logging in or signing up Eric Gawiser pire galform CoolDude26 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 52 Category: Science & Tech.. License: All Rights Reserved Like it (0) Dislike it (0) Added: August 29, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: MUSYC E-HDFS UBR composite Formation and Clustering of High-redshift Galaxies 2. Galaxy Formation Eric Gawiser Rutgers University What Do We Know About Galaxy Formation?: What Do We Know About Galaxy Formation? Recently Solved Problems Integral Constraints Protogalaxy Demographics Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology CMB + galaxy P(k) + Type Ia SNe =0.7, m=0.3, b=0.04, H0=70 km/s/Mpc Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology Final Conditions: Low-z galaxies Well-studied in MW and nearby galaxies Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology Final Conditions: Low-z galaxies Integral Constraints: Cosmological quantities Baryon budget: Star Formation Rate Density (SFRD) is integral constraint over space at a given time (M/yr/Mpc3) Gas Density (gas(t)= gas,0 - 0t d*/dt), Stellar Mass Density (*(t)=0t d*/dt), Metal Density (*(t)=1/42 0t d*/dt) are integral constraints on SFRD over time CIB + FIRB constrain integrated SFRD to z=0 Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology Final Conditions: Low-z galaxies Integral Constraints: Cosmological quantities Identified Galaxy Zoo at z=3 Lyman break galaxies, Lyman alpha emitters, Distant red galaxies, Active Galactic Nuclei, Damped Lyman alpha systems, Submillimeter galaxies However: Evolutionary sequence unclear, progenitors of typical galaxies like the Milky Way yet to be identified Galaxy Formation Models: Galaxy Formation Models Monolithic Collapse Eggen, Lynden-Bell andamp; Sandage 1962 Gravitational collapse of cloud of primordial gas Thus all parts of galaxy formed at the same time Happened very early in the lifetime of the Universe Hierarchical Formation (CDM) Small clumps of matter merge together to form larger galaxies Happens throughout the lifetime of the Universe Thus formation of galaxies is an ongoing process Hierarchical Structure Formation : Hierarchical Structure Formation No preferred scales in DM but non-linear collapse gives distribution of halos where galaxies can form Small halos collapse first 'bottom-up' At zandgt;2, galaxy-mass halos are rare so majority of halos collapsed recently Galaxies have Mmax and Mmin Scales come from 'gastrophysics' of virialization and feedback from supernovae and supermassive black holes Dark energy produces cosmological 'freeze-out' - structure stopped forming at zeq~0.3 Galaxy formation freeze-out occurred earlier in massive galaxies 'downsizing' (anti-hierarchical?) Slide9: Why high redshift? Galaxy formation hard to study in local universe High-z = Jurassic Park of galaxies Nature Sep. 14, 2006 AGN with Damped Lyman Absorber (DLA): AGN with Damped Lyman Absorber (DLA) DLAs have N(HI)andgt;2x1020cm-2, sufficient to self-shield against (re)ionization Provide unbiased sample of lines of sight through the cosmos out to quasar Lower column density systems are ionized DLAs dominate neutral gas content Cosmic density of neutral gas : Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0 HI (21cm) HI (DLAs) gas (x10-3) History of neutral gas: History of neutral gas Closed box: dgas/dt =-d*/dt Cosmic density of neutral gas : Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0 HI (21cm) HI (DLAs) gas (x10-3) Cosmic density of neutral gas: Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0, forming andgt;~ half of the stars seen today HI (21cm) stars HI (DLAs) gas (x10-3) History of neutral gas: History of neutral gas Closed box: dgas/dt =-d*/dt History of neutral gas: History of neutral gas Closed box: dgas/dt =-d*/dt Open box: dgas/dt =-d*/dt + infall + merging - winds Cosmic density of neutral gas: Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0, forming andgt;~ half of the stars seen today HI (21cm) stars HI (DLAs) gas (x10-3) Cosmic star formation history: Cosmic star formation history 16% of cosmic age Giavalisco et al. 2004 zandgt;3 points from Lyman break galaxies only Solid blue curve: semi-analytic model of Somerville et al. 2001 Most stars formed at z<2: Most stars formed at zandlt;2 Pettini 2003 Stellar mass density *(t)=0t d*/dt : Stellar mass density *(t)=0t d*/dt Dust extinction less problematic, but need to know IMF and star formation history Dickinson et al 2003 Cosmic metal enrichment history *(t)=1/42 0t d*/dt : Cosmic metal enrichment history *(t)=1/42 0t d*/dt Cosmic metallicity traced by DLAs rises gradually Wolfe, Gawiser andamp; Prochaska 2005, ARAA DLA metallicities in context: DLA metallicities in context Pettini 2003 Evidence for dust depletion and alpha enhancement in DLAs: Evidence for dust depletion and alpha enhancement in DLAs DLA Kinematics: Disks or Clumps?: DLA Kinematics: Disks or Clumps? Theoretical Advances: Theoretical Advances Semi-analytical models reproduce observations moderately well Cosmological hydrodynamic simulations have advanced greatly - but use recipes for star formation and supernova feedback Cosmological hydro simulations Nagamine et al. 2003: Cosmological hydro simulations Nagamine et al. 2003 M=1010 M Hydro simulation of SFR history as a function of mass using “recipes”: Hydro simulation of SFR history as a function of mass using 'recipes' Nagamine et al. 2003 Demographics of Protogalaxies: Demographics of Protogalaxies Searching for the progenitors of typical galaxies like the Milky Way - are they found amongst the zoo of objects at z=3? Cosmological quantities (SFR, stellar mass buildup) should be summed over all high-redshift objects, not just DLAs, which trace the low-dust neutral gas, or LBGs, which trace the bright end of the luminosity function MUSYC(Multiwavelength Survey by Yale-Chile): MUSYC (Multiwavelength Survey by Yale-Chile) www.astro.yale.edu/MUSYC Gawiser et al 2006a, ApJS 162, 1 Eric Gawiser (Yale, P.I.) Pieter van Dokkum (Yale, P.I.) Paulina Lira (U. Chile) Meg Urry (Yale) Martin Altmann (U. Chile) Felipe Barrientos (P.U. Catolica) Francisco Castander (IEEC-Barcelona) Daniel Christlein (U. Chile/Yale) Paolo Coppi (Yale) Marijn Franx (Leiden) Gaspar Galaz (P.U. Catolica) David Herrera (Yale) Leopoldo Infante (P.U. Catolica) Sheila Kannappan (U.T. Austin) Charles Liu (CUNY/AMNH) Sebastian Lopez (U. Chile) Danilo Marchesini (Yale) José Maza (U. Chile) Rene Méndez (U. Chile) Nelson Padilla (P.U. Catolica) Ezequiel Treister (ESO) Bill van Altena (Yale) Sukyoung Yi (Yonsei) MUSYC (Multiwavelength Survey by Yale-Chile): MUSYC (Multiwavelength Survey by Yale-Chile) Square degree comprised of four 30'x30' fields (E-CDFS, E-HDFS, SDSS1030+05, Castander’s Window 1255+01) Deep UBVRIzJHK + NB5000Å imaging (to 5 depths of U,B,V,RAB=26, KAB=23, NB5000=25) Spitzer-MIPS+IRAC/HST-ACS/GALEX/XMM/Chandra coverage in 3/4 fields Spectroscopic follow-up with VLT+VIMOS, Magellan+IMACS, Gemini+GNIRS MUSYC: A Square-degree Survey of the Formation and Evolution of Galaxies and their Central Black Holes Science Projects:: MUSYC: A Square-degree Survey of the Formation and Evolution of Galaxies and their Central Black Holes Science Projects: Census of galaxies at z=3 (Gawiser) Evolved galaxies at 