Presentation is loading. Please wait.

Presentation is loading. Please wait.

Looking for the siblings of the Sun Borja Anguiano & RAVE collaboration.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Looking for the siblings of the Sun Borja Anguiano & RAVE collaboration."— Presentation transcript:

1 Looking for the siblings of the Sun Borja Anguiano & RAVE collaboration

2 Outline Where was the Sun born ? What we can learn from the chemical homogeneity of the open clusters ?...And from the kinematics/orbits of the “menbers of the family” ? Have they already lost their memories ? And the ages ? A few ideas to look for a needle in a haystack...

3 The Sun in the Galaxy: The travel of our lives ! The Sun is 4.57 ± 0.05 Gyr old (Wasserburg 1995) and it’s situated 8.5 kpc from the center of the Galaxy (IAU 1985) a) Large radial gradient of metallicity in our Galaxy b) The initial dispersion in metallicity of stars born at a common time and a common R is small [Fe/H] = +0.05dex - 0.09dex((R i - R o) /kpc) - 0.048dex(t/10^9 years) The Sun was born in the inner parts of the Galaxy (Ri ~ 6.6 ± 0.9 kpc). Wielen et al. (1996).

4 Stars like the Sun are born in clusters (Lada et al. 1993) How was the star cluster of the Sun ? -Edgeworth-Kuiper belt: nearby encounter with a star in the early history of the solar system (Malhotra 2008) -Well-organized planetary system: the parental cluster cannot be very dense. -Presence of radioactive-isotopes in primitive meteorites, the Sun was polluted by a SN of star about 15-25 solar masses within a distance of 0.02-1.6 pc (Looney et al. 2006). - Star cluster where the Sun was born: M ~ 500-3000 solar masses and radius of 1-3 pc. (Zwart 2009)

5 Where are these stars today ? Dissolution time of a star cluster t ~ 2.3 Myr M^0.6 (Lamers et al. 2005) -The cluster is long gone and the star are spread over the Galaxy- The Sun has been orbiting the GC around 27 times: Galactic jungle -spiral arms, giant molecular clouds, radial mixing, diffusion of stellar orbits...See work of Bland-Hawthorn, Krumholz & Freeman (2009), Zwart (2009) What can RAVE do for theses stars ?

6 From the chemical abundances: Chemical information remains preserved in an open cluster (De Silva, Freeman, Asplund et al. 2007, Sestito et al. 2007)

7 From the kinematics: The orbital velocity is much higher than the velocity dispersion of the stars in the parental cluster, therefore the members are not very far from the orbit of the Sun but they could be at different locations along this orbit. Can we use the preservation of the phase space and the angular momentun to find the solar siblings ? Helmi et al. 1999

8 Strategy: From RAVE (C. Boeche’s abundances): S/N > 80 [Fe/H] ± 0.2 dex [Si/H] ± 0.2 dex [Mg/H] ± 0.3 dex [Ti/H] ± 0.3 dex [Al/H] ± 0.2 dex 689 stars were selected (first estimate of stellar parameters, accurate RV, proper motions, distances) Accurate individual abundances and ages are needed !!!

9 Follow-up observations Work in progrees: Spectral range, site, telescope, instrument, strategy to get the abundances and ages...etc. Conclusion Identify the family of the Sun could allow us to understand better the dinamical processes in the Galaxy, the evaporation of open clusters and our place in the Milky Way.

Download ppt "Looking for the siblings of the Sun Borja Anguiano & RAVE collaboration."

Similar presentations

Astro1010-lee.com UVU Survey of Astronomy Chapter 21 Our Milky Way.

Astro1010-lee.com UVU Survey of Astronomy Chapter 21 Our Milky Way.
Infrared Space Astrometry mission for the Galactic Bulge

Infrared Space Astrometry mission for the Galactic Bulge
An Abundance Spread in the Bootes I Dwarf Spheroidal Galaxy? John E. Norris The Australian National University Gerard Gilmore University of Cambridge R.F.G.

