Lectures on Stellar Populations Spectral Indices Broad Band Colors are affected by the AGE-METALLICITY DEGENERACY Spectral indices have been introduced.

Lectures on Stellar Populations Spectral Indices Broad Band Colors are affected by the AGE-METALLICITY DEGENERACY Spectral indices have been introduced to overcome this problem

Lectures on Stellar Populations Lick Indices Definition: Worthey, Faber, Gonzales, Burstein 1994 Measurement: Kuntschner and Davies 1997 EW, e.g.: MAG, e.g.:

Lectures on Stellar Populations Lick Indices: measurement NOT TRIVIAL Trager’s Thesis 1. Define Pseudocontinuum Flux in the two side bands 2. F c (λ) is the straight line through the 2 adjacent F P Then index is:

Lectures on Stellar Populations Stellar Population Indices are Synthetized not analyzed INDICES FOR SSPs: Start from simplyfied definitions: with some algebra you get: In the SSP, each star contributes its index weighted by the star’s contribution to the total continuum flux

Lectures on Stellar Populations SSP Indices: first derive the SED, then ‘measure’ the index Vazdekis 1999 500 stars (Jones, 97) with spectral resolution of 2 A: Only in the range 3820 – 4500 A 4780 – 5460 A Kurucz models have a resolution of 20 A Lick indices resolution is 8-10 A Need a high resolution stellar SED AND Basically all stars at solar Z

Lectures on Stellar Populations Lick Indices from SED Bertone, Buzzoni et al 2004 Models of atmospheres

Lectures on Stellar Populations Alternatively: Fitting Functions Gorgas et al. 1993

Lectures on Stellar Populations Lick Indices Worthey et al.1994

Lectures on Stellar Populations SSP Lick Indices: an example Metallic line strenghts increase with both AGE and Metallicity Hβ gets weaker as age increases and as Metallicity increases Use combination of metallic and Balmer line strenghts to solve the AGE-METALLICITY degeneracy

Lectures on Stellar Populations First, but very interesting, results: alpha elements overabundance in Es Worthey, Faber & Gonzales 1992: At given Fe index, the data Mg index is stronger than the model predictions Interpreted as a supersolar Mg/Fe ratio Among various possibilities: Short Formation timescales for Es Notice that: Z Fe,o =1.3e-03 Z O,o = 5.8e-03 Αlpha overabundance is more an Fe underabundance

Lectures on Stellar Populations First, but very interesting, results: Age spread among Es Gonzales et al. 1992: E galaxies span a small range in metallicity and a wide range in age The most metal rich are also the OLDEST The alpha overabundance syndrome is also evident 2.5 1.6 1.3

Lectures on Stellar Populations Indices: which diagnostic power? For magnitues consider 10 -0.4(INDEX) Most of the Index growth occurs in the (upper) MS and in the (lower) RGB No wander: these are the phases which Most contribute to the continuum flux In the optical The various fitting functions appear to agree in the relevant evolutionary phases: the final values of the indices happen to agree (at least for this isochrone)

Lectures on Stellar Populations Model Lick Indices compared with GCs data Puzia et al. (2002) measure Lick Indices for 12 MW GCs, 9 in the Bulge Maraston et al. (2002) derive metallicity by comparing with 12 Gyr old SSP models Spectroscopic/Photometric metallicity is available for these clusters: COMPARE THE TWO: The metallicity derived from the Mg index is approx. OK The metallicity derived from the Fe index is systematically low Again: effect of alpha overabundance (Fe depletion)

Lectures on Stellar Populations Indices with alpha enhancement

Lectures on Stellar Populations Tripicco and Bell (1995): Stellar sample with solar Z TB compute high resolution stellar spectra using model atmospheres for (g,Te) combinations along the M67 isochrone. Model Indices are computed for solar Mixture and for other mixtures in which Each element abundance is doubled So as to measure the partial derivative. Find that some indices trace abundance Some do not: Fe4668 is very sensitive to C abundance Compare model indices to a)Stellar values b) Worthey fitting functions

Lectures on Stellar Populations DWARFS GIANTS TB95 W ff

Lectures on Stellar Populations Effect of elemental variation Tripicco and Bell 1995: compute variation of Index in response to doubling the abundance of one element, which leaves (almost) constant the total metallicity Computed for Dwarf Turn-Off star Red Giant

Lectures on Stellar Populations Indices: Correction for alpha overabundance following Thomas, Maraston & Bender (2003) Tripicco and Bell 95 give : for D, TO and G For each class compute the corrected index with: = 0.3 Get SSP corrected Index as:

Lectures on Stellar Populations Thomas, Maraston and Bender 2003 12 Gyr old, Solar Metallicity SSP Models: At constant Z, when [α/Fe] increase: Mg indices get stronger Fe indices get weaker [MgFe] stays constant

Lectures on Stellar Populations Thomas, Maraston and Bender 2003 comparison to GC data: Data: Puzia et al GCs From model Mgb and Fe52 get Fe and αs abundance  Total Z Brodie and Huchra 1990: metallicity Calibration of MW and M31 GCs

