Surveys and Catalogs Summary: What is a survey? What surveys can do? Survey keywords (completeness, area, mag.limit, …) Type of surveys Survey among the.

Slides:

Advertisements

Similar presentations

Astronomical Solutions to Galactic Dark Matter Will Sutherland Institute of Astronomy, Cambridge.

Advertisements

General Astrophysics with TPF-C David Spergel Princeton.

P.Tisserand Rencontres du Vietnam Final results on galactic dark matter from the EROS-2 microlensing survey ~ images processed - 55 million.

HIGH PROPER MOTION WHITE DWARF CANDIDATES GSCII Annual Meeting October CBBS, Stevensville (MD) by Daniela Carollo Osservatorio Astronomico.

Our target sample was culled from the 2MASS and DENIS near-infrared sky surveys and consists of objects spectroscopically confirmed to be L dwarfs together.

N EW ULTRA COLD DWARF BINARIES New discoveries and follow up observations University of Hertfordshire Joana Gomes.

Detection and Photometric Monitoring of QSOs and AGN with COROT J. Surdej, J.Poels, J.-F. Claeskens, E. Gosset Institut d’Astrophysique et de Géophysique,

Galaxy Formation and Evolution Open Problems Alessandro Spagna Osservatorio Astronomico di Torino Torino, 18 Febbraio 2002.

Charles Hakes Fort Lewis College1. Charles Hakes Fort Lewis College2.

Optimal Photometry of Faint Galaxies Kenneth M. Lanzetta Stony Brook University.

John Salzer, Nyla Tresser, Samantha Stevenson & Hart Webb (Wesleyan University) Jessica Rosenberg (Harvard/Smithsonian CfA) Optical Properties of the HI-selected.

15 The Milky Way More than just a candy bar.. 15.

SLAC, 7 October Multifrequency Strategies for the Identification of Gamma-Ray Sources Marcus Ziegler Santa Cruz Institute for Particle Physics Gamma-ray.

The Mass of the Galaxy We can use the orbital velocity to deduce the mass of the Galaxy (interior to our orbit): v orb 2 =GM/R. This comes out about 10.

The Transient Universe: AY 250 Spring 2007 Existing Transient Surveys: Optical I: Big Apertures Geoff Bower.

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.

Statistical Properties of Radio Galaxies in the local Universe Yen-Ting Lin Princeton University Pontificia Universidad Católica de Chile Yue Shen, Michael.

“ Testing the predictive power of semi-analytic models using the Sloan Digital Sky Survey” Juan Esteban González Birmingham, 24/06/08 Collaborators: Cedric.

Distances. Parallax Near objects appear to move more than far objects against a distant horizon. Trigonometric parallax is used to measure distance to.

Dusty star formation at high redshift Chris Willott, HIA/NRC 1. Introductory cosmology 2. Obscured galaxy formation: the view with current facilities,

9B The Milky Way Our Galactic Home. 9B 9B Goals Structure of our Galaxy. Its size and shape. How do stars and things move through it? Mass and Dark Matter.

Galactic Stellar Population Structure and kinematics Alessandro Spagna Osservatorio Astronomico di Torino 26 Febbraio 2002.

Distance Determination of the Hubble Constant H o by the use of Parallax and Cepheid Variable Stars presented by Michael McElwain and G. Richard Murphy.

Overview of Astronomy AST 200. Astronomy Nature designs the Experiment Nature designs the Experiment Tools Tools 1) Imaging 2) Spectroscopy 3) Computational.

Dark Matters in Torino - Villa Gualino, February 21, 2000 Baryonic Dark Matter: Search for Ancient Cool White Dwarfs in the Galactic Halo Daniela Carollo,

Luminosity and Mass functions in spectroscopically-selected groups at z~0.5 George Hau, Durham University Dave Wilman (MPE) Mike Balogh (Waterloo) Richard.

Molecular Gas and Dust in SMGs in COSMOS Left panel is the COSMOS field with overlays of single-dish mm surveys. Right panel is a 0.3 sq degree map at.

