Magnetic Field Structure in Molecular Clouds by Polarization Measurements Wen-Ping Chen National Central University Collaborators: C. Eswaraiah (ARIES),

Slides:



Advertisements
Similar presentations
Methanol maser polarization in W3(OH) Lisa Harvey-Smith Collaborators: Vlemmings, Cohen, Soria-Ruiz Joint Institute for VLBI in Europe.
Advertisements

Studying Parsec Scale Jets in Star Forming Region Tae-Soo Pyo Subaru Telescope.
Dust particles and their spectra. Review Ge/Ay 132 Final report Ivan Grudinin.
Triggered Star Formation by Massive Stars in Star-forming Regions Wen-Ping Chen & Hsu-Tai Lee NCU/Astronomy BATC Workshop Weihai NGC6823 by.
Ammonia and CCS as diagnostic tools of low-mass protostars Ammonia and CCS as diagnostic tools of low-mass protostars Itziar de Gregorio-Monsalvo (ESO.
Formation of Stars Physics 113 Goderya Chapter(s):11 Learning Outcomes:
21 November 2002Millimetre Workshop 2002, ATNF First ATCA results at millimetre wavelengths Vincent Minier School of Physics University of New South Wales.
Polarization - Extinction Relation in the 4th Galactic Quadrant Nadia Kaltcheva Department of Physics and Astronomy, University of Wisconsin Oshkosh Statistical.
Mini Workshop on Star Formation and Astrochemistry. Barcelona, 2006 November 23 1 Robert Estalella, Aina Palau, Maite Beltrán (UB) Paul T. P. Ho (CfA),
Polarization 101 Absorption Emission Scattering. PolarizationPolarization of Background Starlight.
The Interstellar Medium Astronomy 315 Professor Lee Carkner Lecture 19.
Spatial Structure Evolution of Open Star Clusters W. P. Chen and J. W. Chen Graduate Institute of Astronomy National Central University IAU-APRM
Although there are regions of the galaxy M33 which show both high density neutral hydrogen gas and 24 micron emission, high density gas does not always.
SH2 136: A Spooky Nebula Ghoulish dust clouds: a region of star formation Halloween corresponds roughly to the cross-quarter day: half-way between equinox.
STAR FORMATION STUDIES with the CORNELL-CALTECH ATACAMA TELESCOPE Star Formation/ISM Working Group Paul F. Goldsmith (Cornell) & Neal. J. Evans II (Univ.
Satoshi Yamamoto and Nobuyuki Kuboi Department of Physics The University of Tokyo Submillimeter-wave CI Line Survey in Molecular Clouds.
21 October Introduction to M4 Science Observe 95  m Polarized Radiation l Map the “Magnetic Field of the Milky Way” (Central 100 degrees in l and.
ASTR112 The Galaxy Lecture 6 Prof. John Hearnshaw 10. Galactic spiral structure 11. The galactic nucleus and central bulge 11.1 Infrared observations Galactic.
Star Formation Research Now & With ALMA Debra Shepherd National Radio Astronomy Observatory ALMA Specifications: Today’s (sub)millimeter interferometers.
MALT 90 Millimetre Astronomy Legacy Team 90 GHz survey
Initial Conditions for Star Formation Neal J. Evans II.
ATLASGAL ATLASGAL APEX Telescope Large Area Survey of the Galaxy F. Schuller, K. Menten, P. Schilke, et al. Max Planck Institut für Radioastronomie.
Robert Benjamin (UW-W) and the GLIMPSE team with special thanks to
Unit 5: Sun and Star formation part 2. The Life Cycle of Stars Dense, dark clouds, possibly forming stars in the future Young stars, still in their birth.
A NEAR-INFRARED STUDY OF THE SOUTHERN STAR FORMING REGION RCW 34 Lientjie de Villiers M.Sc. PROJECT SUPERVISOR: Prof. D.J. van der Walt.
Star Formation in our Galaxy Dr Andrew Walsh (James Cook University, Australia) Lecture 1 – Introduction to Star Formation Throughout the Galaxy Lecture.
VLASS – Galactic Science Life cycle of star formation in our Galaxy as a proxy for understanding the Local Universe legacy science Infrared GLIMPSE survey.
Great Barriers in High Mass Star Formation, Townsville, Australia, Sept 16, 2010 Patrick Koch Academia Sinica, Institute of Astronomy and Astrophysics.
Chapter 15: Star Formation and the Interstellar Medium.
The Galactic Plane Infrared Polarization Survey (GPIPS) Current Members: Michael Pavel Dan Clemens (PI) Lauren Cashman Sadia Hoq Jordan Montgomory Ian.
Magnetic fields in the Galaxy via Faraday effect: Future prospects with ASKAP and the SKA Lisa Harvey-Smith Collaborators: Bryan CSIRO SKA Project ScientistGaensler.
