The halo is specially interesting because gravitational potential becomes dominated by the dark matter halo

Similar documents
Astr 598: Astronomy with SDSS. Spring Quarter 2004, University of Washington, Željko Ivezić. Lecture 6: Milky Way Structure I: Thin and Thick Disks

Milky Way s Anisotropy Profile with LAMOST/SDSS and Gaia

Estimating the mass of our Milky Way from the LAMOST Galactic spectroscopic survey

What shall we learn about the Milky Way using Gaia and LSST?

Milky Way S&G Ch 2. Milky Way in near 1 IR H-W Rixhttp://online.kitp.ucsb.edu/online/galarcheo-c15/rix/

Halo Tidal Star Streams with DECAM. Brian Yanny Fermilab. DECam Community Workshop NOAO Tucson Aug

LSST Science. Željko Ivezić, LSST Project Scientist University of Washington

Milky Way s Mass and Stellar Halo Velocity Dispersion Profiles

Hypervelocity Stars. A New Probe for Near-Field Cosmology. Omar Contigiani. Supervisor: Dr. E.M. Rossi. Co-supervisor: Msc. T.

The Milky Way s rotation curve out to 100 kpc and its constraint on the Galactic mass distribution

Renegades in the Solar neighborhood

Abundance distribution in the Galactic thick disk

Modelling the Milky Way: challenges in scientific computing and data analysis. Matthias Steinmetz

Action-based Dynamical Modeling of the Milky Way Disk with Gaia & RAVE

THE MILKY WAY HALO. Wyn Evans Institute of Astronomy, Cambridge. Garching, 23 February 2015

Mapping the Galactic halo with main-sequence and RR Lyrae stars

Observational Cosmology

The Geometry of Sagittarius Stream from PS1 3π RR Lyrae

Overview of Dynamical Modeling. Glenn van de Ven

ASTR 200 : Lecture 22 Structure of our Galaxy

Science Results Enabled by SDSS Astrometric Observations

Phys/Astro 689: Lecture 11. Tidal Debris

JINA Observations, Now and in the Near Future

Exploring the structure and evolu4on of the Milky Way disk

Lecture 29. Our Galaxy: "Milky Way"

distribution of mass! The rotation curve of the Galaxy ! Stellar relaxation time! Virial theorem! Differential rotation of the stars in the disk

Probing the history of star formation in the Local Group using the galactic fossil record

Mario Juric Institute for Advanced Study, Princeton

Fabrizio Nesti. LNGS, July 5 th w/ C.F. Martins, G. Gentile, P. Salucci. Università dell Aquila, Italy. The Dark Matter density. F.

Stellar Dynamics and Structure of Galaxies

Fermilab FERMILAB-Conf-00/339-A January 2001

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

Fabrizio Nesti. Ruđer Boškovic Institute, Zagreb Gran Sasso Science Institute, L Aquila. ULB, Bruxelles, March 7 th 2014

Dark matter annihilation and decay factors in the Milky Way s dwarf spheroidal galaxies

Gaia & Ultra-Cool Dwarfs: a high-denition picture of the Milky Way

Astronomy 330 Lecture 7 24 Sep 2010

Dark Matter Halos of nearby galaxies: The HI probe*

Local Group cosmology with ngcfht

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

Lisa Randall The Spacetime Odyssey in Stockholm

Using ground based data as a precursor for Gaia-based proper motions of satellites

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

Dark Matter Density Function Depending on Gravitational Field as Universal Law - M. Abarca

Probing the Milky Way with LISA: Extracting astrophysics from the compact binary population

DM direct detection predictions from hydrodynamic simulations

Dark matter and galaxy formation

ASTRON 449: Stellar (Galactic) Dynamics. Fall 2014

Galaxy Formation Now and Then

Components of Galaxies: Dark Matter

How Massive is the Milky Way?

