+160 -120 BX663 (2.4) -170 170 MD 41 (2.2) +240 -160 K20-9 (2.0) +380 -80 K20-7 (2.2) -100 80 K20-8 (2.2) 70 -70 D3a 4751 (2.27) SA12 6339 (2.3) -50 30.

Slides:

Advertisements

Similar presentations

Astronomical Solutions to Galactic Dark Matter Will Sutherland Institute of Astronomy, Cambridge.

Advertisements

The main growth modes of disks, bulges, and central black holes: Mergers - Violent Instabilities - Secular Evolution Frédéric Bournaud - CEA Saclay with.

Daniel Ceverino (HU) Potsdam, 2009 Avishai Dekel (HU), Reem Sari(HU), Tobias Goerdt(HU), Anatoly Klypin (NMSU) High-Redshift Clumpy Disks & Bulges in Cosmological.

The Thick Disks of Spiral Galaxies as Relics from Gas-Rich, Turbulent, Clumpy Disks at High Redshifts Frédéric Bournaud, Bruce G. Elmegreen, and Marie.

GALAXIES IN DIFFERENT ENVIRONMENTS: VOIDS TO CLUSTERS:  Simulations will require to model full physics:  Cooling, heating, star formation feedbacks…

Formation of Globular Clusters in  CDM Cosmology Oleg Gnedin (University of Michigan)

Alyson Brooks Fairchild Postdoctoral Fellow in Theoretical Astrophysics Caltech In collaboration with the University of Washington’s N-body Shop ™ makers.

1 Mechanisms of Galaxy Evolution Things that happen to galaxies… Galaxy merging Things that happen to galaxies… Galaxy merging.

AGN in hierarchical galaxy formation models Nikos Fanidakis and C.M. Baugh, R.G. Bower, S. Cole, C. Done, C. S. Frenk Accretion and ejection in AGN, Como,

Mathieu PUECH GEPI Observatoire de Paris Rebuilding discs with gas-rich major merger ESO 3D2014 – March 2014, R. Delgado, M. Rodrigues, S. Fouquet + J.L.

LOGO The Chemical and Color Evolution of M Reporter: Jun Yin (Shao) Supervisor: Jinliang Hou (Shao)

Dark Halos of Fossil Groups and Clusters Observations and Simulations Ali Dariush, Trevor Ponman Graham Smith University of Birmingham, UK Frazer Pearce.

HST ACSCO on ACS in EGS at z=1.12 Molecular Gas in Star Forming Galaxies at z=1-3 Linda Tacconi, MPE Garching & Santa Cruz Galaxy Evolution Workshop.

How Galaxies Assemble Romeel Davé, Univ. of Arizona With: Dušan Kereš & Neal Katz (U.Mass), and David Weinberg (Ohio State)

Merger Histories of LCDM Galaxies: Disk Survivability and the Deposition of Cold Gas via Mergers Kyle Stewart AAS Dissertation Talk 213 th AAS Meeting.

Bi-modality and Do w n s i z i n g Avishai Dekel HU Jerusalem Bernard ’ s Cosmic Stories, Valencia, June 2006 Origin of E vs S Galaxies.

AGN in hierarchical galaxy formation models Nikos Fanidakis and C.M. Baugh, R.G. Bower, S. Cole, C. Done, C. S. Frenk Physics of Galactic Nuclei, Ringberg.

THE STRUCTURE OF COLD DARK MATTER HALOS J. Navarro, C. Frenk, S. White 2097 citations to NFW paper to date.

The Properties of LBGs at z>5 Matt Lehnert (MPE) Malcolm Bremer (Bristol) Aprajita Verma (MPE) Natascha Förster Schreiber (MPE) and Laura Douglas (Bristol)

Merger Histories of LCDM Galaxies: Disk Survivability and the Deposition of Cold Gas via Mergers Kyle Stewart Ohio State CCAPP Seminar Kyle Stewart.

