Image: Hubble Hones in on a Hypergiant's Home 10 March 2017

Total Page：16

File Type：pdf, Size：1020Kb

Image: Hubble hones in on a hypergiant's home 10 March 2017 beyond the orbit of Jupiter. Most of Westerlund 1's stars are thought to have formed in the same burst of activity, meaning that they have similar ages and compositions. The cluster is relatively young in astronomical terms —at around three million years old it is a baby compared to our own sun, which is some 4.6 billion years old. Provided by NASA's Goddard Space Flight Center This Hubble image reveals a young super star cluster known as Westerlund 1, only 15,000 light-years away in our Milky Way neighborhood, yet home to one of the largest stars ever discovered. Credit: ESA/Hubble & NASA This beautiful Hubble image reveals a young super star cluster known as Westerlund 1, only 15,000 light-years away in our Milky Way neighborhood, yet home to one of the largest stars ever discovered. Stars are classified according to their spectral type, surface temperature, and luminosity. While studying and classifying the cluster's constituent stars, astronomers discovered that Westerlund 1 is home to an enormous star. Originally named Westerlund 1-26, this monster star is a red supergiant (although sometimes classified as a hypergiant) with a radius over 1,500 times that of our sun. If Westerlund 1-26 were placed where our sun is in our solar system, it would extend out 1 / 2 APA citation: Image: Hubble hones in on a hypergiant's home (2017, March 10) retrieved 2 October 2021 from https://phys.org/news/2017-03-image-hubble-hones-hypergiant-home.html This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only. 2 / 2 Powered by TCPDF (www.tcpdf.org).

