Luke Leisman Calvin College. Photo Credit: SLOAN Digital Sky Survey. Great Lakes Cosmology Workshop June 15, 2010

Similar documents
Galaxy groups: X-ray scaling relations, cool cores and radio AGN

Contents. List of Participants

ROSAT Roentgen Satellite. Chandra X-ray Observatory

Unveiling the Structure of Galaxy Clusters with Combined ESO-VLT, WFI, and XMM-Newton Observations

The interplay between the brightest cluster galaxy and the intra-cluster medium via AGN feedback.

Star Formation in Brightest Cluster Galaxies in Cool Cores:

Clusters physics and evolution from new X- ray/sz samples

Hubble s Law and the Cosmic Distance Scale

The effect of large scale environment on galaxy properties

Clusters of Galaxies " High Energy Objects - most of the baryons are in a hot (kt~ k) gas." The x-ray luminosity is ergs/sec"

Direct empirical proof of dark matter?

The X-ray view of Planck SZ clusters

PLANCK SZ CLUSTERS. M. Douspis 1, 2

Part 2. Hot gas halos and SMBHs in optically faint ellipticals. Part 3. After Chandra?

Massive molecular gas flows and AGN feedback in galaxy clusters

New Results on the AGN Content of Galaxy Clusters

Cluster Thermodynamics: Entropy

arxiv: v1 [astro-ph.he] 29 May 2014

The Distribution of Stellar Mass in Galaxy Clusters since z=1

Clusters, lensing and CFHT reprocessing

The gas-galaxy-halo connection

Observational Evidence of AGN Feedback

Galaxy clusters. Dept. of Physics of Complex Systems April 6, 2018

arxiv:astro-ph/ v1 1 Nov 2006

The inside-out Growth of the Stellar Mass Distribution in Galaxy Clusters since z 1

Physical Conditions in the Gas

High redshift clusters and their evolution. M.Arnaud (CEA-Sap Saclay France)

Molecular gas & AGN feedback in brightest cluster galaxies

Active Galaxies & Quasars

LoCuSS: the connection between brightest cluster galaxy activity, gas cooling and dynamical disturbance of X-ray cluster cores

ASTRON 449: Stellar (Galactic) Dynamics. Fall 2014

Clusters of Galaxies Groups: Clusters poor rich Superclusters:

Driving hot and cold gas flows with AGN feedback in galaxy clusters Credit: ESO

AC Fabian, M. Cappi, J Sanders. Cosmic Feedback from AGN

Clusters of Galaxies Groups: Clusters poor rich Superclusters:

X-Ray and Radio Emissions of AWM and MKW Clusters. Michael Ramuta 1. Astronomy Department, University of Wisconsin-Madison

Trends in Intracluster Metallicity

X- ray surface brightness fluctuations and turbulence in galaxy clusters. Jeremy Sanders. Andy Fabian. Sanders & Fabian 2011, MNRAS, submitted

Publ. Astron. Obs. Belgrade No. 86 (2009), TURKISH NATIONAL OBSERVATORY (TUG) VIEW OF CLUSTERS OF GALAXIES

arxiv:astro-ph/ v1 6 Mar 2006

Multi-wavelength scaling relations (scaling relations 101)

Embedded Spiral Patterns in the massive galaxy cluster Abell 1835

AGN Feedback in the Hot Halo of NGC 4649

Energy Balance in Clusters of Galaxies. Patrick M. Motl & Jack O. Burns Center for Astrophysics and Space Astronomy University of Colorado at Boulder

Active Galaxies and Galactic Structure Lecture 22 April 18th

Distant Clusters of Galaxies in a Deep XMM-Newton Observation

Clusters and Groups of Galaxies

How special are brightest group and cluster galaxies?

Hot Gas Halos in Early-Type Galaxies

AGN Feedback: Are Radio AGN Powered by Accretion or Black Hole Spin?