2andlt;zandlt;3 (van Dokkum) AGN demographics at 0andlt;zandlt;6 (Urry) Properties of K-selected galaxies at zandlt;2 (Lira, Barrientos, Infante) Proper motion + color survey for white and brown dwarfs (Mendez) Groups and clusters at zandlt;1 (Christlein, Lin) Recent star formation in ellipticals (Yi) Public outreach at Hayden Planetarium (Liu) Students giving MUSYC posters: Students giving MUSYC posters Paula Aguirre (PUC) 'Clustering of K-selected galaxies' Harold Francke (U. Chile) 'Clustering of AGN at z=3' 75% of the baryons are hydrogen : 75% of the baryons are hydrogen At z=3, Lyman series falls in observed-frame optical Ionizing photons (andgt;13.6eV= andlt;912Å) do not escape 'Lyman Break' Ly photons (10.2eV=1216Å) from recombination if stars have formed recently enough that little dust exists Protogalaxies at z=3: TLAs: Protogalaxies at z=3: TLAs LBG=Lyman Break Galaxy selected via Lyman break, blue continuum (starburst) LAE=Lyman Alpha Emitter selected via strong emission line (early stage of star formation) DRG=Distant Red Galaxy selected via Balmer break in observed NIR SMG=Sub-Millimeter Galaxy selected in sub-mm, use radio to get position DLA=Damped Lyman Absorption system selected in absorption, N(HI)andgt;1020 cm-2 Origin of the Lyman break: Origin of the Lyman break Steidel andamp; Hamilton 1992 Origin of the Lyman break: Origin of the Lyman break Steidel andamp; Hamilton 1992 V R U Lyman Break Galaxy (LBG): Lyman Break Galaxy (LBG) Steidel andamp; Hamilton 1992 LBG in E-CDFS, R=22.8, z=3.38 strong Ly emission (EW=60Å, SFRUV ≥350 M/yr) numerous chemical absorption features (6 hr IMACS exposure) : LBG in E-CDFS, R=22.8, z=3.38 strong Ly emission (EW=60Å, SFRUV ≥350 M/yr) numerous chemical absorption features (6 hr IMACS exposure) Ly SiII OI/SiII CII FeII SiIV SiII CIV MUSYC LBGs: age, stellar mass,dust, SFR: LBGs: age, stellar mass, dust, SFR Pettini 2003 Stellar winds in LBGs: Stellar winds in LBGs Pettini 2003 Slide41: U B NB5000 V R Lyman Emitter (LAE) Gawiser et al 2006b, ApJ 642, L13, astro-ph/0603244 (MUSYC plus Caryl Gronwall, Robin Ciardullo, John Feldmeier) BV - NB5000 selection of LAEs: BV - NB5000 selection of LAEs LAE in E-CDFS, R=25.7, z=3.085 Ly EW=200Å, SFR≥30 M/yr (6 hr IMACS exposure): LAE in E-CDFS, R=25.7, z=3.085 Ly EW=200Å, SFR≥30 M/yr (6 hr IMACS exposure) MUSYC Gawiser et al 2005 Slide44: Rest-frame UV continuum flux of spectroscopically confirmed samples LBG LAE # obj MUSYC UVR colors of confirmed objects: UVR colors of confirmed objects Confirmed LAE Confirmed LBG Images from HST-ACS: irregular morphology at z=3: Images from HST-ACS: irregular morphology at z=3 AGN z=3.60 R=22.4 LBG z=3.37 R=24.3 LBG z=3.24 R=23.8 LAE z=3.10 R=26.1 NIR selects rest-frame Balmer break at 2<z<4: NIR selects rest-frame Balmer break at 2andlt;zandlt;4 Reddy et al 2005 Distant Red Galaxies (DRG): Distant Red Galaxies (DRG) van Dokkum et al 2005, in prep. MUSYC van Dokkum et al 2005 Redshift distributions of 1.5<z<3.5 samples: Redshift distributions of 1.5andlt;zandlt;3.5 samples Reddy et al 2005 SMG contribution to SFRD: SMG contribution to SFRD Chapman et al 2005 Slide51: M = MUSYC, in progress Slide52: M = MUSYC, in progress Three Recent Reviews: Three Recent Reviews Pettini 2003, 'Element Abundances through the Cosmic Ages', astro-ph/0303272 Silk 2004, 'Dark Matter and Galaxy Formation: Challenges for the Next Decade', astro-ph/0412297 Wolfe, Gawiser andamp; Prochaska 2005, 'The Damped Ly Systems', ARAA, astro-ph/0509481 Gawiser Problem 3 is now assigned: Gawiser Problem 3 is now assigned You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