Astr 511: Galactic Astronomy. Winter Quarter 2015, University of Washington, Željko Ivezić. Lecture 1:

LAMOST Sky Survey --Site limitations and survey planning

(Present and) Future Surveys for Metal-Poor Stars

Milky Way Satellite Galaxies with DES

The role of radial migration in shaping the stellar populations of spiral galaxies

Phys/Astro 689: Lecture 12. The Problems with Satellite Galaxies

Spatial distribution of stars in the Milky Way

Circular Orbits for m << M; a planet and Star

Today. Gravitational Lenses 11/19/2013. Astronomy Picture of the Day

Dark Matter ASTR 2120 Sarazin. Bullet Cluster of Galaxies - Dark Matter Lab

The Milky Way. 20 March The Shape of the Galaxy Stellar Populations and Motions Stars as a Gas. University of Rochester

Dark Matter & Dark Energy. Astronomy 1101

Collisionless Boltzmann Eq (Vlasov eq)" S+G sec 3.4! Collisionless Boltzmann Eq S&G 3.4!

Modified Gravity (MOG) and Dark Matter: Can Dark Matter be Detected in the Present Universe?

Dark Matter Density Function Depending on Gravitational Field as Universal Law - M. Abarca

Gaia DR2 and/versus RAVE DR5: application for the semi-analytic thin disk model

Formation and growth of galaxies in the young Universe: progress & challenges

Eggen, Lynden Bell, Sandage (1962)

Gaia-LSST Synergy. A. Vallenari. INAF, Padova

The Universe of Galaxies: from large to small. Physics of Galaxies 2012 part 1 introduction

Modelling the Milky Way bar

Correlations between stellar dynamics and metallicity in the discs

The Milky Way Galaxy (ch. 23)

The Hot Gaseous Halos of Spiral Galaxies. Joel Bregman, Matthew Miller, Edmund Hodges Kluck, Michael Anderson, XinyuDai

Extra Gal 9: Photometry & Dynamics

Kinematics of the Solar Neighborhood

arxiv: v1 [astro-ph.ga] 30 Jan 2015

Distinguishing Between Warm and Cold Dark Matter

Visible Matter. References: Ryden, Introduction to Cosmology - Par. 8.1 Liddle, Introduction to Modern Cosmology - Par. 9.1

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

Astronomy 113. Dr. Joseph E. Pesce, Ph.D. Distances & the Milky Way. The Curtis View. Our Galaxy. The Shapley View 3/27/18

Astronomy 113. Dr. Joseph E. Pesce, Ph.D. Dr. Joseph E. Pesce, Ph.D.

Cosmological Puzzles: Dwarf Galaxies and the Local Group

A galaxy is a self-gravitating system composed of an interstellar medium, stars, and dark matter.

The Milky Way Part 3 Stellar kinematics. Physics of Galaxies 2011 part 8

BINDING THEORY. R. Gupta. Guru Nanak Dev Engineering College, Ludhiana, Punjab, India

Problem Set 4 Solutions

Exploring the Structure of the Milky Way with WFIRST

Brief update (3 mins/2 slides) on astrophysics behind final project

Recent Progress in Modeling of Galaxy Formation. Oleg Gnedin (University of Michigan)

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!

The Milky Way Part 2 Stellar kinematics. Physics of Galaxies 2012 part 7

Dark Matter. 4/24: Homework 4 due 4/26: Exam ASTR 333/433. Today. Modified Gravity Theories MOND

Large Synoptic Survey Telescope

Chapter 23: Dark Matter, Dark Energy & Future of the Universe. Galactic rotation curves

Firenze (JPO: 28/07/17) Small Scale Crisis for CDM: Fatal or a Baryon Physics Fix

Einführung in die Astronomie II

The Gaia Mission. Coryn Bailer-Jones Max Planck Institute for Astronomy Heidelberg, Germany. ISYA 2016, Tehran

Introduction to SDSS -instruments, survey strategy, etc

Gaia Revue des Exigences préliminaires 1

Transcription:

Evidence for dark matter in the Milky Way Astr 511: Galactic Astronomy Winter Quarter 2015 University of Washington Željko Ivezić The halo is specially interesting because gravitational potential becomes dominated by the dark matter halo

New Cosmological Puzzles The modern cosmological models can explain all observations, but need to postulate dark matter and dark energy (though gravity model could be wrong, too)

Bovy & Tremaine (2012, ApJ 756, 89) estimated local dark matter density: ρdm = (0.008 ± 0.003) M pc 3 (0.3 ± 0.1 GeV cm 3 ) using disk star kinematics from SDSS A statistically significant dynamical detection of dark matter in the solar neighborhood N.B. 10% effect

The Milky Way is complex and big Only 2.5 deg wide: <1% halo volume We need more data (at least 2 mag deeper than SDSS, and time-resolved) And interesting and informative

Velocity distribution for (nearby) halo stars Kinematics of halo stars based on SDSS-POSS proper motions: velocity ellipsoid is nearly invariant in spherical coordinate system Bond et al. (2010, ApJ, 716, 1) Together with the measurement of stellar number density distribution, this finding encodes information about the gravitational potential - including the dark matter contribution

q=0.64 power-law halo 2 exponential disks

Velocity distribution for (nearby) halo stars Kinematic data constrain dark matter via Jeans equations Kinematics of halo stars based on SDSS-POSS proper motions: velocity ellipsoid is nearly invariant in spherical coordinate system Bond et al. (2010, ApJ, 716, 1) Given stellar distribution from Juric+2008 and stellar kinematics from Bond+2010, we can apply Jeans equations and infer the gravitational potential, and ultimately the distribution of dark matter

N-body model (Governato et al.) Velocity distribution for (nearby) halo stars Kinematic data constrain dark matter via Jeans equations Tests based on a N-body model galaxy (Loebman+2012): Jeans equations recover the known acceleration with a bias below 10%

SDSS az normalized by model az Top: model with DM; bottom: no DM N-body model (Governato et al.) Velocity distribution for (nearby) halo stars Kinematic data constrain dark matter via Jeans equations N-body model galaxy suggests dark matter halo: Tests based on a N-body model galaxy: Jeans equations recover the known acceleration with a bias below 10%

ar with DM az SDSS, halo, total (Loebman et al. 2012) Baryons (SDSS, disk) (Bovy & Rix, 2013) Add DM: Up to 3 times stronger acc. SDSS measured over baryon model DM halo is oblate qpot=0.7±0.1 qrho=0.4±0.1 (Loebman et al. 2014)

ar az with DM baryons dark matter measured dark matter MOND Acceler. due to baryons and measured acc. don t point in the same direction: 1) DM halo can t be spherical 2) MOND does not work Strong constraints because of 2D acceleration measurements

Problems (and long-term solutions): Add DM: ar with DM az The BHB sample from Xue et al. has about 100 stars at the right location. Radial velocity errors are ~2-5 km/s. Proper motion based errors are ~180 km/s (without distance errors). With Gaia: about 2 km/s Need to wait The spherically invariant velocity ellipsoid for halo stars from Bond+10 has σrr = 141 km/s σθθ = 75 km/s σφφ = 85 km/s with ~ 10 km/s errors. Either: 1) this result cannot be extrapolated to the symmetry axis (R=0), 2) or the Milky Way is not axially symmetric

Problems (and possible short-term solutions): az Halo Disk Best-fit model Z - halo and disk stars should feel the same gravitational potential and have same accelerations derived from Jeans equations - but at Z<2 kpc, halo and disk stars differ by a factor of ~2 - this discrepancy could be due to inadequate model for the spatial profile from Juric et al. (2008), or inadequate kinematic model from Bond et al. (2010) (Bovy & Rix results are assumed infallible) - it turns out that the most plausible resolution is a decrease of the axis ratio for halo stars from q=0.64 at Z>6 kpc to q ~ 0.3 at Z=0 - this could be verified with new SDSS-APOGEE data

6D information from LSST: 3D spatial, 2 velocities, [Fe/H]

montage from B. Willman 200 million stars from LSST

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