1 / 19

C. Jordi, E. Solano Universitat de Barcelona LAEFF, Madrid

Progress report on the determination of absolute magnitudes using Str ömgren photometry. C. Jordi, E. Solano Universitat de Barcelona LAEFF, Madrid. COROT week 9 : Dec -200 5. Contents of COROTSKY: seismology programme. Stars brighter than V=9, centre & anticentre directions.

corazon-soria
Télécharger la présentation

C. Jordi, E. Solano Universitat de Barcelona LAEFF, Madrid

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. Progress report on the determination of absolute magnitudes using Strömgren photometry. C. Jordi, E. Solano Universitat de Barcelona LAEFF, Madrid COROT week 9: Dec-2005

  2. Contents of COROTSKY: seismology programme • Stars brighter than V=9, centre & anticentre directions. • 12000 stars. 6820 stars later than A5. • Hierarchical criteria for assigning Mv to a target. •  The criteria was reviewed in COROT week 7 (see Jordi, • Solano & Ribas). •  Already adopted in COROTSKY (see Charpinet’s • presentation in CW8.

  3. (5) Absolute magnitude from Strömgren / Physpar • “Stars with Strömgren photometry in the Physpar windows not having / < 0.1”. • 12 stars of “region1” (O-B) • 3 stars of “region 2” (A0-A2) • 249 stars of “region 3” (late A) post-Hipp. calib (CW7) Mv = 1.88 + 5.2 (b-y) o– 9.1co++ 4.9 mo + 2.7 10-6 vsini2 • 278 stars of “region 4” (F0-G2) post-Hipp. calib (CW7) • Mv = Mv(ZAMS,) - 0.13 + 1.57 b- (8.9+29.6 ) co+ 0.22 [Fe/H] • Stars of “region 5” (from G2) PENDING • 50 stars of “regions 6-8” (B0-G5 supergiants)

  4. G2-K type stars: Mv calibration

  5. Complete uvby- photometry in Hauch & Mermilliod (1998) • Classified as “region 5” with PHYSPAR • V in Hipparcos and Hauck & Mermilliod (1998) in agreement • At least 2 measurements in Hauck & Mermilliod (1998) • Spectral type in Hipparcos in agreement with photometry • Not anomalous location in colour-colour diagrams • Not supergiants according to photometry • Not luminosity classes I & II according to spectral type in Hipparcos • Not peculiar, variable or belonging in multiple systems (HIP flags) • Not variable or joint photometry in Hauck & Mermilliod (1998) • Not variable or belonging in multiple systems according to SIMBAD 303 stars: 272 with /<0.15 104 with /<0.1 Definition of a well-controlled stellar sample

  6. How do the pre-Hipparcos calibrations behave?

  7. A trend with metallicity A slight trend with evolution Olsen(1984)

  8. What’s happening here? COROTSKY

  9. Let’s see an example • HD46241. Δ(Mv)=-6.809. Classified by Physpar as K0V. • π : 6.3 • σ(π)/ π: 0.149  d= 159 pc.  Av = 0 • V= 5.83  Mv(π) = -0.18 •  It cannot be a MS star

  10. What’s happening here? COROTSKY T T T T T t • GKM giants have Mv in the range [0.0, -0.5] • GKM MS have Mv > 5 • Stars having ΔMv < -5 are giants wrongly classified.

  11. Why so many giants? COROTSKY T T T T T t • GKM Main Sequence stars with V < 9.5 are nearby stars  they have good parallaxes  classified in group (2): σ(π)/π<0.1 • Stars with V < 9.5 not having good parallaxes must be far  they must be giants.

  12. Building the new calibration ...

  13. largest dependency

  14. Same approach as for F0-G2 calibration 1) stars with / < 5 % (104 stars, small bias, unreddened) least-squares fit with 3-sigma clipping Mv()-Mv(ZAMS, (b-y) o)= 0.238–[ 5.49 + 18.89(b-y)o]co 2) stars with / < 15 % (272 stars, unreddened) least-squares fit with 3-sigma clipping Mv()- Mv = +0.08 – 6.78 mo

  15. The new calibration ... Mv = Mv(ZAMS,) + 0.238–[ 5.49 + 18.89(b-y)o]co– 6.78 mo ± 0.018 0.587.36 0.40 Valid for -0.10 < co< 0.25 = 0.11 mag -0.05 < mo< 0.11 0.36 < (b-y)o< 0.60

  16. =0.40 =0.28 Trends have been removed COROTSKY 24 stars; /<6%

  17. Conclusions • A new Strömgren calibration has been derived for the G Main Sequence stars. • Both systematic and random errors have been reduced. • 249 late-A + 278 F0-G2 + 30 G2-K0 MS stars with Mv derived from Strömgren photometry using post-Hipparcos calibrations ready to be delivered to COROTSKY. • … BUT still too many stars without information on Mv… • New method: Spectral type & luminosity: σ(Mv) = 1 subtype • - SIMBAD has been explored but VizieR has not. • - To explore all the catalogues contained in VizieR using VO-like tools (e.g. vizquery).

More Related