1 / 26

A New Technique to Measure Δ Y/ Δ Z

A New Technique to Measure Δ Y/ Δ Z. Main collaborators: J. R. de Medeiros (UFRN) M. Catelan (PUC). A. A. R. Valcarce (UFRN). XXXVII SAB meeting Águas de Lindóia, Brazil , Oct 16 th , 2012. Outline. Introduction Determination of Y Theoretical models (PGPUC )

ranae
Télécharger la présentation

A New Technique to Measure Δ Y/ Δ Z

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. A New Technique to Measure ΔY/ΔZ Main collaborators: J. R. de Medeiros (UFRN) M. Catelan (PUC) A. A. R. Valcarce (UFRN) XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  2. Outline • Introduction • Determination of Y • Theoretical models (PGPUC) • Method • Comparison • Application • Summary XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  3. Outline • Introduction • Determination of Y • Theoretical models (PGPUC) • Method • Comparison • Application • Summary XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  4. Introduction The helium-metallicity relation (Y-Z relation) is the keystone to understand the formation and evolution of stars and all the objects related to them. This relation reads: Y = Yp + ΔY/ΔZ x Z The importance of the Y-Z relation: One can know a free parameter (Y) and then assume that the differences between theory and observations are only associated to differences in ages, masses and/or other free parameters. Yp: primordial helium abundance ΔY/ΔZ: helium-to-metal enrichment ratio XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  5. Effects of Y on Evolutionary Tracks Evolutionary tracks are different if they have the same [Fe/H], [α/Fe] and mass, but a different He abundance (Y). Some effects include: • Variations in luminosity (L), effective temperatures (Teff), and surface gravity (g). • Faster evolution for higher Y. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  6. Effects of Y on Evolutionary Tracks Evolutionary tracks are different if they have the same [Fe/H], [α/Fe] and mass, but a different He abundance (Y). Some effects include: • Variations in luminosity (L), effective temperatures (Teff), and surface gravity (g). • Faster evolution for higher Y. The problem is that maybe Y ≠Yp+ ΔY/ΔZ x Z as happens in some globular clusters. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  7. Y ≠Yp + ΔY/ΔZ x Z The CMD of some GCs show they are not simple stellar populations. In some cases implying Y ≠Yp + ΔY/ΔZ x Z . NGC 2808 (Piotto et al. 2007) XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  8. Outline • Introduction • Determination of Y • Theoretical models (PGPUC) • Method • Comparison • Application • Summary XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  9. Theoretical Models PGPUC stellar evolutionary code: updated version of the code of Sweigart (1971 – 1998), that is a highly modified version of the code created by Schwarzschild & Härm (1965). Evolutionary Tracks: Grevesse & Sauval (1998) chemical composition. 7 masses ( 0.5 ≤ M/Mʘ≤ 1.1 ) 7 helium abundances ( 0.230 ≤ Y ≤ 0.370 ) 12 metallicities ( -2.00 ≤ [Fe/H] ≤ 0.75 ) 2 alpha-elements distributions ( [α/Fe]=0.0, 0.3 ) For more information see: Valcarce, Catelan, & Sweigart (2012, ArXiv:astro-ph/1208.5127) XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  10. Method for Determining Y For a star with a given chemical composition only one evolutionary track reproduces Mbol and Teff at the same time. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  11. Method for Determining Y For a star with a given chemical composition only one evolutionary track reproduces Mbol and Teff at the same time. However, if Y is unknown several evolutionary tracks with the same [Fe/H] pass through the same point. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  12. Method for Determining Y For a star with a given chemical composition only one evolutionary track reproduces Mbol and Teff at the same time. However, if Y is unknown several evolutionary tracks with the same [Fe/H] pass through the same point. → Another observable is required to solve this mathematical problem. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  13. Method for Determining Y Since the stellar mass (M) is different for each Y at the same Mbol—Teff, the spectroscopic surface gravity (g) can be used to determine Y. If Y is known, it is straightforward to determine the other stellar properties (Z, M, Age). However, the precision in the measurement of g have to be really high to constrain them. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  14. Method for Determining Y log g = 4.53 ± 0.06 Since the stellar mass (M) is different for each Y at the same Mbol—Teff, the spectroscopic surface gravity (g) can be used to determine Y. If Y is known, it is straightforward to determine the other stellar properties (Z, M, Age). However, the precision in the measurement of g have to be really high to constrain them. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  15. Comparison: Observational Data Because this method require 3 parameters (Mbol, Teff, and log g), we use the observational results listed in Casagrande et al. (2006). Low-mass MS stars • -2.0 ≤ [Fe/H] ≤ +0.4 with σ[Fe/H]≤ ±0.15 dex • 4400 ≤ Teff[K] ≤ 6400 with σTeff≤ ±100 K • 4.1 ≤ log g ≤ 5.0 with σlog g≤ ±0.20 dex XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  16. Comparison: Observational Data Because this method require 3 parameters (Mbol, Teff, and log g), we use the observational results listed in Casagrande et al. (2006). Low-mass MS stars • -2.0 ≤ [Fe/H] ≤ +0.4 with σ[Fe/H]≤ ±0.15 dex • 4400 ≤ Teff[K] ≤ 6400 with σTeff≤ ±100 K • 4.1 ≤ log g ≤ 5.0 with σlog g≤ ±0.20 dex Yp Casagrande et al. (2007) XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  17. Comparison: ΔY/ΔZ from nearby stars Y=0.245 + ΔY/ΔZ x Z with ΔY/ΔZ=2.0 Casagrande et al. (2007) determined Y assuming all stars are 5 Gyr old. Yp If we assume all stars are 5 Gyr old, we also find helium abundances below the primordial value. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  18. Comparison: ΔY/ΔZ from nearby stars Y=0.245 + ΔY/ΔZ x Z with ΔY/ΔZ=2.0 Casagrande et al. (2007) determined Y assuming all stars are 5 Gyr old. Yp t < 13.5 Gyr Interpolated Extrapolated t > 13.5 Gyr However, when we use our method (age is not constant) metal poor stars show more realistic Y values. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  19. Comparison: ΔY/ΔZ from nearby stars Y=0.245 + ΔY/ΔZ x Z with ΔY/ΔZ=2.0 Casagrande et al. (2007) determined Y assuming all stars are 5 Gyr old. Yp t < 13.5 Gyr Interpolated Extrapolated t > 13.5 Gyr Mass Limit ≈ 0.75 Mʘ due to the “classic radius problem” of low mass stars (e.g., Feiden & Chaboyer 2012). XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  20. Outline • Introduction • Determination of Y • Theoretical models (PGPUC) • Method • Comparison • Application • Summary XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  21. Application Baumann et al. (2010) study the lithium abundances in nearby stars with solar properties. • -0.4 ≤ [Fe/H] ≤ +0.3 with σ[Fe/H]≤ ±0.025 dex • 5600 ≤ Teff[K] ≤ 6100 with σTeff≤ ±40 K • 4.0 ≤ log g ≤ 4.6 with σlog g≤ ±0.06 dex They determined stellar masses and ages using the theoretical Teff vs log g diagram together with Y2 isochrones (Y=0.23+0.20xZ, Yi et al. 2001). Baumann et al. (2010) XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  22. Application We use our method (Y ≠ Yp +ΔY/ΔZ x Z) to determine the fundamental properties of the stars of Baumann et al. (2010): Y, Z, M, and age. XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  23. Application When a Y-Z relation is used instead of assuming an unknown Y, there are differences in masses and ages around ≈ 0.02 Mʘ and ≈ 2 Gyr. TW: This work with Y ≠ Yp +ΔY/ΔZ x Z B10: Baumann et al. (2010) with Y = Yp +ΔY/ΔZ x Z XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  24. www2.astro.puc.cl/pgpuc/ XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  25. Outline • Introduction • Determination of Y • Theoretical models (PGPUC) • Method • Testing the Method • Observational Data • ΔY/ΔZ from nearby stars • Summary XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

  26. Summary We present a new method to determine the He abundance in nearby stars using Mbol, Teff, and g, that can be used to determine ΔY/ΔZ. However, this method has mass limit around 0.75 Mʘ. We show that assuming all stars are 5 Gyr old is not a good approximation (specially for metal poor stars), inducing an error Y determination. When a Y-Z relation is assumed instead of a variable Y value, there will be differences of |ΔM|≈0.02 Mʘ and |ΔAge|≈2 Gyr. Finally, we present the PGPUC online database for theoretical models for a wide range of M, Y, and Z (and soon [α/Fe]). www2.astro.puc.cl/pgpuc/ XXXVII SAB meeting Águas de Lindóia, Brazil, Oct 16th, 2012

More Related