Stellar populations in the cd galaxy NGC 3311

Galaxy Systems in the Optical and Infrared. Andrea Biviano INAF/Oss.Astr.Trieste

Age of the Universe Lab Session - Example report

Radio emission from galaxies in the Bootes Voids

MASSIVE BLACK HOLES AMY REINES IN NEARBY DWARF GALAXIES HUBBLE FELLOW NATIONAL OPTICAL ASTRONOMY OBSERVATROY

PDF hosted at the Radboud Repository of the Radboud University Nijmegen

WORKSHOP ULXs AND THEIR ENVIRONMENT June 13th 16th, 2016 Strasbourg, France

Large-Scale Structure

What HI tells us about Galaxies and Cosmology

ALMA Synergy with ATHENA

Cosmology The Road Map

Feeding the Beast. Chris Impey (University of Arizona)

arxiv:astro-ph/ v1 6 May 2004

Gasflows in Galaxy Clusters

The SLUGGS survey: revisiting the correlation between X-ray luminosity and total mass of massive early-type galaxies

Multi-wavelength Astronomy

Source plane reconstruction of the giant gravitational arc in Abell 2667: a condidate Wolf-Rayet galaxy at z 1

New Galaxy Groups from the RASS. Thomas Reiprich

Globular Cluster Systems in Giant Ellipticals

Homework 9 due Nov. 26 (after Thanksgiving)

arxiv:astro-ph/ v1 10 Nov 1999

What HI tells us about Galaxies and Cosmology

The peculiar velocity and temperature profile of galaxy clusters

THE SUNYAEV-ZELDOVICH EFFECT

Multiwavelength Analysis of CLASH Clusters

UV observations of the galaxy cluster Abell 1795 with the optical monitor on XMM-Newton

Fossil Galaxy Groups; Halo and all therein

Two Phase Formation of Massive Galaxies

LECTURE 1: Introduction to Galaxies. The Milky Way on a clear night

Radio emission in clusters of galaxies. An observational perspective

Gravitational Lensing of the Largest Scales

Modern Image Processing Techniques in Astronomical Sky Surveys

A Look Back: Galaxies at Cosmic Dawn Revealed in the First Year of the Hubble Frontier Fields Initiative

cluster scaling relations and mass definitions

D4.2. First release of on-line science-oriented tutorials

DARC - DYNAMICAL ANALYSIS OF RADIO CLUSTERS

A Supermassive Black Hole in the Dwarf Starburst Galaxy Henize Amy Reines Einstein Fellow National Radio Astronomy Observatory

Simulations Applied to the Bright SHARC XCLF: Results and Implications

Course of Galaxies course organizer: Goeran Ostlin ESSAY. X-ray physics of Galaxy Clusters

A Multi-wavelength View of the Archetypal CSS Radio Galaxy 3C303.1: Evidence for Shocks and Induced Star Formation

Chapter 19 Galaxies. Hubble Ultra Deep Field: Each dot is a galaxy of stars. More distant, further into the past. halo

X-ray and Sunyaev-Zel dovich Effect cluster scaling relations: numerical simulations vs. observations

Radio-optical outliers a case study with ICRF2 and SDSS

Intracluster light in individual moderate redshift (0.02 < z < 0.31) clusters

Clusters: Observations

Stellar-to-Halo Mass Relation in X-ray Groups at 0.5<z<1

Data Release 5. Sky coverage of imaging data in the DR5

Probing of the Interactions Between the Hot Plasmas and Galaxies in Clusters over a Cosmological Timescale

Discovery of eight lensing clusters of galaxies

Sources of scatter in cluster mass-observable relations

Transcription:

Luke Leisman Calvin College Photo Credit: SLOAN Digital Sky Survey Great Lakes Cosmology Workshop June 15, 2010

Acknowledgements Funding: Sid Jansma Calvin Summer Research Fellowship Co-workers: Deborah Haarsma, David Sebald Calvin College Megan Donahue, Mark Voit, Seth Bruch Michigan State University Hans Böhringer and Daniele Pierini Max-Planck Institute, Germany Judith Croston University of Southampton, United Kingdom Gabriel Pratt and Monique Arnaud University of Paris, France