Lectures on Stellar Populations What have we learnt In an SSP each stellar index is weighted with the contribution of the Star to the Total Continuum Flux of the SSP Cool Dwarfs have a high Mg index, but cannot be efficiently used to enhance the SSP Mg index Metallic Line Strenghts are stronger in older and more metal rich stellar populations Balmer Line Strenghts are stronger in younger and more metal poor stellar populations Index – Index Diagrams offer a diagnostic for age AND metallicity Element Abundance Ratios affect the indices in different ways The Optimist’s View: One Balmer Index One Mg Index One Fe Index AGE METALLICITY α/Fe RATIO

Lectures on Stellar Populations But: Tantalo and Chiosi (2004) SSP Models with α enhancement Based on Salasnich et al. α enhanced models + TB 95 response functions Ages depend on abundance pattern As a consequence, Z also does Based on patching literature isochrones + TB 95 response functions Based on isochrones + FCT + TB 95 response functions

Lectures on Stellar Populations Seek better diagnostic for AGE: other Balmer Indices (Hγ, Hδ) unaffected by gas emission Worthey and Ottaviani 1997 For each index 2 definitions: F for wide (40 A), A for narrow (20 A) central bandapasses Models: high sensitivity to AGE (but Hβ is still the more sensitive) Jump from [Fe/H]=-1 to -0.5 due to Variation of HB morphology

Lectures on Stellar Populations New Generation of Models: Thomas,Maraston and Korn 2004 Korn et al. (2005) compute response functions of atmospheres with various (g,Teff) for a wide range of metallicities (1/200 to 3.5 solar). Based on these, TMK re-compute Indices with variable [alpha/Fe] ratios. Contrary to Hβ (?!) higher order Balmer Indices are sensitive to [α/Fe] ratio (at high Z) The pseudocontinua contain Fe lines

Lectures on Stellar Populations Effect on Galaxies AGE Dating When [α/Fe]=0.2 is used the Ages indicated by Hβ and Hγ F become consistent When using solar ratio models high order Balmer lines lead to underestimate the age

Lectures on Stellar Populations New Response Functions: Korn,Maraston,Thomas 2005 Model atmospheres with high resolution for typical MS,TO and RG stars on Isochrones with Z=-2.25 …+0.67 Determine the response function of 21 Lick indices

Lectures on Stellar Populations Korn,Maraston,Thomas 2005 Solid: new response functions Dotted : old response functions Black Dots: GCs data Open Square: Bulge field Grey dots: Es The new models are almost the same As the old. We have much more confidence on the metallicity dependence of the correction for non solar [α/Fe] ratio Still not explored the behaviour along the Isochrone

Lectures on Stellar Populations Puzia et al. 2006: AGES, METALLICITIES and ABUNDANCE RATIOs of a sample of extragalactic GCs Use: [MgFe]’ as total Z indicator Weighted ave of Balmer Lines as AGE indicator and to measure [α/Fe] Quality of the index as age indicator depends on: Mean error of the data Transformation accuracy to the Lick system Error on the original Lick spectra Accuracy of the Lick FF Dynamic range of the index Degeneracy parameter Notice that many GCs fall out of the Grid. This should be further investigated

Lectures on Stellar Populations CAVEATS: BALMER LINE STRENGTHS depend on HB morphology Hβ depends on HB morphology: Models have 10 and 15 Gyr Solid: no mass loss Maraston 2003

Lectures on Stellar Populations CAVEATS: BALMER LINE STRENGTHS depend on HB morphology from Puzia et al 2006: OBSERVED BALMER INDICES OF MW GCs (squares) M31 GCs (inv. Triangles) LMC GCs (triangles) STAR: high Z GCs with blue HB HBR=(B-R)/(B+V+R)

Lectures on Stellar Populations CAVEATS: SPURIOUS CORRELATIONS From Thomas et al. 2005: (SFH of Ellipticals) Monte carlo Simulation: - take indices of one SSP with t=10.7, [Z/H]=0.26,[α/Fe]=0.25 - apply observed errors (gaussian) on the diagnostic indices - derive (t,Z,α/Fe) Error of the procedure can be Quantified into 0.1 dex for metallicity 0.03 for abundance ratio 1.5 Gyr of age ERRORS ON Hβ INDUCE A SPURIOUS ANTICORRELATION OF AGE AND METALLICITY

Lectures on Stellar Populations Spectral Indices Broad Band Colors are affected by the AGE-METALLICITY DEGENERACY Spectral indices have been introduced.

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Lectures on Stellar Populations Spectral Indices Broad Band Colors are affected by the AGE-METALLICITY DEGENERACY Spectral indices have been introduced.

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Presentation on theme: "Lectures on Stellar Populations Spectral Indices Broad Band Colors are affected by the AGE-METALLICITY DEGENERACY Spectral indices have been introduced."— Presentation transcript:

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