Age and abundance structure of the central sub-kpc of the Milky Way

Similar documents
Micro-lensed dwarf stars in the Galactic Bulge

The chemical evolution of the Galactic Bulge seen through micro-lensing events

Abundance distribution in the Galactic thick disk

Exploring the structure and evolu4on of the Milky Way disk

THE GALACTIC BULGE AND ITS GLOBULAR CLUSTERS: MOS. B. Barbuy

Zoccali et al. 2003, A&A, 399, 931. Overview of (old) Galactic components. bulge, thick disk, metal-weak halo. metallicity & age distribution

Chemical evolution of the Galactic disk using Open Clusters

Galactic Bulge Science

University of Naples Federico II, Academic Year Istituzioni di Astrofisica, read by prof. Massimo Capaccioli. Lecture 16

THE CHEMICAL EVOLUTION OF THE MILKY WAY DISK

Studying stars in M31 GCs using NIRI and GNIRS

The Chemical/Dynamical Evolution of the Galactic Bulge

Chemical evolution of the Galactic bulge as traced by microlensed dwarf and subgiant stars, V. Evidence for a wide age distribution and a complex MDF

arxiv: v1 [astro-ph.ga] 9 Feb 2017

The Star Clusters of the Magellanic Clouds

Spatial distribution of stars in the Milky Way

arxiv: v2 [astro-ph.ga] 10 Jul 2017

Review of the Bulge Stellar Population And Comparison to the Nuclear Bulge

Are open clusters chemically homogeneous? Fan Liu

The Thick Thin Disk and the Thin Thick Disk: a New Paradigm from Gaia

Lecture Five: The Milky Way: Structure

arxiv:astro-ph/ v1 3 Nov 2006

arxiv: v1 [astro-ph.ga] 26 Mar 2018

Review of stellar evolution and color-magnitude diagrams

The Composition of the Old, Metal-Rich Open Cluster, NGC 6791

Following the evolution of the Galactic disc with Open Clusters

Signatures of SN Ia in the galactic thick disk. Observational evidence from alpha elements in 67 dwarf stars in the solar neighbourhood

Overview of Gaia-ESO Survey results based on high-resolution spectra of FGK-type stars Rodolfo Smiljanic! (Gaia-ESO WG11 co-coordinator)

Dust [12.1] Star clusters. Absorb and scatter light Effect strongest in blue, less in red, zero in radio.

The Gaia-ESO Spectroscopic Survey. Survey Co-PIs. Gerry Gilmore (IoA, Cambridge) & Sofia Randich (INAF/Arcetri) >300 CoIs

Our Galaxy. Milky Way Galaxy = Sun + ~100 billion other stars + gas and dust. Held together by gravity! The Milky Way with the Naked Eye

Chemo-dynamical disk modeling. Ivan Minchev Leibniz-Institut fur Astrophysik Potsdam (AIP)

Basics of Galactic chemical evolution

Chemical evolution of the Galactic bulge as traced by microlensed dwarf and subgiant stars,

Lecture 30. The Galactic Center

Galaxies. CESAR s Booklet

Astronomy 114. Lecture 29: Internal Properties of Galaxies. Martin D. Weinberg. UMass/Astronomy Department

Determination of [α/fe] and its Application to SEGUE F/G Stars. Young Sun Lee

Astr 5465 Feb. 5, 2018 Kinematics of Nearby Stars

Properties of the Milky Way stellar disks in the direction of the Draco dsph galaxy.

The Milky Way Galaxy

From theory to observations

The HERMES project. Reconstructing Galaxy Formation. Ken Freeman RSAA, ANU. The metallicity distribution in the Milky Way discs Bologna May 2012

arxiv: v1 [astro-ph.ga] 13 Jun 2016

arxiv:astro-ph/ v1 16 Dec 2006

JINA Observations, Now and in the Near Future

DOES THE MILKY WAY HAVE AN ACCRETED DISK COMPONENT?

GALAXIES 626. The Milky Way II. Chemical evolution:

A HIGH-RESOLUTION SPECTRUM OF THE HIGHLY MAGNIFIED BULGE G DWARF MOA-2006-BLG-099S 1

Globular Clusters in LSB Dwarf Galaxies

White Dwarfs in Clusters

Review of results from the EROS microlensing search for massive compact objects

Tc trends and terrestrial planet formation The case of Zeta Reticuli

Basics of chemical evolution

The Giant Branches of Open and Globular Clusters in the Infrared as Metallicity Indicators: A Comparison with Theory

Thorium (Th) Enrichment in the Milky Way Galaxy

Searching for extrasolar planets using microlensing

The Great Debate: The Size of the Universe (1920)

Chemistry & Dynamics of the Milky Way From Before Hipparcos Until Gaia

Outline. c.f. Zhao et al. 2006, ChJA&A, 6, 265. Stellar Abundance and Galactic Chemical Evolution through LAMOST Spectroscopic Survey

Exploring the stellar population of nearby and high redshift galaxies with ELTs. Marco Gullieuszik INAF - Padova Observatory

Age Dating A SSP. Quick quiz: please write down a 3 sentence explanation of why these plots look like they do.