Brightest Cluster Galaxies: Importance Most massive galaxies in the universe Central location in cluster Extended envelope (e.g. Vale & Ostriker 2008) Different properties from ellipticals of the same mass (von der Linden 2007)

BCGs unsolved mysteries Formation history (Rasmussen et al. 2010, Stott et al. 2010, others) Interplay with host cluster (e.g. Lin & Mohr 2004) Used as a standard candle (Postman and Lauer 1995) Yet, found in wide variety of cluster environments Cluster gas properties may give insight into these mysteries

Cluster Gas Gas in clusters emit X-rays via free-free emission Gas density is well determined by X-ray surface brightness In some clusters high density leads to significant energy loss which can turn on feedback mechanisms (McNamara & Nulsen 2007, many others) Our work is focusing on clusters with low core densities/ long cooling times

Data from the Representative XMM- Newton Cluster Structure Survey (REXCESS) (Bohringer et al. 2007) Sample of 33 clusters Selected based on X-ray luminosity Range of redshifts from 0.05 < z < 0.15 Data directly observed: Southern Observatory for Astrophysical Research (SOAR) and XMM- Newton Our Sample

Optical Reduction BCGs magnitudes are difficult to measure Crowded fields masks (Varella et al. 2009) Total magnitude confused by sky background and Intracluster light metric magnitudes Procedure: Mask light from non-bcg sources Fit the remaining light using elliptical isophotes Numerically integrate ellipses inside metric radius

Results from Haarsma et al. 2010 ApJ 713, 1037 Blue star - cool core clusters Green X - BCG far from cluster center 90% of BCGs in REXCESS within 0.035 R 500 Consistent with previous studies (Bildfell et al 2008, Rafferty et al. 2008, Sanderson et al. 2009, Hudson et al. 2009) Correlation of BCG mass with cluster mass: L BCG α M cl 0.18+/-0.07 Consistent with previous results (Schombert 1988, Whiley et al. 2007, Brough et al. 2008, etc.)

Results: Core Gas Density vs BCG Luminosity Unexpected correlation between core gas density and BCG metric luminosity Follows power law: n e α L 2.7+/-0.4 Possible Explanation: merger history Need follow up data to confirm trend

Our Samples Data from the Representative XMM- Newton Cluster Structure Survey (REXCESS) (Böhringer et al. 2007) Sample of 33 clusters Selected based on X-ray luminosity Range of redshifts from 0.05 < z < 0.15 Data directly observed: Southern Observatory for Astrophysical Research (SOAR) and XMM- Newton Data from the Archive of Chandra Cluster Entropy Profiles (ACCEPT) (Cavagnolo et al. 2009) Sample of 240 clusters, 98 with X-ray & optical Selected based on archival availability Range of redshifts from 0.005 < z < 0.3 Data was mined from archived data: Sloan Digital Sky Survey (SDSS) and Chandra

We are using images from SDSS, but not their catalog magnitudes. Why? Means of comparison Better deblending/masking SDSS does not provide a metric radius We have the flexibility to measure BCG magnitudes in many different ways

Hot off the Press ACCEPT REXCESS

Hot off the Press ACCEPT REXCESS line is the fit from REXCESS results

Hot off the Press ACCEPT REXCESS

Hot off the Press ACCEPT REXCESS

Photo Credit: SLOAN Digital Sky Survey Photo Credit: SLOAN Digital Sky Survey Abell 2124 Abell 773 BCG Identification In most cases BCG is obvious Considerations: Brightness Proximity to cluster center Profile/diffuseness of emission Color/red sequence Number of neighbors In up to 40% of clusters the BCG is not located at the dynamical center (Skibba et al. 2009)

Summary Haarsma et al. 2010 REXCESS sample of 33 clusters Confirmed weak cluster mass vs BCG mass correlation Found most BCGs (90%) located near cluster core Discovered trend between gas properties and BCG stellar properties Suggested a model to explain the trend via long term merger history Follow Up in Progress ACCEPT/SDSS sample of 98 clusters No clear trend in full sample Possible trend in sub-samples Investigating the issue of BCG identification

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback