Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Milky-Way spiral arm tracers to the actual pattern D. Russeil LAM, Marseille, France.

Published byMorgan Henry Modified over 8 years ago

Similar presentations

Presentation on theme: "The Milky-Way spiral arm tracers to the actual pattern D. Russeil LAM, Marseille, France."— Presentation transcript:

1 The Milky-Way spiral arm tracers to the actual pattern D. Russeil LAM, Marseille, France

2 What are the best spiral arm tracers? Examples: M31, M83, M51

3 Visible stars UV Young stars (OB) Near-IR old stars FIR dust COHI M31

4 M51 2MASS J,H,K VisibleUV (GALEX) NIR spitzer (four band composite) FIR Herschel (70,100,160 m m) HaHa

5 H  – R image UV image (GALEX)‏M83 Spiral arms = overdensity of gas (ionised + molecular), stars (especially OB stars) and dust

6 We use the same tracers as external galaxies The spiral structure: traced by the most massive clouds and brightest HII regions e.g. Baade (1963), Rumstey and Kaufman (1983), Boulanger et al. (1981) Structure: distorted, spurs, bridges, arm splitting... e.g. Kennicutt (1981) Problem Problem: we are inside the Galaxy !!!! - Information along the line of sight is superimposed - Distance ambiguity problem (inner Galaxy)‏ The structure of our Galaxy

7 AAO/UKST H  Survey l = 290° ; b = 0° Georgelin et al., 2000 Marseille H  Survey (Scanning PF interferometer) Vlsr=20 kms -1 Vlsr= -25 kms -1 d ~ 2.7 kpc d ~ 8 kpc Parker et al., 1999 Kinematic information

8 Distance Determination Stellar distance – Distance uncertainties on individual star:~25% (e.g. Humphreys, 1976; Conti and Vacca, 1980; Brand and Wouterloot, 1988; Reed, 1996) ● Spectral type determination ● Mv - Spectral type relationship ● HII regions: identification of exciting stars – Interstellar Extinction => Local structure (< 6 kpc ) Identification of the exciting star(s): UBV photometry + spectro. Kinematic distance Systemic velocity + choice of a rotation curve Circular Velocity departures Near/far ambiguity Brand & Blitz (1993) Rotation curve Multiwavelenght information: H , radio recomb., Molecular, HI, Absorbtion lines Solar parameters: R 0, q 0

9 Kinematic information: velocity departures Spiral arm density wave streaming motion (e.g. Burton, 1973) Typical values: 10 – 40 km/s Brand & Blitz 1993 Russeil et al. 2003 => velocity departure corrected if stellar distance known !! McClure-Griffiths et al. 2007 HI Terminal velocity

10 I: Distribution of stellar tracers OB stars, young clusters, HII regions HII regions (Crampton & Georgelin 1975) OB associations (Mel’nik & Efremov 1995)

11 Dias & Lépine, 2005 Open Clusters in the Solar neighborhood Importance of the cluster age: only the youngest are still located in the arms Perseus arm Sagittarius arm Local (Orion) arm

12 II: Adding velocity information (e.g. Mezger 1970, Downes 1980) Radio lines => probing (almost) the whole galactic plane Recomb. lines (H109 , H110  ) Abs. lines ( H 2 CO, OH …) Molecular lines (CO) Caswell & Haynes 1987 HII regions (radio data) Mol. clouds Cohen et al. 1985

13 Solomon & Rivolo, 1989 10 4 < M < 5 10 6 Msun Molecular clouds

14 III: Star-forming complexes distribution Method/strategy (Bok, 1971; Georgelin and Georgelin, 1976) Goal: reduce spatial and kinematic spread of objects belonging to the same complex. Kinematic + Multiwavelength information: Grouping young objects into complexes Determination of the systemic velocity (taking into account internal motions …) Determination of the kinematic distance solving the distance ambiguity problem Determination of the stellar distance

15 The spiral structure 1': Norma-Cygnus arm (or external arm) 2': Norma-Perseus arm 1: Sagittarius-Carina arm 2: Scutum- crux arm Symbole size -> excitation parameter U (Russeil 2007) U > 70 pc/cm 2 Fit weighting: excitation parameter