Galaxy Formation Models Cold Dark Matter is the dominant component of galaxies and is key to their formation and evolution. CDM models have been wonderful.

A.Kravtsov (U.Chicago) D. Ceverino (NMSU) O. Valenzuela (U.Washington) G. Rhee (UNLV) F. Governato, T.Quinn, G.Stinson (U.Washington) J.Wadsley (McMaster,

Evolution in Lyman-alpha Emitters and Lyman-break Galaxies Masao Mori Theoretical Astrophysics division, Center for Computational Sciences, University.

Effects of baryons on the structure of massive galaxies and clusters Oleg Gnedin University of Michigan Collisionless N-body simulations predict a nearly.

130 cMpc ~ 1 o z~ = 7.3 Lidz et al ‘Inverse’ views of evolution of large scale structure during reionization Neutral intergalactic medium via HI.

A NEAR-INFRARED MULTIPLE-OBJECT INTEGRAL-FIELD SPECTROMETER FOR THE VLT The Science Case Matt Lehnert, MPE.

Star Formation at High Redshift: Observational Progress and Theoretical Perspectives Romeel Davé movie by B. Oppenheimer.

The Main Mode of Galaxy/Star Formation? Avishai Dekel, HU Jerusalem Leiden, September 2008 HU Flow Team Birnboim, Freundlich, Goerdt, Neistein, Zinger.

SMA [CII] 158um 334GHz, 20hrs BRI z=4.7 HyLIRG (10 13 L o ) pair: Quasar host Obscured SMG SFR ~ 10 3 ; M H2 ~ Iono ea 2007 Salome ea

1 Lessons from cosmic history Star formation laws and their role in galaxy evolution R. Feldmann UC Berkeley see Feldmann 2013, arXiv:

Cosmological Galaxy Formation

The co-evolution of massive ellipticals & their black holes Thorsten Naab University Observatory, Munich 8 th Sino-German Workshop on Galaxy Formation.

Linking Galaxies’ Gas Content to their Metallicity Gradients Sean Moran Johns Hopkins University & The GASS Team.

The coordinated growth of stars, haloes and large-scale structure since z=1 Michael Balogh Department of Physics and Astronomy University of Waterloo.

Most star and BH formation is happening in secular evolving disks E. Daddi (CEA Saclay) Mark Sargent(CEA), Mathieu Bethermin(CEA), Giulia Rodighiero(INAF),

Virial shocks in galaxy and cluster halos

Ben Moore, Institute for Theoretical Physics, University of Zurich +Oscar Agertz, Roman Teyssier+ Galaxy formation: is the end in sight? Obergurgl, December.

Modeling the dependence of galaxy clustering on stellar mass and SEDs Lan Wang Collaborators: Guinevere Kauffmann (MPA) Cheng Li (MPA/SHAO, USTC) Gabriella.

Lecture 29: From Smooth to Lumpy Astronomy 1143 – Spring 2014.

MNRAS, submitted. Galaxy evolution Evolution in global properties reasonably well established What drives this evolution? How does it depend on environment?

How do galaxies accrete their mass? Quiescent and star - forming massive galaxies at high z Paola Santini Roman Young Researchers Meeting 2009 July 21.

The dynamics of the gas regulator model and the implied cosmic sSFR-history Yingjie Peng Cambridge Roberto Maiolino, Simon J. Lilly, Alvio Renzini.

School/Workshop on parallel computing in astrophysics: April, 2010, Santiago, Chile.

野口正史（東北大学）.  Numerical simulation Disk galaxy evolution driven by massive clumps  Analytical model building Hubble sequence.

Q1: Quenching and the cessation of star-formation 1 1.The "Q" word and its meaning a.Is quenching a good word to describe the end of star-formation in.

Galaxy groups Driving galaxy evolution since z=1 Michael Balogh Department of Physics and Astronomy University of Waterloo.