A spectroscopic survey of the 3CR sample of radio galaxies Authors: Sara Buttiglione (SISSA - Trieste), Alessandro Capetti (INAF – Osservatorio Astronomico.

RADIO OBSERVATIONS IN VVDS FIELD : PAST - PRESENT - FUTURE P.Ciliegi(OABo), Marco Bondi (IRA) G. Zamorani(OABo), S. Bardelli (OABo) + VVDS-VLA collaboration.

Astronomical Surveys Matthew Colless Observational Techniques Workshop April 2001.

Introduction to the modern observational cosmology Introduction/Overview.

The 6dF Galaxy Survey Design and Goals Matthew Colless The 6dFGS Workshop AAO, Sydney, May 2002.

Prospects for observing quasar jets with the Space Interferometry Mission Ann E. Wehrle Space Science Institute, La Canada Flintridge, CA, and Boulder,

A STEP Expected Yield of Planets … Survey strategy The CoRoTlux Code Understanding transit survey results Fressin, Guillot, Morello, Pont.

MMT Science Symposium1 “false-color” keV X-ray image of the Bootes field Thousands of AGNs in the 9.3 square degree Bootes field * X-ray and infrared.

Wide Field Astronomy from Space Steven Beckwith Space Telescope Science Institute January 9, 2002.

Large surveys and estimation of interstellar extinction Oleg Malkov Institute of Astronomy, Moscow Moscow, Apr 10-11, 2006.

The infrared extinction law in various interstellar environments 1 Shu Wang 11, 30, 2012 Beijing Normal University mail.bnu.edu.cn.

Luminosity Functions from the 6dFGS Heath Jones ANU/AAO.

Astronomy 1143 – Spring 2014 Lecture 22 The Nature of Dark Matter: MACHOs and WIMPs.

Cosmology and extragalactic astronomy Mat Page Mullard Space Science Lab, UCL 5. The cosmic distance ladder.

Galaxies with Active Nuclei Chapter 14:. Active Galaxies Galaxies with extremely violent energy release in their nuclei (pl. of nucleus).  “active galactic.

ALMA Science Examples Min S. Yun (UMass/ANASAC). ALMA Science Requirements  High Fidelity Imaging  Precise Imaging at 0.1” Resolution  Routine Sub-mJy.

Major dry-merger rate and extremely massive major dry-mergers of BCGs Deng Zugan June 31st Taiwan.

Astrophysics from Space Lecture 6: Supermassive black holes Prof. Dr. M. Baes (UGent) Prof. Dr. C. Waelkens (KUL) Academic year

1 Stellar Properties Basic Data Mass and Radius Spectral Classification Photometric Systems.

The Milky Way Galaxy. Sky Maps in Different Bands.

Galactic coordinates in celestial equator plane NCP in galactic plane

MGL/OATo 7th GSC2 Meeting, Barolo (I), 22 Oct 2001 The GSC2.2 Catalog: Global Properties Mario G. Lattanzi Osservatorio Astronomico di Torino.

(there’s no place like home) The Milky Way Galaxy.

Copyright © 2010 Pearson Education, Inc. Clicker Questions Chapter 14 The Milky Way Galaxy.

Stellar population Studies with LAMOST - Chen Bing - Contents Contents Galactic structure & Evolution Galactic structure & Evolution Related Projects Related.

Galactic studies with GSC-II GSC-II Annual Meeting Barolo, Italy, October 2001 Alessandro Spagna Osservatorio Astronomico di Torino.

The vertical structure of the Galactic Halo Carla Cacciari, Angela Bragaglia - INAF OA Bologna Tom Kinman - NOAO Alberto Buzzoni - INAF TNG Alessandro.

FIRST LIGHT A selection of future facilities relevant to the formation and evolution of galaxies Wavelength Sensitivity Spatial resolution.