An Abundance Spread in the Bootes I Dwarf Spheroidal Galaxy? John E. Norris The Australian National University Gerard Gilmore University of Cambridge R.F.G.
The Age-Metallicity-Velocity relation in the nearby disk Borja Anguiano Astrophysikalisches Institut Potsdam (AIP) K. Freeman (ANU), E. Wylie de Boer (ANU),

The Age-Metallicity-Velocity relation in the nearby disk Borja Anguiano Astrophysikalisches Institut Potsdam (AIP) K. Freeman (ANU), E. Wylie de Boer (ANU),
Martin Asplund Galactic archeology & planet formation.

Martin Asplund Galactic archeology & planet formation.
Earth in Space Notes Part 1. Our Solar System Objects in our solar system move in predictable patterns. The predictable movement of these objects are.

Earth in Space Notes Part 1. Our Solar System Objects in our solar system move in predictable patterns. The predictable movement of these objects are.
Dissolving globular clusters: the fate of M 12 Work in collaboration with F. Paresce (INAF) and L. Pulone (Obs. Rome)

Dissolving globular clusters: the fate of M 12 Work in collaboration with F. Paresce (INAF) and L. Pulone (Obs. Rome)
The origin of the Solar System. Small planets beyond Pluto – Sedna, ~1,300 – 1750 km dia.

The origin of the Solar System. Small planets beyond Pluto – Sedna, ~1,300 – 1750 km dia.
Chemical Signatures of the Smallest Galaxies Torgny Karlsson SIfA, School of Physics, The University of Sydney Collaborators: Joss Bland-Hawthorn and Ralph.

Chemical Signatures of the Smallest Galaxies Torgny Karlsson SIfA, School of Physics, The University of Sydney Collaborators: Joss Bland-Hawthorn and Ralph.
The Milky Way PHYS390 Astrophysics Professor Lee Carkner Lecture 19.

The Milky Way PHYS390 Astrophysics Professor Lee Carkner Lecture 19.
Spatial Structure Evolution of Open Star Clusters W. P. Chen and J. W. Chen Graduate Institute of Astronomy National Central University IAU-APRM2002.7.03.

Spatial Structure Evolution of Open Star Clusters W. P. Chen and J. W. Chen Graduate Institute of Astronomy National Central University IAU-APRM
The Milky Way Galaxy James Binney Oxford University.

The Milky Way Galaxy James Binney Oxford University.
Compilation of stellar fundamental parameters from literature : high quality observations + primary methods Calibration stars for astrophysical parametrization.

Compilation of stellar fundamental parameters from literature : high quality observations + primary methods Calibration stars for astrophysical parametrization.
Distances to PNe using angular expansion parallax Lizette Guzman-Ramirez (JBCA, University of Manchester) Yolanda Gomez and Laurent Loinard (CRyA, UNAM,

Distances to PNe using angular expansion parallax Lizette Guzman-Ramirez (JBCA, University of Manchester) Yolanda Gomez and Laurent Loinard (CRyA, UNAM,
Properties of Main Sequence Stars Masses Luminosities Lifetimes Distribution.

Properties of Main Sequence Stars Masses Luminosities Lifetimes Distribution.
A Galactic halo road map The halo stars : where, whither, whence? Chris Thom, Jyrki Hänninen, Johan Holmberg, Chris Flynn Tuorla Observatory Swinburne.

A Galactic halo road map The halo stars : where, whither, whence? Chris Thom, Jyrki Hänninen, Johan Holmberg, Chris Flynn Tuorla Observatory Swinburne.
Galaxy Formation and Evolution Galactic Archaeology Chris Brook Modulo 15 Room 509

Galaxy Formation and Evolution Galactic Archaeology Chris Brook Modulo 15 Room 509
„We are not talking about cosmology...“ (A. Sozzetti)

„We are not talking about cosmology...“ (A. Sozzetti)
Levels of organization: Stellar Systems Stellar Clusters Galaxies Galaxy Clusters Galaxy Superclusters The Universe Everyone should know where they live:

Levels of organization: Stellar Systems Stellar Clusters Galaxies Galaxy Clusters Galaxy Superclusters The Universe Everyone should know where they live:
Stellar orbits change through interactions with inhomogeneities of gravitational potential (molecular clouds, spiral arms, bar) Resonant interactions.

Stellar orbits change through interactions with inhomogeneities of gravitational potential (molecular clouds, spiral arms, bar) Resonant interactions.

Similar presentations

Ads by Google