Oxygen in red giants from near-infrared OH lines: 3D effects and first results from. Puerto de la Cruz, May 14, 2012! Carlos Allende Prieto!

Planets in different environments

The Apache Point Observatory Galactic Evolution Experiment. Ricardo Schiavon

Stellar Populations in the Galaxy

Stellar Systems with HST

An analogy. "Galaxies" can be compared to "cities" What would you like to know about cities? What would you need to be able to answer these questions?

Number of Stars: 100 billion (10 11 ) Mass : 5 x Solar masses. Size of Disk: 100,000 Light Years (30 kpc)

Characterization of the exoplanet host stars. Exoplanets Properties of the host stars. Characterization of the exoplanet host stars

Oxygen in the Early Galaxy: OH Lines as Tracers of Oxygen Abundance in Extremely Metal-Poor Giant Stars

Mapping the oxygen abundance in an elliptical galaxy (NGC 5128)

STELLAR LIFETIMES AND ABUNDANCE GRADIENTS: HINTS FROM CENTRAL STARS OF PLANETARY NEBULAE

Chapter 7: From theory to observations

Synergies between E-ELT and space instrumentation for extrasolar planet science

arxiv: v1 [astro-ph.ga] 20 Jun 2013

1.4 Galaxy Light Distributions

Galac%c Unprecedented Precision (0.01 dex)

Lecture Three: Stellar Populations. Stellar Properties: Stellar Populations = Stars in Galaxies. What defines luminous properties of galaxies

From theory to observations

Age- Abundance Trends in the Solar Neighborhood. Diane Feuillet MPIA April 25, 2017 IAUS 330 Nice, France

Chapter 14 The Milky Way Galaxy

Distance Measuring Techniques and The Milky Way Galaxy

Galaxy Evolution at High Resolution: The New View of the Milky Way's Disc. Jo Bovy (University of Toronto; Canada Research Chair)

Stellar populations in the Milky Way halo

Exoplanet Host Stars

The Besançon Galaxy Model development

Galaxy simulations in the Gaia era. Ivan Minchev Leibniz-Institut fur Astrophysik Potsdam (AIP)

The Galactic Chemical Evolution: an observation overview. Alan Alves Brito Precision Spectroscopy 2016 Porto Alegre, September 20

Review of stellar evolution and color-magnitude diagrams

The structure and formation of the Milky Way disks

arxiv: v3 [astro-ph.sr] 24 Apr 2017

The Milky Way. Overview: Number of Stars Mass Shape Size Age Sun s location. First ideas about MW structure. Wide-angle photo of the Milky Way

telescopes resolve it into many faint (i.e. distant) stars What does it tell us?

View of the Galaxy from within. Lecture 12: Galaxies. Comparison to an external disk galaxy. Where do we lie in our Galaxy?

Three Major Components

Stellar Populations in the Milky Way. Star clusters. Cluster HR diagrams B.J. Mochejska, J. Kaluzny (CAMK), 1m Swope Telescope. Prof Andy Lawrence

arxiv: v2 [astro-ph.ga] 26 Apr 2013

On the relation between stars and their planets

Gaia ITNG2013 School, Tenerife. Ken Freeman, Lecture 2: the thin disk

Transcription:

Age and abundance structure of the central sub-kpc of the Milky Way Thomas Bensby Department of Astronomy and THeoretical Physics Sweden

MBD collaboration (Microlensed Bulge Dwarf) Sofia Feltzing Thomas Bensby Andy Gould Jennifer Johnson Martin Asplund Jorge Melendez Sara Lucatello Lund Univ. Lund Univ. Ohio State Univ., USA Ohio State Univ., USA Mount Stromlo, ANU, Australia Sao Paolo, Brazil INAF, Padova, Italy + MOA and OGLE people

Why dwarf stars? Reliable tracers of the chemical composition of the gas cloud they formed from: Long life times (>10 Gyr) and their atmospheres remain intact. Commonly used in Galactic chemical evolution studies: Edvardsson et al. (1993), Fuhrmann, Reddy, Bensby, and Adibekyan papers,...and many more... Studies of bulge giants and nearby disk dwarf stars showed very different abundance trends. Is this real? Need to compare dwarfs with dwarfs.. All detailed studies based on highresolution spectra of red giants, that can be an issue if they are metal-rich as spectral lines become very strong and numerous It is also possible to estimate stellar ages of individual stars from isochrones. Is the bulge really all old?