Eric Gawiser pire galform CoolDude26 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 52 Category: Science & Tech.. License: All Rights Reserved Like it (0) Dislike it (0) Added: August 29, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: MUSYC E-HDFS UBR composite Formation and Clustering of High-redshift Galaxies 2. Galaxy Formation Eric Gawiser Rutgers University What Do We Know About Galaxy Formation?: What Do We Know About Galaxy Formation? Recently Solved Problems Integral Constraints Protogalaxy Demographics Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology CMB + galaxy P(k) + Type Ia SNe =0.7, m=0.3, b=0.04, H0=70 km/s/Mpc Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology Final Conditions: Low-z galaxies Well-studied in MW and nearby galaxies Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology Final Conditions: Low-z galaxies Integral Constraints: Cosmological quantities Baryon budget: Star Formation Rate Density (SFRD) is integral constraint over space at a given time (M/yr/Mpc3) Gas Density (gas(t)= gas,0 - 0t d*/dt), Stellar Mass Density (*(t)=0t d*/dt), Metal Density (*(t)=1/42 0t d*/dt) are integral constraints on SFRD over time CIB + FIRB constrain integrated SFRD to z=0 Recently Solved Problems in Galaxy Formation: Recently Solved Problems in Galaxy Formation Initial Conditions: WMAP cosmology Final Conditions: Low-z galaxies Integral Constraints: Cosmological quantities Identified Galaxy Zoo at z=3 Lyman break galaxies, Lyman alpha emitters, Distant red galaxies, Active Galactic Nuclei, Damped Lyman alpha systems, Submillimeter galaxies However: Evolutionary sequence unclear, progenitors of typical galaxies like the Milky Way yet to be identified Galaxy Formation Models: Galaxy Formation Models Monolithic Collapse Eggen, Lynden-Bell andamp; Sandage 1962 Gravitational collapse of cloud of primordial gas Thus all parts of galaxy formed at the same time Happened very early in the lifetime of the Universe Hierarchical Formation (CDM) Small clumps of matter merge together to form larger galaxies Happens throughout the lifetime of the Universe Thus formation of galaxies is an ongoing process Hierarchical Structure Formation : Hierarchical Structure Formation No preferred scales in DM but non-linear collapse gives distribution of halos where galaxies can form Small halos collapse first 'bottom-up' At zandgt;2, galaxy-mass halos are rare so majority of halos collapsed recently Galaxies have Mmax and Mmin Scales come from 'gastrophysics' of virialization and feedback from supernovae and supermassive black holes Dark energy produces cosmological 'freeze-out' - structure stopped forming at zeq~0.3 Galaxy formation freeze-out occurred earlier in massive galaxies 'downsizing' (anti-hierarchical?) Slide9: Why high redshift? Galaxy formation hard to study in local universe High-z = Jurassic Park of galaxies Nature Sep. 14, 2006 AGN with Damped Lyman Absorber (DLA): AGN with Damped Lyman Absorber (DLA) DLAs have N(HI)andgt;2x1020cm-2, sufficient to self-shield against (re)ionization Provide unbiased sample of lines of sight through the cosmos out to quasar Lower column density systems are ionized DLAs dominate neutral gas content Cosmic density of neutral gas : Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0 HI (21cm) HI (DLAs) gas (x10-3) History of neutral gas: History of neutral gas Closed box: dgas/dt =-d*/dt Cosmic density of neutral gas : Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0 HI (21cm) HI (DLAs) gas (x10-3) Cosmic density of neutral gas: Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0, forming andgt;~ half of the stars seen today HI (21cm) stars HI (DLAs) gas (x10-3) History of neutral gas: History of neutral gas Closed box: dgas/dt =-d*/dt History of neutral gas: History of neutral gas Closed box: dgas/dt =-d*/dt Open box: dgas/dt =-d*/dt + infall + merging - winds Cosmic density of neutral gas: Cosmic density of neutral gas Wolfe, Gawiser andamp; Prochaska 2005, ARAA Neutral gas reservoir traced by DLAs is depleted by z=0, forming andgt;~ half of the stars seen today HI (21cm) stars HI (DLAs) gas (x10-3) Cosmic star formation history: Cosmic star formation history 16% of cosmic age Giavalisco et al. 2004 zandgt;3 points from Lyman break galaxies only Solid blue curve: semi-analytic model of Somerville et al. 2001 Most stars formed at z<2: Most stars formed at zandlt;2 Pettini 2003 Stellar mass density *(t)=0t d*/dt : Stellar mass density *(t)=0t d*/dt Dust extinction less problematic, but need to know IMF and star formation history Dickinson et al 2003 Cosmic metal enrichment history *(t)=1/42 0t d*/dt : Cosmic metal enrichment history *(t)=1/42 0t d*/dt Cosmic metallicity traced by DLAs rises gradually Wolfe, Gawiser andamp; Prochaska 2005, ARAA DLA metallicities in context: DLA metallicities in context Pettini 2003 Evidence for dust depletion and alpha enhancement in DLAs: Evidence for dust depletion and alpha enhancement in DLAs DLA Kinematics: Disks or Clumps?: DLA Kinematics: Disks or Clumps? Theoretical Advances: Theoretical Advances Semi-analytical models reproduce observations moderately well Cosmological hydrodynamic simulations have advanced greatly - but use recipes for star formation and supernova feedback Cosmological hydro simulations Nagamine et al. 2003: Cosmological hydro simulations Nagamine et al. 2003 M=1010 M Hydro simulation of SFR history as a function of mass using “recipes”: Hydro simulation of SFR history as a function of mass using 'recipes' Nagamine et al. 2003 Demographics of Protogalaxies: Demographics of Protogalaxies Searching for the progenitors of typical galaxies like the Milky Way - are they found amongst the zoo of objects at z=3? Cosmological quantities (SFR, stellar mass buildup) should be summed over all high-redshift objects, not just DLAs, which trace the low-dust neutral gas, or LBGs, which trace the bright end of the luminosity function MUSYC(Multiwavelength Survey by Yale-Chile): MUSYC (Multiwavelength Survey by Yale-Chile) www.astro.yale.edu/MUSYC Gawiser et al 2006a, ApJS 162, 1 Eric Gawiser (Yale, P.I.) Pieter van Dokkum (Yale, P.I.) Paulina Lira (U. Chile) Meg Urry (Yale) Martin Altmann (U. Chile) Felipe Barrientos (P.U. Catolica) Francisco Castander (IEEC-Barcelona) Daniel Christlein (U. Chile/Yale) Paolo Coppi (Yale) Marijn Franx (Leiden) Gaspar Galaz (P.U. Catolica) David Herrera (Yale) Leopoldo Infante (P.U. Catolica) Sheila Kannappan (U.T. Austin) Charles Liu (CUNY/AMNH) Sebastian Lopez (U. Chile) Danilo Marchesini (Yale) José Maza (U. Chile) Rene Méndez (U. Chile) Nelson Padilla (P.U. Catolica) Ezequiel Treister (ESO) Bill van Altena (Yale) Sukyoung Yi (Yonsei) MUSYC (Multiwavelength Survey by Yale-Chile): MUSYC (Multiwavelength Survey by Yale-Chile) Square degree comprised of four 30'x30' fields (E-CDFS, E-HDFS, SDSS1030+05, Castander’s Window 1255+01) Deep UBVRIzJHK + NB5000Å imaging (to 5 depths of U,B,V,RAB=26, KAB=23, NB5000=25) Spitzer-MIPS+IRAC/HST-ACS/GALEX/XMM/Chandra coverage in 3/4 fields Spectroscopic follow-up with VLT+VIMOS, Magellan+IMACS, Gemini+GNIRS MUSYC: A Square-degree Survey of the Formation and Evolution of Galaxies and their Central Black Holes Science Projects:: MUSYC: A Square-degree Survey of the Formation and Evolution of Galaxies and their Central Black