The High Redshift Universe Next Door

Milky Way: Galactic Structure and Dynamics Milky Way has spiral structure Galactic Bulge surrounds the Center Powerful radio source Sagittarius A at Center.

Pisa, 4 May 2009 Alessandro Spagna A new kinematic survey (from GSC-II and SDSS-DR7) to study the stellar populations of the Milky Way Alessandro Spagna.

EXPLORE/OC: Photometry Results for the Open Cluster NGC 2660 K. von Braun (Carnegie/DTM), B. L. Lee (Toronto), S. Seager (Carnegie/DTM), H. K. C. Yee (Toronto),

LUMINOUS MATTER  luminous = »The matter that astronomers see in the Universe (stars, dust clouds, etc.) makes up less than 1/2 of one percent of.

“Globular” Clusters: M15: A globular cluster containing about 1 million (old) stars. distance = 10,000 pc radius  25 pc “turn-off age”  12 billion years.

Color Magnitude Diagram VG. So we want a color magnitude diagram for AGN so that by looking at the color of an AGN we can get its luminosity –But AGN.

Galaxy Evolution and WFMOS

Modern cosmology 1: The Hubble Constant

© 2017 Pearson Education, Inc.

The Milky Way Our Galactic Home.

RR Lyrae variable stars

The Milky Way Our Galactic Home.

Presentation transcript:

Surveys and Catalogs Summary: What is a survey? What surveys can do? Survey keywords (completeness, area, mag.limit, …) Type of surveys Survey among the surveys Data Processing Data Storage and access Alessandro Spagna & Richard L. Smart INAF - Osservatorio Astronomico di Torino Torino, 5 febbraio 2002

What is a survey? “A survey is a large, systematic assemblage of data for which some one else will get more glory than the people who did the assembling and systematizing.” (Panel discussion of IAU Symposium n.179 (1996) on New Horizons from Multi-Wavelenght sky surveys)

What surveys can do? Images of celestial objects; sky Maps and Atlas (DSS) Generate Catalogs (reference systems, …, ) Discovery of “rare” objects (WDs, subdwarfs, extra-solar planets,...) Detection of rare events (SN, microlensing, …) Monitor of variable objects (AGN, variable stars, …) Multi-wavelengths cross identification (   X  opt.-IR  Radio ) Selection of targets for spectroscopic follow up (efficient use of large and expensive telescopes) Studies based on large and homogeneous statistical sample (large scale structure of the Universe, galaxy evolution, galaxy clusters, Galactic structure, stellar populations)

What surveys can do? Cent. II B.C, Tolomeus’s Almagesto. Position and magnitude of 1080 bright stars, based on the 850 stars listed by Ipparcus. June 2001: GSC 2.2, position and magnitude of 455 million stars and galaxies, complete down to R<18.5 and B J < 19.5.

What surveys can do? Hertzsprung-Russell (M V, B-V) diagram for the single stars from the Hipparcos Catalogue with relative distance precision sigma_pi/pi < 0.1 and sigma_(B-V) less than or equal to mag. Colours indicate number of stars in a cell of 0.01 mag in (B-V) and 0.05 mag in V magnitude (M_V). 803 refereed papers since 1997 which mention Hipparcos measurements (309 in the title).

What surveys can do? GSC 2.2 optical counterparts in M45 (B<19.5 or R<18.5) 2Mass NIR counterparts in M45 (J<17 or H<16 or K<15)

What surveys can do?

Microlensing results ~20% of the galactic halo is made of compact objects of ~ 0.5 M  MACHO: 11.9 million stars toward the LMC observed for 5.7 yr  events  8%-50% (C.L. 95%) of halo made of M  compact objects. EROS-2: 17.5 million stars toward LMC for 2 yr  2 events (+2 events from EROS-1)  less that 40% (C.L. 95%) of standard halo made of objects < 1 M  Candidate MACHOs: Late M stars, Brown Dwarfs, planets Primordial Black Holes Ancient Cool White Dwarfs

What surveys can do? Count the objects! Fundamental Equation of the Stellar Statistics (Integral Fredholm’s equation of the first kind). Distance Modulus    (M)=Luminosity function D(x,y,z)=density distribution

What surveys can do? NGP Starcounts (i.e. n.ro of stars as a function of the magnitude, color & l,b) depends directly on the properties of the galactic components. The properties of the galactic components (their spatial structure, kinematics, metallicity, LF) constrain the formation and evolution processes of the Galaxy.