Why dwarf stars? Reliable tracers of the chemical composition of the gas cloud they formed from: Long life times (>10 Gyr) and their atmospheres remain intact. Commonly used in Galactic chemical evolution studies: Edvardsson et al. (1993), Fuhrmann, Reddy, Bensby, and Adibekyan papers,...and many more... Studies of bulge giants and nearby disk dwarf stars showed very different abundance trends. Is this real? Need to compare dwarfs with dwarfs.. All detailed studies based on highresolution spectra of red giants, that can be an issue if they are metal-rich as spectral lines become very strong and numerous It is also possible to estimate stellar ages of individual stars from isochrones. Is the bulge really all old? Fuhrmann (1998)

Why dwarf stars? Reliable tracers of the chemical composition of the gas cloud they formed from: Long life times (>10 Gyr) and their atmospheres remain intact. Commonly used in Galactic chemical evolution studies: Edvardsson et al. (1993), Fuhrmann, Reddy, Bensby, and Adibekyan papers,...and many more... Studies of bulge giants and nearby disk dwarf stars showed very different abundance trends. Is this real? Need to compare dwarfs with dwarfs.. All detailed studies based on highresolution spectra of red giants, that can be an issue if they are metal-rich as spectral lines become very strong and numerous It is also possible to estimate stellar ages of individual stars from isochrones. Is the bulge really all old? Fulbright et al. (2007)

Why dwarf stars? Reliable tracers of the chemical composition of the gas cloud they formed from: Long life times (>10 Gyr) and their atmospheres remain intact. Commonly used in Galactic chemical evolution studies: Edvardsson et al. (1993), Fuhrmann, Reddy, Bensby, and Adibekyan papers,...and many more... Studies of bulge giants and nearby disk dwarf stars showed very different abundance trends. Is this real? Need to compare dwarfs with dwarfs.. All detailed studies based on highresolution spectra of red giants, that can be an issue if they are metal-rich as spectral lines become very strong and numerous It is also possible to estimate stellar ages of individual stars from isochrones. Is the bulge really all old? [Fe/H]=0 [Fe/H]=-0.5

Why dwarf stars? Reliable tracers of the chemical composition of the gas cloud they formed from: Long life times (>10 Gyr) and their atmospheres remain intact. Commonly used in Galactic chemical evolution studies: Edvardsson et al. (1993), Fuhrmann, Reddy, Bensby, and Adibekyan papers,...and many more... Studies of bulge giants and nearby disk dwarf stars showed very different abundance trends. Is this real? Need to compare dwarfs with dwarfs.. All detailed studies based on highresolution spectra of red giants, that can be an issue if they are metal-rich as spectral lines become very strong and numerous It is also possible to estimate stellar ages of individual stars from isochrones. Is the bulge really all old? Zoccali et al. (2003) Old turn-off

Dwarf stars in the bulge are faint Dwarf stars in the bulge have V~19-20 Would require around 50 hours to get a good highresolution spectrum with UVES (S/N>50, R>40000) Clarkson et al. (2008)

Nature s magnifying glass A star can brighten by factors of several hundreds during a microlensing event Earth Compact object Lensed background star If the star reaches I~15 a 2 hour exposure with UVES gives S/N>50

OGLE and MOA OGLE-IV detected 2145 bulge microlensing events, and MOA detected 577 bulge microlensing events in 2015 Bulge fields currently monitored by OGLE-IV

91 microlensed bulge dwarfs Positions reflect the areas that are monitored by MOA and OGLE Distributed 2-5 degrees below the plane (or ~150-750 pc below the plane, assuming a distance of 8 kpc)

The metallicity distribution Generalised histogram: each star is represented by a gaussian distribution centred at the determined [Fe/H] with a width represented by the estimated uncertainty. Independent of binning.

Multiple components The 5 gaussian peaks in the b=-5 ARGOS fields from Ness et al. (2013)

Ages and metallicities Metal-rich stars show a wide range of ages with a significant fraction (~50%) being young/ intermediate-age. Metal-poor stars mainly old, around 10-12 Gyr

The old turn-off conspiracy Zoccali et al. (2003) Young and metal-rich stars occupy the same region in the HR diagram as old and metal-poor stars Clarkson et al. (2011) Stacking all stars in the same diagram will produce an apparent old turnoff Bensby et al. (2013, A&A, 549, A147) See also Haywood et al.(2016)

Chromium Background dots (nearby dwarfs from Bensby+2014): Red: older than ~9 Gyr (thick disk) Blue: younger than ~ 7 Gyr (thin disk)

Nickel Background dots (nearby dwarfs from Bensby+2014): Red: older than ~9 Gyr (thick disk) Blue: younger than ~ 7 Gyr (thin disk)

Magnesium Background dots (nearby dwarfs from Bensby+2014): Red: older than ~9 Gyr (thick disk) Blue: younger than ~ 7 Gyr (thin disk)

Calcium Background dots (nearby dwarfs from Bensby+2014): Red: older than ~9 Gyr (thick disk) Blue: younger than ~ 7 Gyr (thin disk)

Titanium Background dots (nearby dwarfs from Bensby+2014): Red: older than ~9 Gyr (thick disk) Blue: younger than ~ 7 Gyr (thin disk)

A shift in the knee A signature of slightly faster enrichment in the Bulge The knee in the bulge [alpha/fe] trends located at ~0.1 dex higher [Fe/H] than in the local thick disk.

Summary Microlensing offers a unique opportunity to study the detailed age and abundance structure of the Milky Way bulge Multiple components in the bulge MDF Wide age distribution Metal-poor mostly old Metal-rich young and old Abundance trends at [Fe/H]<0 very similar to the local thick disk, but slightly shifted to higher [Fe/H] Strong connections between the bulge components and the other Galactic populations. What is the bulge? A region (rather than a population) A conglomerate of Galactic stellar populations... and a bar!

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback