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Published byAugustus Murphy Modified over 9 years ago
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Naoyuki Tamura (University of Durham) The Universe at Redshifts from 1 to 2 for Early-Type Galaxies ~ Unveiling “Build-up Era” with FMOS ~
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Outline Summary Galaxy population at z 2 To understand the histories of early-type galaxies … Does stellar population tell us all ? What are expected at 1 < z < 2 ? Revisit the starting point : How can the strengths of Subaru/FMOS be exploited ? Extremely Red Objects Limitation due to lack of spectrum
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NGC 3923 : E4 SFR t Evolutions of CM relation & Fundamental Plane up to z ~ 1 look passive. No active star formation is on-going at z=0. The bulk of stars seem to be old. Stars in Elliptical Galaxies Star formation Passive evolution stopped. z > 2 ?
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Ages at z = 0 from spectroscopy [km/s] 100 200 300 [km/s] 60 100 180 Trager et al. (2000) Caldwell et al. (2003) Cluster Group Field Virgo Field
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What does “age” tell us ? “Galaxy formation history” - when did a galaxy become an elliptical ? “Star formation history” - when did most of the stellar content form ? ? Monolithic Collapse Scenario Starburst Gas rich Hierarchical Merging Scenario Major merger Luminosity Function Stellar Population
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Luminosity Function of E/S0s at z < 1 COMBO-17 ~ 2800 arcmin^2, R < 26 (5 ), ~ 25000 galaxies ~ 5000 galaxies on the red sequence at 0.2 < z < 1.2. Rix et al. (2004) GEMS High resolution imaging follow-up with ACS/HST Most of them (~ 85 %) seem to be morphologically early-type. Evolution of luminosity function
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Luminosity Function of E/S0s at z < 1 COMBO-17 Bell et al. (2003) About half of the local population were already in place at z ~ 1 ?
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Luminosity Function of E/S0s at z < 1 Morphology Spectroscopy Multi-band photometry Im et al. (2002): DEEP Groth Strip survey Chen et al. (2003): Las Campanas IR survey Pozzetti et al. (2003): K20 survey Suggest a mild evolution up to z ~ 1 50 ~ 80 % were already in place at z ~ 1 ? (HST/WFPC2 images)
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Any “bona-fide” E/S0s at z > 2 ? Radio galaxies Rocca-Volmerange et al. (2004) Pentericci et al. (2001) (z = 2.3)(z = 2.4) Passive evolution prediction (z = 10, M = 10 M ) f 12
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Any “bona-fide” E/S0s at z > 2 ? Lyman Break Galaxies SCUBA Galaxies Red galaxies from FIRES No clear Hubble sequence ? A population of passive E/S0s have not revealed yet ? Stellar mass ~ 10 M J-K ~ 2 or redder z = 2 ~ 3 (?) z > 3 Strong clustering ~ 2.5 (1 < z < 4) SFR ~ 1000 M /yr SFR ~ 1 - 100 M /yr Starburst galaxies ? 10 Investigations are on-going...
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How can they be linked at z = 1 ~ 2 ? Star forming galaxies Passive evolution phase Luminosity function of passive galaxies and its evolution at z = 1 ~ 2 A number of post-starburst galaxies ? Half or more of the local population show up in this epoch ? Consumption ? Distant clusters are revealed ? Through redshift survey … somehow Environmental effect ?
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Extremely Red Objects (EROs) Good candidates for passive ellipticals at z > 1. Heterogeneity Although the colour criterion seems to work for isolating passive ellipticals … Luminosity function of EROs has been studied. Our understandings of EROs have been limited due to lack of spectra. R-K > 5 / I-K > 4 (Cimatti et al. 2003; Yan et al. 2004)
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Smith et al. (2002) Smail et al. (2002) Mannucci et al. (2002) Colour criterion to classify EROs Cimatti et al. (2003)
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Miyazaki et al. (2002) Caputi et al. (2004) Evolution of ERO LF at z > 1 ?
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Extremely Red Objects (EROs) Good candidates for passive ellipticals at z > 1. Heterogeneous Although the colour criterion seems to work for isolating passive ellipticals … Luminosity function of EROs has been studied. Photo-z : z ~ 0.3 at z ~ 1.5 Our understandings of EROs have been limited due to lack of spectra. Too coarse to investigate evolution at 1 < z < 2 ? R-K > 5 / I-K > 4 (Cimatti et al. 2003; Yan et al. 2004)
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What we need to do are : To perform deep spectroscopic observations and to get quality data. Redshift Classification Absorption line To collect a large number of galaxies at z > 1 from a large survey area. Good statistics Cosmic variance
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The other word of FMOS (1) Wide spectral coverage in the NIR Spectral features in the rest frame optical are available for galaxies at z > 1. Combination with UKIDSS-DXS Optimal for redshift survey. (& Subaru/Suprime-Cam) Allows us to efficiently pick up candidates for galaxies at z > 1 with colour information. Luminosity can be derived with the aid of redshift.
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The other word of FMOS (2) Wide field & high multiplicity 30’ FMOS-FOV / 400 fibres ~ 200 fibres will be available for objects in one exposure. Better statistics Longer integration Highly efficient !
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Simulated Spectrum H = 20.5 mag Old stellar population (3.0 Gyr age) at z = 1.5 8 hr integration (1 hr x 8) & 5 pix. binning 4000 A G-band HH Mgb
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Gemini Deep Deep Survey 4 x 30 arcmin^2 field Nod & shuffle technique Gemini Multi-Object Spectrograph > 30 hr integration per field Fibre Multi-Object Spectrograph FOV ~ 700 arcmin^2 200/200 fibres for object/sky (+ Double beam switching obs. ?) ??? hr integration per FOV ???????????????? Survey
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Simulated Spectrum H = 22.0 mag Old stellar population (3.0 Gyr age) at z = 1.5 100 hr integration (1 hr x 100) & 5 pix. binning 4000 A G-band HH Mgb NaD
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Summary Luminosity function of passive galaxies Evolution of LF between z = 1 and 2. A number of post-starburst galaxies ? To understand history of early-type galaxy Luminosity Function Stellar Population Bridging two epochs ? z < 12 < z Need to look at absorption lines Star forming galaxiesPassive evolution Wide field & high multiplicity can be exploited for deep observation.
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