logging in or signing up Eric Gawiser pire galclust 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: 38 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 3. Galaxy Clustering Eric Gawiser Rutgers University 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 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 ECDFS RJK: ECDFS RJK NIR selects rest-frame Balmer/4000Å break at 2<z<4: NIR selects rest-frame Balmer/4000Å 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 2006 Sub-Millimeter Galaxy contribution to Star Formation Rate Density: Sub-Millimeter Galaxy contribution to Star Formation Rate Density Chapman et al 2005 LBGs and LAEs in MUSYC-ECDFS: LBGs and LAEs in MUSYC-ECDFS 1240 LBGs 162 LAEs Projection of 12(r )=(r/r0)- into w12() = dz1 dz2 p1(z1)p2(z2) 12(r(z1,z2, )) Need redshifts to determine selection functions pi(z) for inversion of w12() to determine 12(r): Projection of 12(r )=(r/r0)- into w12() = dz1 dz2 p1(z1)p2(z2) 12(r(z1,z2, )) Need redshifts to determine selection functions pi(z) for inversion of w12() to determine 12(r) Spatial and angular cross-correlation functions: dP(r) = 12[1 + 12(r)] dV1 dV2 dP() = 12[1 + w12()] d1 d2 For autocorrelation and acceptable geometry, Limber approximation w() = 1- r0 (1/2, (-1)/2) p2(z) (1+z)1- DA(z)1- H(z)/c dz LBG and LAE redshift distributions : LBG and LAE redshift distributions 2.8andlt;zandlt;3.7 expected for UVR Dark curve shows selection function: narrow-band filter response convolved with EW distribution LAE LBG Measuring angular auto-correlation: Measuring angular auto-correlation (): Excess probability of finding pairs separated by angular distance over uniform distribution Landy-Szalay estimator uses counts of pairs separated by DD: between data pairs DR: data-random pairs RR: random-random pairs The random pairs 'subtract' the excess probability that is due to the geometry of the survey Usually assumed that () = A- LBGs and LAEs in MUSYC-ECDFS: LBGs and LAEs in MUSYC-ECDFS 1240 LBGs 162 LAEs LBGs in MUSYC-ECDFS: LBGs in MUSYC-ECDFS 1240 LBGs Clustering analysis by Harold Francke LAEs in MUSYC-ECDFS: LAEs in MUSYC-ECDFS 162 LAEs Clustering analysis by H. Francke Clustering Determination: Clustering Determination LBG, LAE, and DRG samples are large enough to use r0 to determine bias xLBG-LBG( r ) = (r/r0)- =b2LBG xDM( r ) SMG, DLA samples are small, so study cross-correlation with numerous LBGs to determine bias xDLA-LBG( r ) =(r/r0)- = bDLAbLBG xDM( r ) bLBG etc. determine typical dark matter halo masses of each family of protogalaxies Method for auto-correlation from Mo andamp; White 1996, MNRAS 282, 347 First applied to cross-correlation by Gawiser et al 2001, ApJ 562, 628 Bias minimum DM halo massnumber abundance of host halos: Bias minimum DM halo mass number abundance of host halos MUSYC Quadri et al 2007 Clustering vs. halo abundance: Clustering vs. halo abundance What are the low-redshift descendants of z=3 galaxies?: What are the low-redshift descendants of z=3 galaxies? Gawiser et al 2007, in prep LAE 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? Did galaxy, stars, supermassive black holes all form simultaneously? 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? Thin disk: 10 Gyr - formed at z~2 but simulations have trouble making. Angular momentum coupling between DM andamp; baryons affects bar/disk formation and bulge cuspiness. Globular clusters: formed by Pop III stars in 106 M halos? 