16 Distance Determination « New methods » Maser parallaxeStellar distance IR-NIR Stellar parallaxe ?? e.g. Hanson et al. 1996, 2005, Figer et al. 1997 Spectral classification ~2.12 m m, ~8000 A Classification not easy e.g. Xu et al. 2008, Zhang et al. 2008, 2009 VERA project (e.g. Honna et al. 2005, 2007) Very good distance accuracy Only few (very close) OB stars observed with Hypparcos GAIA: capability to observe/classify OB stars ??

17 Hou et al. 2009 Updated view of the spiral arms (including the most recent data): - Molecular clouds + HII regions - dkin: ambiguity distance solving (e.g. Kolpack et al. 2003, Watson et al. 2003, Sewilo et al. 2004, Busfield et al. 2006, Anderson & Bania 2009) - distance: stellar distance + maser parallaxe (e.g. Xu et al. 2008, Zhang et al. 2008) - Fit weighting: Exc. param. and Mol. Mass The spiral structure

18 FIR emission (Herschel- HiGal) a good ‏spiral arm tracer! Herschel Hi-GAL Survey: P.I.: S. Molinari (INAF, Roma, Italy) Survey of the Galactic plane: -70°< l<70° ; -1°<b<+1° Wavelenghts: 70, 100, 250, 350 and 500 m m

19 The filamentary structure of the cold ISM First results from Herschel-Hi-GAL survey (Molinari et al. 2010)

20 The filamentary structure of the cold ISM First results from Herschel-Hi-GAL survey GRS 13CO isocontours (Jackson et al. 2006)

21 The filamentary structure of the cold ISM First results from Herschel-Hi-GAL survey Molinari et al. 2010

22 Herschel Hi-GAL Survey: FIR as the spiral arm fitting weight Star formation rate through the Galaxy Emission profile/sources count plots to find arm's tangent direction...

23 The spiral arms from star counts and Emission profiles Arms tangent directions Old star population and dust Benjamin 2008 and Drimmel 2000 => 2 major spiral arms !! Scutum-Crux and Perseus Churchwell et al., 2009 (JHK 2Mass, 4.5 m m Spitzer)

24

25 Scutum Crux (south) Scutum Crux (North) Norma (North) Norma (South) (JHK 2Mass, 4.5 m m Spitzer) Sagittarius Carina (North) Russeil 2003

26 Bronfman 1992, CO Hou et al. 2009, 4 Poly. arms. Hou et al. 2009, 4 log. arms. Sagittarius Carina Sagittarius Carina Drimmel, 2000 (COBE/DIRBE data) Scutum Crux Scutum Crux Norma Orion spur

27 Rygl et al. 2010 Spitzer IRAC 3.6-4.5 m m Mean color excess Norma Scutum Crux Norma Sagittarius Carina Scutum Crux

28 The HI to trace our Galaxy's outer structure HI data - Poor contrast: arm to inter-arm density ratio ~3 - High spatial filling factor - Largely dominant in the outer Galaxy Molecular data - High contrast: e.g. arm to inter-arm density ratio ~28 in 12 CO for Perseus arm (Brunt, 2003) - But fast decline with Galactocentric radius - Few far outer molecular clouds (R G 13.5 – 17.5 kpc) with embedded stellar cluster (e.g. Yun et al. 2009, 2007, Snell et al. 2002, Santos et al. 2000)

29 McClure-Griffiths et al. 2004 (SGPS HI data) Vazquez et al. 2008 (photometric distance of clusters + CO mol. clouds) Russeil et al. 2007 HI data

30 Nakanishi & Sofue (2003) - Outer: kinematic distance - Inner: kinematic distance + vertical distribution model ajustement HI map

31 OuterPerseus Sag. Carina Nakanishi & Sofue (2003) - Logaritmic HI arms - Not detected in HI: Scutum-Crux and Norma arms

32 Levine et al., 2006 Connection Outer- inner structures (Hou et al. 2009) HI map - Map of perturbation HI surface density - « Unsharp masking » technique - HI thickness smaller in the amrs

33 Distance determination : GAIA, maser Parallaxes, Infrared spectroscopy/photometry New/recent and incoming Large surveys of the galactic plane : Molecular: GRS, IGPS HI:all plane surveys Ionised gas: radio (MAGPIS, CORNISH), Halpha (IPHAS, WHAM)... Dust/PAH: MSX, Spitzer-GLIMPSE, Spitzer-MIPSGAL Cold dust: ATLASGAL, SCUBA2 (sub-mm continuum), Herschel-Hi-GAL (FIR)‏ Perspectives To resolve distance ambiguity SF Complexes delimitation Optical counterpart, HII regions morphology/velocity/excitation parameter New tracer!? FIR longitude profiles Direct distance; precise the rotation curve; velocity departures

34

35

36 Molecular data Nakanishi & Sofue (2006) from 12 CO(1-0) data - Outer: kinematic distance - Inner: kinematic distance + vertical distribution model

37 Interstellar medium global view in our Galaxy Ionised gas: HII regions + WIM HII regions: around OB stars, 20 -1000 cm -3, < 30 pc WIM: widespread (h ~ 1 kpc), 20% of the disk volume, 0.08 cm -3 Molecular gas: GMC, clumps, cores... Contrast arm-interarm ~ 28:1 GMC: 10 5 -10 6 M sun, 50 -100 pc, 10 2 -10 3 cm -3 Clumps and cores: <1 pc, 10 4 -10 6 cm -3 Atomic gas: Contrast arm-interarm ~ 3:1 Widespread (h ~ 200 - 600 pc), Warp, 1 – 500 cm -3

38 Galaxy's outer structure: the warp Observed througth all tracers: - Young stars (e.g. Smart et al. 1997, Reed 1996 Vazquez et al.2008) - HII regions, Ionised gas (e.g. Guibert et al. 1978, Fich & Blitz, 1981, Paladini et al. 2004, Cersosimo, 2009) - HI & CO (e.g. Burton 1988, Nakanishi & Sofue 2003, Levine et al. 2006) Nakanishi & Sofue (2003)

39 Russeil 2003 Paladini et al. 2004 HII regions - Starts ~ 13 kpc - Northern warp more pronounced

40 The filamentary structure of the cold ISM First results from Herschel-Hi-GAL survey IPHAS

41 SH2-86 Halpha image Isocontours= 13CO

42 H  – R image UV image (GALEX)‏M83 NIR image 4.5  m NIR image 8  m

Download ppt "The Milky-Way spiral arm tracers to the actual pattern D. Russeil LAM, Marseille, France."

Similar presentations

Gas and mm Dust emission François Boulanger et Guilaine Lagache (Institut d Astrophysique Spatiale, Orsay) Tracing diffuse ISM components in te Solar Neighborhood.

Gas and mm Dust emission François Boulanger et Guilaine Lagache (Institut d Astrophysique Spatiale, Orsay) Tracing diffuse ISM components in te Solar Neighborhood.
Our Galaxy `. Interstellar dust obscures our view at visible wavelengths along lines of sight that lie in the plane of the galactic disk.

Our Galaxy `. Interstellar dust obscures our view at visible wavelengths along lines of sight that lie in the plane of the galactic disk.
The Relation between Atomic and Molecular Gas in the Outer Disks of Galaxies Jonathan Braine Observatoire de Bordeaux with... N. Brouillet, E. Gardan,

The Relation between Atomic and Molecular Gas in the Outer Disks of Galaxies Jonathan Braine Observatoire de Bordeaux with... N. Brouillet, E. Gardan,
Galaxies-I. By the 1700’s the old notion that the Earth was the center of the Universe was overthrown by the success of Newton’s theory of universal gravitation,

Galaxies-I. By the 1700’s the old notion that the Earth was the center of the Universe was overthrown by the success of Newton’s theory of universal gravitation,
Filamentary Structures in Molecular Clouds and their connection with Star Formation E.Schisano 1, S.Molinari 1, D.Polychroni 1, D.Elia 1, M.Pestalozzi.

Filamentary Structures in Molecular Clouds and their connection with Star Formation E.Schisano 1, S.Molinari 1, D.Polychroni 1, D.Elia 1, M.Pestalozzi.
Gas and Star Formation in the Circinus Galaxy Bi-Qing For ( 傅碧晴 ) SIEF John Stocker Fellow ICRAR / University of Western Australia Baerbel Koribalski (CSIRO.

Gas and Star Formation in the Circinus Galaxy Bi-Qing For ( 傅碧晴 ) SIEF John Stocker Fellow ICRAR / University of Western Australia Baerbel Koribalski (CSIRO.
The Milky Way Galaxy Chapter 15. The Milky Way Almost everything we see in the night sky belongs to the Milky Way We see most of the Milky Way as a faint.

The Milky Way Galaxy Chapter 15. The Milky Way Almost everything we see in the night sky belongs to the Milky Way We see most of the Milky Way as a faint.
The Interstellar Medium Astronomy 315 Professor Lee Carkner Lecture 19.

The Interstellar Medium Astronomy 315 Professor Lee Carkner Lecture 19.
Radio Astronomy And The Spiral Structure Of The Milky Way Jess Broderick Supervisor: Dr George Warr.

Radio Astronomy And The Spiral Structure Of The Milky Way Jess Broderick Supervisor: Dr George Warr.
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 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.
Cambridge, June 13-16, 2005 A Study of Massive Proto- and Pre-stellar Candidates with the SEST Antenna Maite Beltrán Universitat de Barcelona J. Brand.

Cambridge, June 13-16, 2005 A Study of Massive Proto- and Pre-stellar Candidates with the SEST Antenna Maite Beltrán Universitat de Barcelona J. Brand.
The Milky Way Galaxy 19 April 2005 AST 2010: Chapter 24.

The Milky Way Galaxy 19 April 2005 AST 2010: Chapter 24.
Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 23 Our Galaxy CHAPTER 23 Our Galaxy.

Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 23 Our Galaxy CHAPTER 23 Our Galaxy.
The Milky Way Center, Shape Globular cluster system

The Milky Way Center, Shape Globular cluster system
The Milky Way and Other Galaxies Science A-36 12/4/2007.

The Milky Way and Other Galaxies Science A-36 12/4/2007.
ASTR112 The Galaxy Lecture 6 Prof. John Hearnshaw 10. Galactic spiral structure 11. The galactic nucleus and central bulge 11.1 Infrared observations Galactic.

ASTR112 The Galaxy Lecture 6 Prof. John Hearnshaw 10. Galactic spiral structure 11. The galactic nucleus and central bulge 11.1 Infrared observations Galactic.
The CNM – How Much, How Cold, and Where? John Dickey University of Tasmania 4 February 2013 C + as an Astronomical Tool.

The CNM – How Much, How Cold, and Where? John Dickey University of Tasmania 4 February 2013 C + as an Astronomical Tool.
Compact HII regions toward Methanol Maser traced sources of Massive Star Formation Adam Avison (UK ARC, JBCA) Gary Fuller + MMB Collaboration.

Compact HII regions toward Methanol Maser traced sources of Massive Star Formation Adam Avison (UK ARC, JBCA) Gary Fuller + MMB Collaboration.
TURBULENCE AND HEATING OF MOLECULAR CLOUDS IN THE GALACTIC CENTER: Natalie Butterfield (UIowa) Cornelia Lang (UIowa) Betsy Mills (NRAO) Dominic Ludovici.

TURBULENCE AND HEATING OF MOLECULAR CLOUDS IN THE GALACTIC CENTER: Natalie Butterfield (UIowa) Cornelia Lang (UIowa) Betsy Mills (NRAO) Dominic Ludovici.
MALT 90 Millimetre Astronomy Legacy Team 90 GHz survey

MALT 90 Millimetre Astronomy Legacy Team 90 GHz survey

Similar presentations

Ads by Google