Magnetic Fields in Molecular Clouds Richard M. Crutcher University of Illinois Collaborators:Tom Troland, University of Kentucky Edith Falgarone, Ecole.
Dusty disks in evolved stars?
Studying Young Stellar Objects with the EVLA
Protostellar jets and outflows — what ALMA can achieve? — 平野 尚美 (Naomi Hirano) 中研院天文所 (ASIAA)
ASTR112 The Galaxy Lecture 7 Prof. John Hearnshaw 11. The galactic nucleus and central bulge 11.1 Infrared observations (cont.) 11.2 Radio observations.
The infrared extinction law in various interstellar environments 1 Shu Wang 11, 30, 2012 Beijing Normal University mail.bnu.edu.cn.
Shih-Ping Lai 賴詩萍 (National Tsing-Hua University, Taiwan) 清華大學, 台灣.
Lecture 30: The Milky Way. topics: structure of our Galaxy structure of our Galaxy components of our Galaxy (stars and gas) components of our Galaxy (stars.
Masers Surveys with Mopra: Which is best 7 or 3 mm? Simon Ellingsen, Maxim Voronkov & Shari Breen 3 November 2008.
Forming High Mass Stars Probing the Formation Epoch.
Philamentary Structure and Velocity Gradients in the Orion A Cloud
Star Clusters The Secret of the Stars Star clusters Nebula and.
1)Observations: where do (massive) stars form? 2)Theory: how do (massive) stars form? 3)Search for disks in high-mass (proto)stars 4)Results: disks in.
Fitting Magnetized Molecular Cloud Collapse Models to NGC 1333 IRAS 4A Pau Frau Josep Miquel Girart Daniele Galli Institut de Ciències de l’Espai (IEEC-CSIC)
Early O-Type Stars in the W51-IRS2 Cluster A template to study the most massive (proto)stars Luis Zapata Max Planck Institut für Radioastronomie, GERMANY.
IR Astronomy In Search of Grain Alignment Pierre Bastien Megan Krejny Kathleen DeWahl Terry Jay Jones University of Minnesota.
Master in Astrophysics, Particle Physics, and Cosmology Academic year Fall semester Mon, Tue, Wed, 16:10 – 17:30, room N07P Stellar Structure and.
A Survey of the Global Magnetic Fields of Giant Molecular Clouds Giles Novak, Northwestern University Instrument: SPARO Collaborators: P. Calisse, D. Chuss,
The Formation of Stars. I. Making Stars from the Interstellar Medium A. Star Birth in Giant Molecular Clouds B. Heating By Contraction C. Protostars D.
The Cores to Disks Spitzer Legacy Science Project PI: Neal J. Evans II and the c2d Team Maryland Team: Mundy, Lai, Chapman and several UG students.
NGC7538-IRS1: Polarized Dust & Molecular Outflow C. L. H. Hull (UC Berkeley), T. Pillai (Caltech), J.-H. Zhao (CfA), G. Sandell (SOFIA-USRA, NASA), M.
LDN 723: Can molecular emission be used as clock calibrators? Josep Miquel Girart Collaborators: J.M.Masqué,R.Estalella (UB) R.Rao (SMA)
ISM & Astrochemistry Lecture 1. Interstellar Matter Comprises Gas and Dust Dust absorbs and scatters (extinguishes) starlight Top row – optical images.
Cosmic Masers Chris Phillips CSIRO / ATNF. What is a Maser? Microwave Amplification by Stimulated Emission of Radiation Microwave version of a LASER Occur.
“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.
Polarized Light from Star-Forming Regions
1 SIMBA survey of southern high-mass star forming regions Santiago Faúndez (U. de Chile) Leonardo Bronfman(U. de Chile) Guido Garay (U. de Chile) Rolf.
Observability of YSOs with the WISE and AKARI infrared observatories Sarolta Zahorecz Eötvös University, Budapest PhD student, 3. year Thesis advisor:
1)The recipe of (OB) star formation: infall, outflow, rotation  the role of accretion disks 2)OB star formation: observational problems 3)The search for.
SMA and ASTE Observations of Low-mass Protostellar Envelopes in the Submillimeter CS (J = 7-6) and HCN (J = 4-3) Lines Shigehisa Takakuwa 1, Takeshi Kamazaki.
21 November 2002Millimetre Workshop 2002, ATNF High mass star formation in the Southern hemisphere sky Vincent Minier (Service d’Astrophysique, CEA Saclay),
Fumitaka Nakamura (National Astronomical Observatory of Japan)
K(2 m) Version of JASMINE and its Science
Using ALMA to disentangle the Physics of Star Formation in our Galaxy
The Formation and Structure of Stars
Thin, Cold Strands of Hydrogen in the Riegel-Crutcher Cloud
The Formation of Stars.
University of Minnesota
MASER Microwave Amplification by Stimulated Emission of Radiation
Presentation transcript:

Magnetic Field Structure in Molecular Clouds by Polarization Measurements Wen-Ping Chen National Central University Collaborators: C. Eswaraiah (ARIES), S. P. Lai (NTHU), C. D. Lee (NCU), C. C. Lin (NCU), A. K. Pandey (ARIES), Shuji Sato (Nagoya U), Y. H. Shi (NCU), Bohe Su (NCU), M. Tamura (NAOJ), J. W. Wang (NTHU)

Magnetic Field and Star Formation What is the field strength and structure on different length scales (hence densities) from the molecular cloud, core, to protostar? B suppresses cloud fragmentation/collapse; ambipolar diffusion reduces the strength, hence the influence of, the field. B collates filaments? Guides core collapse and mass outflows?

Observations in OIR Observations in FIR to mm Scattering by dustDichroic extinction by aligned dust Polarized thermal emission by dust aligned by B Courtesy: Tamura Stahler & Pallo 2004

The Rho Oph cloud (Vrba et al. 1976) The Rho Oph cloud (Stahler & Palla 2004; data from Loren 1989 and Goodman et al. 1990)  Background stars should be otherwise unpolarized.  IR less extinction than the optical, so probes deeper into the cloud (more background stars) but less effective  To derive the B information, need to sort out which mechanism is at work.  To infer if cloud geometry influenced by B, need to isolate other effects, e.g., by shocks. Polarization of Background Stars --- Dichroic extinction by thermalized, magnetically aligned dust

Our program To probe the B structure on protostellar scales and on the inner part of a cloud core by SMA, and soon by ALMA; disk/outflow configuration on the outer part of a cloud core by NIR polarization (e.g., SIRPOL) on the periphery of a cloud core by optical polarization (e.g., TRIPOL)

SIRPOL --- SIRIUS (Simultaneous IR imager for Unbiased Survey) with polarimeter IRSF 1.4 m telescope at SAAO Simultaneous JHKs imaging polarimeter FOV 7.7’, (1 K x 1 K x 3 bands, 0.45”/pix) Imaging sensitivity, J=19.2, H=18.6, Ks=17.3 mag (S/N=5; 60 min) Pol sensitivity, J < 16.5, H < 15.7, Ks < 14.5 (dP < 0.3-1%) Tamura et al on the Orion Nebula