What surveys can do? Left panel: SDSS galaxy counts (dots). Solid line (r<16) shows the m distribution expected for a homogeneous galaxy distribution in an “Euclidean” universe. Crosses indicate the starcounts. Right panel: galaxy counts normalized to the Euclidean distribution compared with 3 different cosmological models. (Yasuda et al, 2001, AJ)

Survey keywords spectral range area coverage magnitude limit, sensitivity accuracy level, spectral resolution angular resolution n.ro of objects and completeness

Survey keywords Spectral coverage 1-4  m. Stars - low extinction  m Stars - strong extinction 12, 60,100  m. Dust termal emission 7-10  m. Red giants, PNs, YSOs, clouds 0.25,0.75,1.5 keV Hot gas - strong extinction >300 MeV Diffuse cosmic Rays, Pulsars H2 emission from Molecular clouds GHz. Hot gas, H-II regions 21cm from H clouds 408 MHz synchrotron radiation

Survey keywords Area and Magnitude limit

DSS-2. Magnitude limit R=20.5 Telescope D=1.2m, Exp.Time=60min, DQE=2% HDF (HST). Magnitude limit, I=30 Telescope D=2.5m, Exp.Time=10 days, DQE=30-40% (WFPC2)

Survey keywords Spatial resolution 1 arcsec pixel: (DSS2, 2MASS) 0.05 arcsec pixel HST-WFPC2

Survey keywords Completeness and Selection criteria Types of surveys: Selective surveys. For examples, stellar samples selected on the basis of the chemical or kinematic properties (e.g. low metallicity and high proper motion stars  Pop. II halo stars. Warning: “biased” results) Surveys with tracers. High luminosity objects which can be observed up to great distances, easy to identify and to measure their distance (e.g. globular clusters, giants, variable RR Lyrae, … ). It is assumed that tracers are representative of the whole population. In situ surveys. These measure directly the bulk of the objects which constitute the target populations (e.g. dwarfs of the galactic Pop.I and Pop.II). These should guarantee “unbiased” results if systematic effects due to the magnitude threshold, photometric accuracy, angular resolution, etc. are properly taken into account.

Correction of selection effects Malmquist bias For magnitude-limited surveys the volume within we can see the most luminous objects is larger to than that within which we can see the faintest ones  luminous objects are over-represented  The measured is brighter than the true mean of the population.

Correction of selection effects Lutz-Kelker bias Magnitude-limited surveys contain a greater number of distant stars than nearby stars. Thus, because of the measure error, , the observed parallax is - on average - higher than its true value  distance underestimation  luminosity underestimation  = 1/d N(  ) observed true 

Survey keywords Accuracy level Trigonometric distance Photometric distance Example:  =0.2 mag   d /d = 0.10 Examples:  =1 mas, d=1 kpc   d /d = 1  =10  as, d=10 kpc   d /d = 0.10

Survey keywords Accuracy level

Survey among Surveys (Stellar) Surveys: Astrometric surveys  Positions, Proper motions, Parallaxes (Hipparcos/Tycho, DIVA, GAIA, PPM*, NPM/SPM*, GSC-2*, 2MASS*, …) [*=no parallaxes] Photometric surveys  UV, Optical, IR photometry of stars/galaxies (EIS, 2MASS, DENIS, SDSS, GSC2, NPM/SPM, GAIA, …) Spectroscopic surveys  stars (spectral classification, radial velocity, metallicity), galaxies/QSO (redshift) (CfA RS, SDSS, ESO Slice RS, 2dF, GAIA, …)