Holes Science Projects: Census of galaxies at z=3 (Gawiser) Evolved galaxies at 2andlt;zandlt;3 (van Dokkum) AGN demographics at 0andlt;zandlt;6 (Urry) Properties of K-selected galaxies at zandlt;2 (Lira, Barrientos, Infante) Proper motion + color survey for white and brown dwarfs (Mendez) Groups and clusters at zandlt;1 (Christlein, Lin) Recent star formation in ellipticals (Yi) Public outreach at Hayden Planetarium (Liu) Students giving MUSYC posters: Students giving MUSYC posters Paula Aguirre (PUC) 'Clustering of K-selected galaxies' Harold Francke (U. Chile) 'Clustering of AGN at z=3' 75% of the baryons are hydrogen : 75% of the baryons are hydrogen At z=3, Lyman series falls in observed-frame optical Ionizing photons (andgt;13.6eV= andlt;912Å) do not escape 'Lyman Break' Ly photons (10.2eV=1216Å) from recombination if stars have formed recently enough that little dust exists Protogalaxies at z=3: TLAs: Protogalaxies at z=3: TLAs LBG=Lyman Break Galaxy selected via Lyman break, blue continuum (starburst) LAE=Lyman Alpha Emitter selected via strong emission line (early stage of star formation) DRG=Distant Red Galaxy selected via Balmer break in observed NIR SMG=Sub-Millimeter Galaxy selected in sub-mm, use radio to get position DLA=Damped Lyman Absorption system selected in absorption, N(HI)andgt;1020 cm-2 Origin of the Lyman break: Origin of the Lyman break Steidel andamp; Hamilton 1992 Origin of the Lyman break: Origin of the Lyman break Steidel andamp; Hamilton 1992 V R U Lyman Break Galaxy (LBG): Lyman Break Galaxy (LBG) Steidel andamp; Hamilton 1992 LBG in E-CDFS, R=22.8, z=3.38 strong Ly emission (EW=60Å, SFRUV ≥350 M/yr) numerous chemical absorption features (6 hr IMACS exposure) : LBG in E-CDFS, R=22.8, z=3.38 strong Ly emission (EW=60Å, SFRUV ≥350 M/yr) numerous chemical absorption features (6 hr IMACS exposure) Ly SiII OI/SiII CII FeII SiIV SiII CIV MUSYC LBGs: age, stellar mass,dust, SFR: LBGs: age, stellar mass, dust, SFR Pettini 2003 Stellar winds in LBGs: Stellar winds in LBGs Pettini 2003 Slide41: U B NB5000 V R Lyman Emitter (LAE) Gawiser et al 2006b, ApJ 642, L13, astro-ph/0603244 (MUSYC plus Caryl Gronwall, Robin Ciardullo, John Feldmeier) BV - NB5000 selection of LAEs: BV - NB5000 selection of LAEs LAE in E-CDFS, R=25.7, z=3.085 Ly EW=200Å, SFR≥30 M/yr (6 hr IMACS exposure): LAE in E-CDFS, R=25.7, z=3.085 Ly EW=200Å, SFR≥30 M/yr (6 hr IMACS exposure) MUSYC Gawiser et al 2005 Slide44: Rest-frame UV continuum flux of spectroscopically confirmed samples LBG LAE # obj MUSYC UVR colors of confirmed objects: UVR colors of confirmed objects Confirmed LAE Confirmed LBG Images from HST-ACS: irregular morphology at z=3: Images from HST-ACS: irregular morphology at z=3 AGN z=3.60 R=22.4 LBG z=3.37 R=24.3 LBG z=3.24 R=23.8 LAE z=3.10 R=26.1 NIR selects rest-frame Balmer break at 2<z<4: NIR selects rest-frame Balmer break at 2andlt;zandlt;4 Reddy et al 2005 Distant Red Galaxies (DRG): Distant Red Galaxies (DRG) van Dokkum et al 2005, in prep. MUSYC van Dokkum et al 2005 Redshift distributions of 1.5<z<3.5 samples: Redshift distributions of 1.5andlt;zandlt;3.5 samples Reddy et al 2005 SMG contribution to SFRD: SMG contribution to SFRD Chapman et al 2005 Slide51: M = MUSYC, in progress Slide52: M = MUSYC, in progress Three Recent Reviews: Three Recent Reviews Pettini 2003, 'Element Abundances through the Cosmic Ages', astro-ph/0303272 Silk 2004, 'Dark Matter and Galaxy Formation: Challenges for the Next Decade', astro-ph/0412297 Wolfe, Gawiser andamp; Prochaska 2005, 'The Damped Ly Systems', ARAA, astro-ph/0509481 Gawiser Problem 3 is now assigned: Gawiser Problem 3 is now assigned