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? When/how did galaxy sequences evolve? Hubble sequence not yet present at zandgt;2 Red/blue sequences (bimodality of properties) require 'gastrophysics' 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? When/how did galaxy sequences evolve? What role did feedback play? Feedback from AGN andamp; supernovae regulates BH/bulge formation, cuspiness of DM halo, baryonic mass loss, IGM enrichment, minimum galaxy mass 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? When/how did galaxy sequences evolve? What role did feedback play? When/how was the universe reionized? Top-heavy IMF predicted at high-z due to low metallicity but exact mass range/epoch unknown and nature of 'surviving' galaxies is sensitive Coming Attractions: Coming Attractions Unification of galaxy formation and evolution Needle-in-haystack techniques evolved gals at zandgt;2 Multiwavelength high-z analogs at low-z Evolutionary sequence (e.g. DLALAELBGSMGDRG) as part of 'grand unified' model of galaxies andamp; AGN Spitzer is key Coming Attractions: Coming Attractions Unification of galaxy formation and evolution ISM in emission at high-redshift CO, [CII] 158 micron with ALMA Compare gas mass with stellar mass Compare tips of high-redshift gas and stellar luminosity functions Coming Attractions: Coming Attractions Unification of galaxy formation and evolution ISM in emission at high-redshift High-redshift galaxies constrain dark energy? Baryon oscillations as standard rod - need zandgt;1 point to constrain equation-of-state (w) of dark energy A million redshifts needed? WFMOS! Blake andamp; Glazebrook 2003, Linder 2003, Seo andamp; Eisenstein 2003 Coming Attractions: Coming Attractions Unification of galaxy formation and evolution ISM in emission at high-redshift High-redshift galaxies constrain dark energy? More jargon Sub-classes (sub-DLAs, bDLAs) may force FLAs! N2 cross-correlation functions Slide28: MUSYC Public Data Release June 1, 2007 at http://www.astro.yale.edu/MUSYC UBVRIzK imaging of 1.2 square degrees to U,B,V,R = 26, K=22 (AB) JHK imaging of 0.1 square degrees to K=23 (AB) Deep Spitzer+IRAC imaging (all 4 bands) of ECDF-S 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 galclust 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: 38 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 3. Galaxy Clustering Eric Gawiser Rutgers University 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 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 ECDFS RJK: ECDFS RJK NIR selects rest-frame Balmer/4000Å break at 2<z<4: NIR selects rest-frame Balmer/4000Å 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 2006 Sub-Millimeter Galaxy contribution to Star Formation Rate Density: Sub-Millimeter Galaxy contribution to Star Formation Rate Density Chapman et al 2005 LBGs and LAEs in MUSYC-ECDFS: LBGs and LAEs in MUSYC-ECDFS 1240 LBGs 162 LAEs Projection of 12(r )=(r/r0)- into w12() = dz1 dz2 p1(z1)p2(z2) 12(r(z1,z2, )) Need redshifts to determine selection functions pi(z) for inversion of w12() to determine 12(r): Projection of 12(r )=(r/r0)- into w12() = dz1 dz2 p1(z1)p2(z2) 12(r(z1,z2, )) Need redshifts to determine selection functions pi(z) for inversion of w12() to determine 12(r) Spatial and angular cross-correlation functions: dP(r) = 12[1 + 12(r)] dV1 dV2 dP() = 12[1 + w12()] d1 d2 For autocorrelation and acceptable geometry, Limber approximation w() = 1- r0 (1/2, (-1)/2) p2(z) (1+z)1- DA(z)1- H(z)/c dz LBG and LAE redshift distributions : LBG and LAE redshift distributions 2.8andlt;zandlt;3.7 expected for UVR Dark curve shows selection function: narrow-band filter response convolved with EW distribution LAE LBG Measuring angular auto-correlation: Measuring angular auto-correlation (): Excess probability of finding pairs separated by angular distance over uniform distribution Landy-Szalay estimator uses counts of pairs separated by DD: between data pairs DR: data-random pairs RR: random-random pairs The random pairs 'subtract' the excess probability that is due to the geometry of the survey Usually assumed that () = A- LBGs and LAEs