Gas Accretion and Secular Processes 1  How much mass assembled in mergers?  How much through gas accretion and secular evolution? Keres et al 2005, Dekel.

What determines the gas content of galaxies?. Galaxy formation - a reminder of the puzzle The fraction of baryons that are “cold” (stars+cold gas) is.

Semi-analytical model of galaxy formation Xi Kang Purple Mountain Observatory, CAS.

Present-Day Descendants of z=3.1 Ly  Emitting (LAE) Galaxies in the Millennium-II Halo Merger Trees Jean P. Walker Soler – Rutgers University Eric Gawiser.

OWLS: OverWhelmingly Large Simulations The formation of galaxies and the evolution of the intergalactic medium.

Big Bang f(HI) ~ 0 f(HI) ~ 1 f(HI) ~ History of Baryons (mostly hydrogen) Redshift Recombination Reionization z = 1000 (0.4Myr) z = 0 (13.6Gyr) z.

KASI Galaxy Evolution Journal Club A Massive Protocluster of Galaxies at a Redshift of z ~ P. L. Capak et al. 2011, Nature, in press (arXive: )

Study of Proto-clusters by Cosmological Simulation Tamon SUWA, Asao HABE (Hokkaido Univ.) Kohji YOSHIKAWA (Tokyo Univ.)

What is EVLA? Giant steps to the SKA-high ParameterVLAEVLAFactor Point Source Sensitivity (1- , 12 hr.)10  Jy1  Jy 10 Maximum BW in each polarization0.1.

The Physics of Galaxy Formation. Daniel Ceverino (NMSU/Hebrew U.) Anatoly Klypin, Chris Churchill, Glenn Kacprzak (NMSU) Socorro, 2008.

The Mass-Dependent Role of Galaxy Mergers Kevin Bundy (UC Berkeley) Hubble Symposium March, 2009 Masataka Fukugita, Richard Ellis, Tom Targett Sirio Belli,

Maracalagonis, 24/05/ Semi-Analytic Modeling of Galaxy Formation PhD student: Elena Ricciardelli Supervisor: prof. Alberto Franceschini.

The Active to Passive Transition Alvio Renzini, Ringberg Schloss, May 21, 2010 ● Star Formation ceases in many galaxies, first in the most massive ones,

Extragalactic science with adaptive optics ( a few highlights)

The interaction-driven model for the starburst galaxies and AGNs

The morphology and angular momentum of simulated galaxy populations

Observing the formation and evolution of massive galaxies

The History of the Baryon Budget Yann Rasera Supervisor: Romain Teyssier and Jean-Pierre Chièze Horizon Project Cosmological simulations Analytical model.

What is EVLA? Build on existing infrastructure, replace all electronics (correlator, Rx, IF, M/C) => multiply ten-fold the VLA’s observational capabilities.

‘3D’ Data Sets are ABSOLUTELY Crucial to Answer the Important Questions of Galaxy Formation and Evolution Galaxy dynamical masses, gas masses Spatially.

Dense gas history of the Universe  Tracing the fuel for galaxy formation over cosmic time SF Law SFR Millennium Simulations, Obreschkow & Rawlings 2009;

Kinemetry of High-Redshift Galaxies

The SINS survey of galaxy kinematics at z~2 : turbulent thick disks and evidence for rapid secular evolution Reinhard Genzel, Natascha Förster Schreiber,

Brightest ~500,000 Galaxies in the Northern Hemisphere (1977; RA & DEC only) 2-D “lacework” pattern.

