Presentation is loading. Please wait.

Presentation is loading. Please wait.

Der Paul van der Werf Leiden Observatory H 2 emission as a diagnostic of physical processes in star forming galaxies Paris October 1, 1999.

Published byDwayne Howard Modified over 8 years ago

Similar presentations

Presentation on theme: "Der Paul van der Werf Leiden Observatory H 2 emission as a diagnostic of physical processes in star forming galaxies Paris October 1, 1999."— Presentation transcript:

1 der Paul van der Werf Leiden Observatory H 2 emission as a diagnostic of physical processes in star forming galaxies Paris October 1, 1999

2 Molecular hydrogen emission in star forming galaxies2 H 2 emission as a diagnostic ä H 2 rotational lines: ä H 2 vibrational lines:  cf. CO J=1 - 0: T: few hundred K n > 10 2 cm -3 T: few thousand K n > 10 4-5 cm -3 T: few tens of K n > 10 2 cm -3

3 Molecular hydrogen emission in star forming galaxies3 H 2 emission lines trace excitation ä General problem: what is the excitation mechanism? ä Shocks ä UV-pumping ä X-ray excitation ä …. H 2 2.12  m in NGC253 (Van der Werf & Moorwood, in preparation) 15” = 180 pc

4 Molecular hydrogen emission in star forming galaxies4 Two case studies ä Rotational H 2 lines in the disk of NGC891: ä Vibrational H 2 lines in the nuclear region of NGC6240: A new view of the warm molecular medium (Valentijn & Van der Werf 1999, ApJ 522, L29) A new diagnostic of the nuclei of gas-rich mergers (Van der Werf, Moorwood & Israel, in preparation)

5 Molecular hydrogen emission in star forming galaxies5 Dust in NGC891 SCUBA 850  m Sky survey Israel, Van der Werf & Tilanus 1999 A&A 344, L83

6 Molecular hydrogen emission in star forming galaxies6 H 2 emission in NGC891 ä ISO-SWS survey to 11 kpc from centre  28  m and 17  m detected at all positions ä 0th-order analysis: High-density limit Isothermal Ortho/para = 3 All three assumptions fail!

7 Molecular hydrogen emission in star forming galaxies7 Simple analysis of position 8kpc N Solution: abandon high-density assumption 0th order analysis gives: T=76K N(H 2 )=2.7  10 22 cm -2 CO gives: T~20 K N(H 2 )=1.0. 10 22 cm -2

8 Molecular hydrogen emission in star forming galaxies8 Low-density solution Adopt density from CO: n(H 2 )~200 cm -3 T~130 K N(H 2 )=3.6. 10 21 cm -2  H 2 J=3 (and CO J=2) subthermally populated subthermally populated Low-density PDRs  cf. [CII] Low-density PDRs  cf. [CII] Good throughout inner disk Good throughout inner disk In outer disk: 2 components? In outer disk: 2 components?

9 Molecular hydrogen emission in star forming galaxies9 Two-component solution Solution: ortho-para ratio ~ 1 Warm H 2 dominates S(1)Warm H 2 dominates S(1) Cool H 2 dominates S(0)Cool H 2 dominates S(0) T > 130 K T < 90 K N(H 2 ) > 10 23 cm -2 M(H 2 ) > 10. M(HI) Problem: temperature balance; [CII] indicates 15  lower mass [CII] indicates 15  lower mass

10 Molecular hydrogen emission in star forming galaxies10 Vibrational H 2 emission in ULIGs Sub-arcsecond resolution near-IR H 2 imaging shows gas components between the nuclei of merging galaxies, e.g., NGC6240 ( Van der Werf et al. 1993 ApJ 405, 522) ( Van der Werf et al. 1993 ApJ 405, 522) Origin: dissipative components merge first ?Origin: dissipative components merge first ? Fate: nuclear starburst ? AGN ?Fate: nuclear starburst ? AGN ? Properties: M gas ~ M dyn ?Properties: M gas ~ M dyn ? Role of H 2 emission ?Role of H 2 emission ? Arp220 H 2 1-0 S(1) (Van der Werf & Israel, in preparation) in preparation)

11 Molecular hydrogen emission in star forming galaxies11 H 2 2.1  m emission in NGC6240 H 2 emission peaks between the nuclei. between the nuclei. MorphologyMorphology SpectraSpectra } H 2 emission from cloud-cloud shocks cloud-cloud shocks  H 2 emission powered by dissipation of mechanical energy in nuclear medium  H 2 emission measures inflow rate of molecular gas to centre of potential well K H 2 1-0 S(1) 10” = 5 kpc

12 Molecular hydrogen emission in star forming galaxies12 H 2 vibrational spectrum in NGC6240 Vibrational lines: T~1900 KVibrational lines: T~1900 K Rotational lines: T~400 KRotational lines: T~400 K  Energy radiated by shocks: L rad ~ 1.6. 10 9 L  L rad ~ 1.6. 10 9 L  Energy dissipated by shocks: L dis ~ ½ M H 2 v 2 L dis ~ ½ M H 2 v 2. L rad = L dis v~280 km s -1    M H 2 ~ 260 M  yr -1.

13 Molecular hydrogen emission in star forming galaxies13 Fate of the infalling gas Southern nucleus: M H 2 ~ 50 M  yr -1Southern nucleus: M H 2 ~ 50 M  yr -1 Northern nucleus: M H 2 ~ 20 M  yr -1Northern nucleus: M H 2 ~ 20 M  yr -1 Central component: M H 2 ~ 190 M  yr -1Central component: M H 2 ~ 190 M  yr -1 Nuclei: total mass inflow rate 70 M  yr -1 total star formation rate 45 M  yr -1 total star formation rate 45 M  yr -1... Central component: M H 2 ~2.2. 10 9 M  ~ 30% of M dyn M H 2 ~2.2. 10 9 M  ~ 30% of M dyn t acc ~ 10 7 yr t acc ~ 10 7 yr large shear prevents star formation large shear prevents star formation explosive nuclear starburst will result explosive nuclear starburst will result K H 2 1-0 S(1) N

14 Molecular hydrogen emission in star forming galaxies14 A merger sequence? (counterrotating disks) Antennae NGC6240  Arp220 Arp220 SCUBA 850  m (Van der Werf & Moorwood, in preparation)

15 Molecular hydrogen emission in star forming galaxies15 Conclusions In disks of late-type galaxies, H 2 rotational lines traceIn disks of late-type galaxies, H 2 rotational lines trace extended low-density PDRs extended low-density PDRs In mergers, H 2 lines trace dissipation of mechanical energyIn mergers, H 2 lines trace dissipation of mechanical energy in the merging gas components in the merging gas components In both cases, H 2 lines provide unique diagnostics onceIn both cases, H 2 lines provide unique diagnostics once the excitation mechanism is understood the excitation mechanism is understood

Download ppt "Der Paul van der Werf Leiden Observatory H 2 emission as a diagnostic of physical processes in star forming galaxies Paris October 1, 1999."

Similar presentations

Ming Zhu (JAC/NRC) P. P. Papadopoulos (Argelander Institute for Astronomy, Germany) Yu Gao (Purple Mountain Observatory, China) Ernie R. Seaquist (U. of.

Ming Zhu (JAC/NRC) P. P. Papadopoulos (Argelander Institute for Astronomy, Germany) Yu Gao (Purple Mountain Observatory, China) Ernie R. Seaquist (U. of.
Luminous Infrared Galaxies with the Submillimeter Array: Probing the Extremes of Star Formation Chris Wilson (McMaster), Glen Petitpas, Alison Peck, Melanie.

Luminous Infrared Galaxies with the Submillimeter Array: Probing the Extremes of Star Formation Chris Wilson (McMaster), Glen Petitpas, Alison Peck, Melanie.
From GMC-SNR interaction to gas-rich galaxy-galaxy merging Yu GAO Purple Mountain Observatory, Nanjing, China Chinese Academy of Sciences.

From GMC-SNR interaction to gas-rich galaxy-galaxy merging Yu GAO Purple Mountain Observatory, Nanjing, China Chinese Academy of Sciences.
Black Hole Fueling Image from ESO. Accretion to Supermassive Black Hole a: Ho, Filippenko & Sargent 1997a 10^6Mo 10^8 yr.

Black Hole Fueling Image from ESO. Accretion to Supermassive Black Hole a: Ho, Filippenko & Sargent 1997a 10^6Mo 10^8 yr.
Extragalactic Star Formation into the ALMA Era (Beyond CO)* Yu GAO 高 煜 Purple Mountain Observatory, Nanjing Chinese Academy of Sciences *Dedicated to the.

Extragalactic Star Formation into the ALMA Era (Beyond CO)* Yu GAO 高 煜 Purple Mountain Observatory, Nanjing Chinese Academy of Sciences *Dedicated to the.
DUST AND MOLECULES IN SPIRAL GALAXIES as seen with the JCMT F.P. Israel, Sterrewacht Leiden.

DUST AND MOLECULES IN SPIRAL GALAXIES as seen with the JCMT F.P. Israel, Sterrewacht Leiden.
Excitation Mechanisms: The Irradiated and Stirred ISM Marco Spaans (Groningen) Rowin Meijerink (Leiden), Frank Israel (Leiden), Edo Loenen (Leiden), Willem.

Excitation Mechanisms: The Irradiated and Stirred ISM Marco Spaans (Groningen) Rowin Meijerink (Leiden), Frank Israel (Leiden), Edo Loenen (Leiden), Willem.
Molecular gas in the z~6 quasar host galaxies Ran Wang National Radio Astronomy Observatory Steward Observatory, University of Atrizona Collaborators:

Molecular gas in the z~6 quasar host galaxies Ran Wang National Radio Astronomy Observatory Steward Observatory, University of Atrizona Collaborators:
Spitzer Reveals Activities of Supermassive Black Holes in Elliptical Galaxies Qiusheng Gu Nanjing University in collaboration with J.-S. Huang (CfA), G.

Spitzer Reveals Activities of Supermassive Black Holes in Elliptical Galaxies Qiusheng Gu Nanjing University in collaboration with J.-S. Huang (CfA), G.
AGN in hierarchical galaxy formation models Nikos Fanidakis and C.M. Baugh, R.G. Bower, S. Cole, C. Done, C. S. Frenk Accretion and ejection in AGN, Como,

AGN in hierarchical galaxy formation models Nikos Fanidakis and C.M. Baugh, R.G. Bower, S. Cole, C. Done, C. S. Frenk Accretion and ejection in AGN, Como,
 High luminosity from the galactic central region L bol ~ 10 44-46 erg/s  High X-ray luminosity  Supermassive black hole at the center of the galaxy.

 High luminosity from the galactic central region L bol ~ erg/s  High X-ray luminosity  Supermassive black hole at the center of the galaxy.
Imaging Arp 220 in CO 6-5 and dust at 100 pc resolution with ALMA C. Wilson, (McMaster); N. Rangwala, J. Glenn, P. Maloney, J. R. Kamenetzky (Colorado);

Imaging Arp 220 in CO 6-5 and dust at 100 pc resolution with ALMA C. Wilson, (McMaster); N. Rangwala, J. Glenn, P. Maloney, J. R. Kamenetzky (Colorado);
Eddington limited starbursts in the central 10pc of AGN Richard Davies, Reinhard Genzel, Linda Tacconi, Francisco Mueller Sánchez, Susanne Friedrich Max.

Eddington limited starbursts in the central 10pc of AGN Richard Davies, Reinhard Genzel, Linda Tacconi, Francisco Mueller Sánchez, Susanne Friedrich Max.
CO J =1-0 + J =3-2 map (Oka+ 1999, 2007) Galactic Center Kunihiko Tanaka (1), Tomoharu Oka (1), Shinji Matsumura (1), Kazuhisa Kamegai (2), Makoto Nagai.

CO J =1-0 + J =3-2 map (Oka+ 1999, 2007) Galactic Center Kunihiko Tanaka (1), Tomoharu Oka (1), Shinji Matsumura (1), Kazuhisa Kamegai (2), Makoto Nagai.
Molecular Hydrogen in the outer filaments surrounding NGC 1275 Nina Hatch CS Crawford, RM Johnstone, AC Fabian IOA, Cambridge.

Molecular Hydrogen in the outer filaments surrounding NGC 1275 Nina Hatch CS Crawford, RM Johnstone, AC Fabian IOA, Cambridge.
ULTRALUMINOUS INFRARED GALAXIES: 2D KINEMATICS AND STAR FORMATION L. COLINA, IEM/CSIC S. ARRIBAS, STSCI & CSIC D. CLEMENTS, IMPERIAL COLLEGE A. MONREAL,

ULTRALUMINOUS INFRARED GALAXIES: 2D KINEMATICS AND STAR FORMATION L. COLINA, IEM/CSIC S. ARRIBAS, STSCI & CSIC D. CLEMENTS, IMPERIAL COLLEGE A. MONREAL,
Submillimeter Astronomy in the era of the SMA, 2005, Cambridge, MA Observations of Extragalactic Star Formation in [CI] (370  m) and CO J=7-6 T. Nikola.

Submillimeter Astronomy in the era of the SMA, 2005, Cambridge, MA Observations of Extragalactic Star Formation in [CI] (370  m) and CO J=7-6 T. Nikola.
The Narrow-Line Region and Ionization Cone Lei Xu.

The Narrow-Line Region and Ionization Cone Lei Xu.
STAR FORMATION STUDIES with the CORNELL-CALTECH ATACAMA TELESCOPE Star Formation/ISM Working Group Paul F. Goldsmith (Cornell) & Neal. J. Evans II (Univ.

STAR FORMATION STUDIES with the CORNELL-CALTECH ATACAMA TELESCOPE Star Formation/ISM Working Group Paul F. Goldsmith (Cornell) & Neal. J. Evans II (Univ.
Quasar & Black Hole Science for GSMT Central question: Why do quasars evolve?

Quasar & Black Hole Science for GSMT Central question: Why do quasars evolve?

Similar presentations

Ads by Google