in MUSYC-ECDFS: LBGs and LAEs in MUSYC-ECDFS 1240 LBGs 162 LAEs LBGs in MUSYC-ECDFS: LBGs in MUSYC-ECDFS 1240 LBGs Clustering analysis by Harold Francke LAEs in MUSYC-ECDFS: LAEs in MUSYC-ECDFS 162 LAEs Clustering analysis by H. Francke Clustering Determination: Clustering Determination LBG, LAE, and DRG samples are large enough to use r0 to determine bias xLBG-LBG( r ) = (r/r0)- =b2LBG xDM( r ) SMG, DLA samples are small, so study cross-correlation with numerous LBGs to determine bias xDLA-LBG( r ) =(r/r0)- = bDLAbLBG xDM( r ) bLBG etc. determine typical dark matter halo masses of each family of protogalaxies Method for auto-correlation from Mo andamp; White 1996, MNRAS 282, 347 First applied to cross-correlation by Gawiser et al 2001, ApJ 562, 628 Bias minimum DM halo massnumber abundance of host halos: Bias minimum DM halo mass number abundance of host halos MUSYC Quadri et al 2007 Clustering vs. halo abundance: Clustering vs. halo abundance What are the low-redshift descendants of z=3 galaxies?: What are the low-redshift descendants of z=3 galaxies? Gawiser et al 2007, in prep LAE 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? Did galaxy, stars, supermassive black holes all form simultaneously? 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? Thin disk: 10 Gyr - formed at z~2 but simulations have trouble making. Angular momentum coupling between DM andamp; baryons affects bar/disk formation and bulge cuspiness. Globular clusters: formed by Pop III stars in 106 M halos? 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? When/how did galaxy sequences evolve? Hubble sequence not yet present at zandgt;2 Red/blue sequences (bimodality of properties) require 'gastrophysics' 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? When/how did galaxy sequences evolve? What role did feedback play? Feedback from AGN andamp; supernovae regulates BH/bulge formation, cuspiness of DM halo, baryonic mass loss, IGM enrichment, minimum galaxy mass 5 Unsolved Problems in Galaxy Formation: 5 Unsolved Problems in Galaxy Formation What does a protogalaxy look like? When/how did each component form? When/how did galaxy sequences evolve? What role did feedback play? When/how was the universe reionized? Top-heavy IMF predicted at high-z due to low metallicity but exact mass range/epoch unknown and nature of 'surviving' galaxies is sensitive Coming Attractions: Coming Attractions Unification of galaxy formation and evolution Needle-in-haystack techniques evolved gals at zandgt;2 Multiwavelength high-z analogs at low-z Evolutionary sequence (e.g. DLALAELBGSMGDRG) as part of 'grand unified' model of galaxies andamp; AGN Spitzer is key Coming Attractions: Coming Attractions Unification of galaxy formation and evolution ISM in emission at high-redshift CO, [CII] 158 micron with ALMA Compare gas mass with stellar mass Compare tips of high-redshift gas and stellar luminosity functions Coming Attractions: Coming Attractions Unification of galaxy formation and evolution ISM in emission at high-redshift High-redshift galaxies constrain dark energy? Baryon oscillations as standard rod - need zandgt;1 point to constrain equation-of-state (w) of dark energy A million redshifts needed? WFMOS! Blake andamp; Glazebrook 2003, Linder 2003, Seo andamp; Eisenstein 2003 Coming Attractions: Coming Attractions Unification of galaxy formation and evolution ISM in emission at high-redshift High-redshift galaxies constrain dark energy? More jargon Sub-classes (sub-DLAs, bDLAs) may force FLAs! N2 cross-correlation functions Slide28: MUSYC Public Data Release June 1, 2007 at http://www.astro.yale.edu/MUSYC UBVRIzK imaging of 1.2 square degrees to U,B,V,R = 26, K=22 (AB) JHK imaging of 0.1 square degrees to K=23 (AB) Deep Spitzer+IRAC imaging (all 4 bands) of ECDF-S