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The impact of Gaia on the future of astrophysics Coryn A.L. Bailer-Jones Max-Planck-Institut für Astronomie, Heidelberg.

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Presentation on theme: "The impact of Gaia on the future of astrophysics Coryn A.L. Bailer-Jones Max-Planck-Institut für Astronomie, Heidelberg."— Presentation transcript:

1 The impact of Gaia on the future of astrophysics Coryn A.L. Bailer-Jones Max-Planck-Institut für Astronomie, Heidelberg

2 Some major questions ● Stellar structure, evolution and atmospheres – testing/improving models across whole HRD – calibration of Mass – Luminosity relation ● How and when did the Galaxy form? – age-metallicity-kinematics relation – substructure in disk and halo (mergers, accretion) – age of Galactic components – star formation history, evolution of the IMF

3 Some major questions ● Dark matter – what is its physical nature? does it really exist? – distribution on small scales (< 1 Mpc) – growth of structure in the early universe ● Exoplanetary systems – what variety of systems exist? (statistics, biases) – direct mass determinations (sini ambiguity) – relation to properties of stellar host

4 Entire sky to V=20, 100 times over 5 years radial velocities, photometry ESA mission for 2011 launch Gaia in a nutshell high accuracy astrometry: parallaxes, proper motions 6D phase space survey + physical parameters

5 Gaia capabilities

6 10  as = 10% distances at 10 kpc 10  as/yr = 1 km/s at 20 kpc

7 Distances ● important in every area of astronomy – angular scales length scales proper motions velocities – 3D spatial structure – intrinsic stellar luminosities (HRD, ages) ● all other measures calibrated with parallaxes ● strength of Gaia is accuracy and statistics – 1% distance accuracy at 1kpc for V=15 – 700,000 stars with distance accuracy better than 0.1% – 21 million stars 1% – 220 million stars 10% ● only from space, and only Gaia

8 Distance accuracy to nearby stars GroundGaiaHipparcos

9 The cosmic distance ladder 1 1010 2 10 3 10 4 10 5 10 6 10 7 10 8 10 9 Distance (pc) 1 1010 2 10 3 10 4 10 5 10 6 10 7 10 8 10 9 SIM GAIA HIPPARCOS Ground based Hyades LMC M31 M81 Virgo Coma 61 Cyg GC Brigh st * in Gal. HII regions Glob. clust. Spirals Tully-Fisher Ellip. als SN Cluster of Gal. Proper Motion MS Fitting RR Lyr Novae Cepheids Spectro and photom. parallaxes Trigonometric Parallaxes  < 10%

10 Stellar structure and evolution ● structure models – luminosities (also need A V and T eff ) – helium abundances (not available in spectrum; need accurate luminosities) ● open clusters and SFRs – 70 within 500pc, providing individual distances to 0.5% (<2.5pc at V=15) – accurate ages from position in HRD of MS turn off – Gaia will discover thousands more (from clustering in 6D space, HRD) ● binaries – directly calibrate Mass-Luminosity relationship

11 Galaxy formation ● CDM models – galaxies built up by many small units ● look for evidence of mergers/accretion – in external galaxies – but in more detail in our Galaxy

12 Spatial overdensities in the halo Brown et al. 2005 ● spatial overdensities/streams found – Sagittarius dSph – Canis Major ● but limited discovery space – low contrast – projection effects – streams well-mixed spatially ● can improve with – radial velocities – better identification of tracers ● ultimately need astrometry

13 Substructure fossils in phase space Helmi & de Zeeuw 2000 Initial distribution Final distribution after 12 Gyr convolved with Gaia errors

14 Galactic thin and thick disks ● mass of the disk – determine gravitational potential from stellar motions – dark matter ● formation of disk – monolithic collapse or via accretion of satellites? – is there a smooth age-metallicity-kinematic relation? – phase space measurements to look for substructure – age from WD luminosity function (200,000, precise to <0.5 Gyr)

15 Exosolar planetary systems 47 Ursa Majoris astrometric displacement = 360 as Lattanzi et al. 2000

16 Exosolar planetary systems ● astrometric companion search – = (M p /M s )(a p /d) – no sin i ambiguity in mass ● extensive, unbiased survey – monitor 10 5 stars to 200 pc (V<13) – all stellar types to P ~ 10 years – ~ 5000 new planets expected – orbital solutions for 1000 – 2000 systems – masses to 10 M Earth to 10pc ● transits – Jupiter across Sun ⇒ 0.01 mag photometric ampltiude – expect 6000 detections for 0 – 2 AU orbit around F-K stars

17 Solar system ● Gaia capabilities – all sky complete survey to G=20, to within 40° of Sun (“daytime”) – discovery of 10 5 – 10 6 new objects (cf. 65000 now) – very accurate orbital elements (~30 times better) – multi-band photometry (taxonomy, chemistry) ● main belt asteroids – solar system formation – sizes, albedos, masses (~ 100, cf. 10 now) ● Near-Earth Objects – expect 1600 Earth-crossing (vs. 100 now) ● General Relativity – light bending (Sun: 4 mas at 90°), to 5x10 - 7 – perihelion precession (and solar J 2 )

18 Data reduction principle Scan width: 0.7° Sky scans (highest accuracy along scan)

19 Data processing ● 1 Mb/s for 5 years (~ 100 TB raw) ● complex data treatment – objects mixed up in time and space – astrometry, photometry and spectroscopy – iterative adjustment of parameters for ~100 million stars ● many tasks, e.g. – object matching, attitude modelling, global astrometric processing, binary star analysis, radial velocity determination, photometry, variablity analysis, CCD calibration, object classification, determination of stellar physical parameters ● ~10 21 FLOPS (10 17 FLOPS from 1 PC in 1 year) – 1s per star for all operations would require 30 years ● basic data processing prototype (GDAAS)

20 Timeline and the scientific community ● Fully approved and funded ESA mission – prime contractor selected by end of year – implementation phase starts mid 2006 – launch December 2011 – nominal mission in 2012 – 2016 – data processing complete ca. 2018 ● Scientific community is responsible for the data processing – funding by national agencies – currently setting up the Data Processing and Analysis Consortium – significant commitment, investment and expertise required – but rewards will be extensive

21 Organisation

22 CU8: Astrophysical Parameters ● stellar parameters – T eff, log g, [Fe/H], A V, [  /Fe] – include parallax to derive luminosity; evolutionary model to derive age ● Gaia observes entire sky to V=20 – no prior information; very wide parameter space – need an initial classification (esp. QSO identification) ● many complications – optimal combination of photometry, spectroscopy and astrometry – differing spatial resolutions and flux limits; source variability – parameter degeneracy; problem of “weak” parameters ● solutions – supervised machine learning methods (extensive development required!)

23 Accuracy = 10–25 as @ V=15: ⇒ distances to <1% for 20 million stars ⇒ transverse velocities to 1km/s at 20 kpc All sky survey to V=20 (10 9 stars) 5D phase space (6D to V~17) Physical stellar properties (multiband photometry) Formation and evolution of the Galaxy Stellar structure Exoplanets Solar system Fundamental physics Summary complete, accurate & large number statistics

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