The Carina nebula (NGC 3372) RA = 10:45:08.5, Dec = ‒59:52:04 is a large bright nebula powered by UV radiation from 65 O-type stars and 3 WNH stars (Smith et al. 2008), including the most massive and luminous star in the Milky Way, Eta Carinae. At a distance of 2.3 kpc, the Carina nebula is a good laboratory to study massive star formation. RCW 57A (NGC 3576) RA = 11:11:54.8 Dec = ‒61:18:26 is among the brightest Galactic HII regions, hosting many IR excess stars and some high-mass Class 0/I objects (Barbosa et al. 2003). At a distance of 2.4 kpc (Persi et al. 1994), RCW57 is also a good target to study star formation in a turbulent environment.

DSS 5 deg Carina Nebula RCW 57A

Only reliable measurements (ΔP 3 and ΔH < 0.05 mag) are included.

Carina nebulaRCW 57A 12CO(J = 1−0) emission (Yonekura et al. 2004) H band

Carina nebula [Background = foreground = Galactic] in polarization because the SIRPOL field is devoid of dense cloud.  No B information The whole region was mosaicked in the spring of 2012.

[S II] Rcw 57A Hour-glass shaped B threading the elongated cloud

H-band stellar polarization overlaid on the WISE 4.6 micron image Grey lines: H-band pol Central curve: 13CO Dashed lines: HII region (3.4 cm) Pluses: H2O maser sources Filled squares: IRAS sources Triangles: Class I Open squares: Class II cavities, bubble Eswaraiah+2012 prep

Foreground stars toward RCW57A and Carina Nebula with V-band polarization (Heiles 2000) and Hipparcos parallaxes (van Leeuwen 2007). By assuming P max = 1.0%, max =0.55 micron, K=1.15 and by using the Serkowski's relation P/P max = exp[ -K * ln 2 ( max / ) ] So the foreground polarization in NIR is negligible P J < 0.65 % (J=1.25 micron) P H < 0.46 % (H=1.63 micron) P Ks < 0.30 % (K=2.14 micron)  P internal in RCW 57A  no external perturber to shape the cloud

TRIPOL --- Tri-color Imaging Polarimeter Designed and fabricated by Prof. Shuji Sato of Nagoya U. Prototype completed in 2011, tested on Lulin one- meter telescope (LOT), now on the 75 cm telescope at SAAO. Second unit completed in 2012, now as facility instrument at Lulin. Meant to be simple, robust, versatile, and economic, particularly suitable for small telescopes. Simultaneous imaging at gri bands

F10 3 Color Imaging & a Polarizer 3 channel polarization ½-plate wire-grid birefringenceor r i plain imager CCD 3-CCD

~3000 US$ SBIG

TRIPOL images of M1 (top) polarized intensity and (bottom) total intensity in g’, r’, and i’ (left to right) TRIPOL first light images: M16 in g’ (left), r’, and i’.

HL Tau XZ Tau g’ r’ i’ HL Tau (B=16.02, K=7.41) PolarizationPol Angle g’ / /- 01 r’ / /- 01 i‘ / /- 0.0 XZ Tau (B=10.4, K=7.29) g‘1.48 +/ /- 03 r‘1.29 +/ /- 02 i‘1.51 +/ /- 01 TRIPOL images taken with the LOT in August 2011 T Tauri stars

CB3 --- a dark globule CB 3 g band

Ward-Thompson et al. (2009)

Conclusions Polarization is a powerful tool to infer the magnetic field configuration in molecular clouds. A combination of extinction (OIR) and thermal emission (FIR to mm) measurements will yield the field structure from small- to large-length scales. In RCW 57A, there is possible evidence of B controlled cloud contraction. Full operation of TRIPOL is scheduled in December 2012 to study cores with YSOs, starless cores, etc.