Presentation transcript:

BX663 (2.4) MD 41 (2.2) K20-9 (2.0) K20-7 (2.2) K20-8 (2.2) D3a 4751 (2.27) SA (2.3) SA (2.2) GK2471 (2.43) ZC (1.41) K20-5 (2.2) BzK 4165 (1.7) BX 502 (2.16) BX 405 (2.03) BM 1163 (1.41) BX 404 (2.03) SA (1.51) merger-like rotation- dominated K20-6 (2.2) BX 599 (2.33) GK 2113 (1.61) GK 167 (2.58) GK2252 (2.41) BzK 6004 (2.4) BzK (2.4) BX528 (2.3) ZC (2.2) D3a 6397 (1.51) BX389 (2.2) 1” (8 kpc) BX 610 (2.2) BX482 (2.2) increasing dispersion Förster, Bouché,Cresci, Genzel, Shapiro et al SINS 70 Galaxies Disk: 30-40% (v/σ ~ 2 – 4) Disp: 30% (v/σ < 1) Merger: 20-30% Forster Schreiber et al. 09 Shapiro et al. 09

SINS “rotators” Cresci et al. 09

SINS “rotators” Cresci et al. 09

SINS “rotators” Cresci et al. 09

Étude des galaxies à faible masse MUSE Workshop March 18/19 N. Bouché (MPE  LATT)

The Hubble sequence still unexplained  Need to study progenitors!

Why study low-mass galaxies? Ocvirk, Teyssier 08 VVDS SINS LBG

Where are the baryons? S. White & co (SDSS) M halo

New insights in galaxy formation Scaling relations (SFR-Mass, TF, etc..) see H. Flores, M. Puech, L. Tresse Z=2 GOODS sBzK K<22.5 Daddi + Elbaz 07 Z=0 SDSS Puech 08, Cresci 09  Mergers not dominant

Questions Why SFR ~ 200 M/yr at z=2? Origin of scaling relations: TF, SFR-Mass? Role of feedback in low-mass end (z=2)? What happens at z>5 ?

the millenium cosmological simulation high-sigma halos: fed by relatively thin, dense filaments → cold flows typical halos: reside in relatively thick filaments, fed ~spherically → no cold flows

Genel et al. 08 DM accretion rate M halo Insights from Millennium Simulation EPS dM/dt ~ 35 M h 1.0 (1+z) 2.2 SFR =ε 0.18 dM h /dt SINS ε must be ~1

Dark + baryon accretion Prediction: >>50% baryons accreted as cold gas! (but clumpy)

New insights in galaxy formation Scaling relations (SFR-Mass, TF, etc..) see H. Flores, M. Puech, L. Tresse Z=2 GOODS sBzK K<22.5 Daddi + Elbaz 07 Z=0 SDSS EPS

f_baryon at z=0 Observation at z=0 Toy model prediction Strongly tied to only assumption

Gas : : 10% 30-50%Tacconi/Daddi 30%Tacconi 10% Ω(HI)/Ω(star) Accretion prediction Observations

Questions Why SFR ~ 200 M/yr at z=2? Origin of scaling relations: TF, SFR-Mass? Role of feedback in low-mass end (z=2)? What happens at z>5 ?

Galaxy formation with MUSE  Need Resolved spectroscopy (  Mdyn, Mh, SFR, O/H, etc..) of low-mass galaxies A.Feedback processes (IGM, MZ relation) (z~0.7 – 1.0) B.High redshift Lyman alpha emitters C.Cold accretion

Galaxy formation with MUSE  Need Resolved spectroscopy (  Mdyn, Mh, SFR, O/H, etc..) of low-mass galaxies A.Feedback processes (IGM, MZ relation) (z~0.7 – 1.0) B.High redshift Lyman alpha emitters C.Cold accretion

Galaxy formation with MUSE  Need Resolved spectroscopy (  Mdyn, Mh, SFR, O/H, etc..) of low-mass galaxies A.Feedback processes (IGM, MZ relation) (z~0.7 – 1.0) B.High redshift Lyman alpha emitters C.Cold accretion (z~3) 1’

How? Study low-mass galaxies at z~1 [OII] Study filaments at z~3 [Lya] LAE at z~4,5 LAE at z>6 Verhamme  Need KMOS (OII)  Measure ε_SFR (M halo)  Need KMOS / Hawk-I etc  SF UDF MDF

Cold Accretion