

18 July Monte Carlo Markov Chain Parameter Estimation in Semi-Analytic Models Bruno Henriques Peter Thomas Sussex Survey Science Centre.
The Role of Dissipation in Galaxy Mergers Sadegh Khochfar University of Oxford.

The Role of Dissipation in Galaxy Mergers Sadegh Khochfar University of Oxford.
Xiaohu Yang Shanghai Astronomical Observatory Partner group of MPA Collaborators: Yu Wang (SHAO), H.J. Mo (UMass), F.C. van den Bosch (MPIA), Neal Katz.

Xiaohu Yang Shanghai Astronomical Observatory Partner group of MPA Collaborators: Yu Wang (SHAO), H.J. Mo (UMass), F.C. van den Bosch (MPIA), Neal Katz.
Formation of Globular Clusters in  CDM Cosmology Oleg Gnedin (University of Michigan)

Formation of Globular Clusters in  CDM Cosmology Oleg Gnedin (University of Michigan)
1 Mechanisms of Galaxy Evolution Things that happen to galaxies… Galaxy merging Things that happen to galaxies… Galaxy merging.

1 Mechanisms of Galaxy Evolution Things that happen to galaxies… Galaxy merging Things that happen to galaxies… Galaxy merging.
Kevin Bundy, Caltech The Mass Assembly History of Field Galaxies: Detection of an Evolving Mass Limit for Star-Forming Galaxies Kevin Bundy R. S. Ellis,

Kevin Bundy, Caltech The Mass Assembly History of Field Galaxies: Detection of an Evolving Mass Limit for Star-Forming Galaxies Kevin Bundy R. S. Ellis,
Gabriella De Lucia, November 1,Tucson MPA The emergence of the red-sequence Gabriella De Lucia Max-Planck Institut für Astrophysik A Workshop on Massive.

Gabriella De Lucia, November 1,Tucson MPA The emergence of the red-sequence Gabriella De Lucia Max-Planck Institut für Astrophysik A Workshop on Massive.
Galaxy Groups in HICAT Jamie Stevens. Outline Introduction Group-finding in HICAT HIPASS group properties Star formation properties Summary.

Galaxy Groups in HICAT Jamie Stevens. Outline Introduction Group-finding in HICAT HIPASS group properties Star formation properties Summary.
RESULTS AND ANALYSIS Mass determination Kauffmann et al. determined masses using SDSS spectra (Hdelta & D4000) Comparison with our determination: Relative.

RESULTS AND ANALYSIS Mass determination Kauffmann et al. determined masses using SDSS spectra (Hdelta & D4000) Comparison with our determination: Relative.
Multivariate Properties of Galaxies at Low Redshift.

Multivariate Properties of Galaxies at Low Redshift.
Dark Matter and Galaxy Formation Section 4: Semi-Analytic Models of Galaxy Formation Joel R. Primack 2009, eprint arXiv:0909.2021 Presented by: Michael.

Dark Matter and Galaxy Formation Section 4: Semi-Analytic Models of Galaxy Formation Joel R. Primack 2009, eprint arXiv: Presented by: Michael.
The Evolution of Galaxy Morphologies in Clusters “ New Views of the Universe” KICP, U. Chicago, December 2005 Marc Postman & collaborators: Marc Postman.

The Evolution of Galaxy Morphologies in Clusters “ New Views of the Universe” KICP, U. Chicago, December 2005 Marc Postman & collaborators: Marc Postman.
Disentangling Luminosity, Morphology, Stellar Age, Star Formation, and Environment in Galaxy Evolution Daniel Christlein Andes Fellow Yale University.

Disentangling Luminosity, Morphology, Stellar Age, Star Formation, and Environment in Galaxy Evolution Daniel Christlein Andes Fellow Yale University.
“ Testing the predictive power of semi-analytic models using the Sloan Digital Sky Survey” Juan Esteban González Birmingham, 24/06/08 Collaborators: Cedric.

“ Testing the predictive power of semi-analytic models using the Sloan Digital Sky Survey” Juan Esteban González Birmingham, 24/06/08 Collaborators: Cedric.
Galaxy Clusters Perseus Cluster in X-rays. Why study clusters? Clusters are the largest virialized objects in the Universe. Cosmology: tail of density.

Galaxy Clusters Perseus Cluster in X-rays. Why study clusters? Clusters are the largest virialized objects in the Universe. Cosmology: tail of density.
Lens Galaxy Environments Neal Dalal (IAS), Casey R. Watson (Ohio State) astro-ph/0409483 1.Who cares? 2.What to do 3.Results 4.Problems! 5.The future.

Lens Galaxy Environments Neal Dalal (IAS), Casey R. Watson (Ohio State) astro-ph/ Who cares? 2.What to do 3.Results 4.Problems! 5.The future.
Evolution of Galaxy groups Michael Balogh Department of Physics University of Waterloo.

Evolution of Galaxy groups Michael Balogh Department of Physics University of Waterloo.

Similar presentations

Ads by Google