Copy Link

Recommended publications

Astronomie in Theorie Und Praxis 8. Auflage in Zwei Bänden Erik Wischnewski
Astronomie in Theorie und Praxis 8. Auflage in zwei Bänden Erik Wischnewski Inhaltsverzeichnis 1 Beobachtungen mit bloßem Auge 37 Motivation 37 Hilfsmittel 38 Drehbare Sternkarte Bücher und Atlanten Kataloge Planetariumssoftware Elektronischer Almanach Sternkarten 39 2 Atmosphäre der Erde 49 Aufbau 49 Atmosphärische Fenster 51 Warum der Himmel blau ist? 52 Extinktion 52 Extinktionsgleichung Photometrie Refraktion 55 Szintillationsrauschen 56 Angaben zur Beobachtung 57 Durchsicht Himmelshelligkeit Luftunruhe Beispiel einer Notiz Taupunkt 59 Solar-terrestrische Beziehungen 60 Klassifizierung der Flares Korrelation zur Fleckenrelativzahl Luftleuchten 62 Polarlichter 63 Nachtleuchtende Wolken 64 Haloerscheinungen 67 Formen Häufigkeit Beobachtung Photographie Grüner Strahl 69 Zodiakallicht 71 Dämmerung 72 Definition Purpurlicht Gegendämmerung Venusgürtel Erdschattenbogen 3 Optische Teleskope 75 Fernrohrtypen 76 Refraktoren Reflektoren Fokus Optische Fehler 82 Farbfehler Kugelgestaltsfehler Bildfeldwölbung Koma Astigmatismus Verzeichnung Bildverzerrungen Helligkeitsinhomogenität Objektive 86 Linsenobjektive Spiegelobjektive Vergütung Optische Qualitätsprüfung RC-Wert RGB-Chromasietest Okulare 97 Zusatzoptiken 100 Barlow-Linse Shapley-Linse Flattener Spezialokulare Spektroskopie Herschel-Prisma Fabry-Pérot-Interferometer Vergrößerung 103 Welche Vergrößerung ist die Beste? Blickfeld 105 Lichtstärke 106 Kontrast Dämmerungszahl Auflösungsvermögen 108 Strehl-Zahl Luftunruhe (Seeing) 112 Tubusseeing Kuppelseeing Gebäudeseeing Montierungen 113 Nachführfehler
[Show full text]
Pos(INTEGRAL 2010)091
A candidate former companion star to the Magnetar CXOU J164710.2-455216 in the massive Galactic cluster Westerlund 1 PoS(INTEGRAL 2010)091 P.J. Kavanagh 1 School of Physical Sciences and NCPST, Dublin City University Glasnevin, Dublin 9, Ireland E-mail: [email protected] E.J.A. Meurs School of Cosmic Physics, DIAS, and School of Physical Sciences, DCU Glasnevin, Dublin 9, Ireland E-mail: [email protected] L. Norci School of Physical Sciences and NCPST, Dublin City University Glasnevin, Dublin 9, Ireland E-mail: [email protected] Besides carrying the distinction of being the most massive young star cluster in our Galaxy, Westerlund 1 contains the notable Magnetar CXOU J164710.2-455216. While this is the only collapsed stellar remnant known for this cluster, a further ~10² Supernovae may have occurred on the basis of the cluster Initial Mass Function, possibly all leaving Black Holes. We identify a candidate former companion to the Magnetar in view of its high proper motion directed away from the Magnetar region, viz. the Luminous Blue Variable W243. We discuss the properties of W243 and how they pertain to the former Magnetar companion hypothesis. Binary evolution arguments are employed to derive a progenitor mass for the Magnetar of 24-25 M Sun , just within the progenitor mass range for Neutron Star birth. We also draw attention to another candidate to be member of a former massive binary. 8th INTEGRAL Workshop “The Restless Gamma-ray Universe” Dublin, Ireland September 27-30, 2010 1 Speaker Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike Licence.
[Show full text]
Super Stellar Clusters with a Bimodal Hydrodynamic Solution: an Approximate Analytic Approach
A&A 471, 579–583 (2007) Astronomy DOI: 10.1051/0004-6361:20077282 & c ESO 2007 Astrophysics Super stellar clusters with a bimodal hydrodynamic solution: an approximate analytic approach R. Wünsch1, S. Silich2, J. Palouš1, and G. Tenorio-Tagle2 1 Astronomical Institute, Academy of Sciences of the Czech Republic, v.v.i., Bocníˇ II 1401, 141 31 Prague, Czech Republic e-mail: [email protected] 2 Instituto Nacional de Astrofísica Optica y Electrónica, AP 51, 72000 Puebla, Mexico Received 12 February 2007 / Accepted 22 May 2007 ABSTRACT Aims. We look for a simple analytic model to distinguish between stellar clusters undergoing a bimodal hydrodynamic solution from those able to drive only a stationary wind. Clusters in the bimodal regime undergo strong radiative cooling within their densest inner regions, which results in the accumulation of the matter injected by supernovae and stellar winds and eventually in the formation of further stellar generations, while their outer regions sustain a stationary wind. Methods. The analytic formulae are derived from the basic hydrodynamic equations. Our main assumption, that the density at the star cluster surface scales almost linearly with that at the stagnation radius, is based on results from semi-analytic and full numerical calculations. Results. The analytic formulation allows for the determination of the threshold mechanical luminosity that separates clusters evolving in either of the two solutions. It is possible to ﬁx the stagnation radius by simple analytic expressions and thus to determine the fractions of the deposited matter that clusters evolving in the bimodal regime blow out as a wind or recycle into further stellar generations.
[Show full text]
Arxiv:2005.00801V2 [Astro-Ph.GA] 15 May 2020
Noname manuscript No. (will be inserted by the editor) The Physics of Star Cluster Formation and Evolution Martin G. H. Krause · Stella S. R. Offner · Corinne Charbonnel · Mark Gieles · Ralf S. Klessen · Enrique Vázquez-Semadeni · Javier Ballesteros-Paredes Philipp Girichidis · J. M. Diederik Kruijssen · Jacob L. Ward · Hans Zinnecker Received: 31 Jan 2020 / Accepted: date Martin G. H. Krause Centre for Astrophysics Research, School of Physics, Astronomy and Mathematics, University of Hertfordshire, College Lane, Hatfield, Hertfordshire AL10 9AB, UK E-mail: [email protected] Stella S. R. Offner Department of Astronomy, The University of Texas, Austin TX, 78712, U.S.A. Corinne Charbonnel Department of Astronomy, University of Geneva, Chemin de Pegase 51, 1290 Versoix, Switzer- land; IRAP, CNRS & Univ. of Toulouse, 14, av.E.Belin, 31400 Toulouse, France Mark Gieles Institut de Ciènciesdel Cosmos (ICCUB-IEEC), Universitat de Barcelona, Mart´ıi Franquès 1, 08028 Barcelona, Spain; ICREA, Pg. Lluis Companys 23, 08010 Barcelona, Spain Ralf S. Klessen Universität Heidelberg, Zentrum für Astronomie, Institut für Theoretische Astrophysik, Albert-Ueberle-Str. 2, 69120 Heidelberg, Germany Enrique Vázquez-Semadeni Instituto de Radioastronom´ıay Astrof´ısica,Universidad Nacional Autónomade Méx´ıco,Cam- pus Morelia, Apdo. Postal 3-72, Morelia 58089, México Javier Ballesteros-Paredes Instituto de Radioastronom´ıay Astrof´ısica,Universidad Nacional Autónomade Méx´ıco,Cam- pus Morelia, Apdo. Postal 3-72, Morelia 58089, México Philipp Girichidis Leibniz-Institut fürAstrophysik (AIP), An der Sternwarte 16, 14482 Potsdam, Germany J. M. Diederik Kruijssen Astronomisches Rechen-Institut, Zentrum für Astronomie der Universität Heidelberg, Mönchhofstraße 12-14, 69120 Heidelberg, Germany Jacob L.
[Show full text]
"#$%&'() + '', %-./0$%)%1 2 ()3 4&(5' 456')5'
rs uvvwxyuzyws { yz|z|} rsz}~suzywsu}u~w vz~wsw 456789@A C 99D 7EFGH67A7I P @AQ R8@S9 RST9AS9 UVWUX `abcdUVVe fATg96GTHP7Eh96HE76QGiT69pf q rAS76876@HTAs tFR u Fv wxxy @AQ 4FR 4u Fv wxxy UVVe abbc d dbdc e f gc hi` ij ad bch dgcadabdddc c d ac k lgbc bcgb dmg agd g` kg bdcd dW dd k bg c ngddbaadgc gabmob nb boglWad g kdcoddog kedgcW pd gc bcogbpd kb obpcggc dd kfq` UVVe c iba ! " #$%& $' ())01023 Book of Abstracts – Table of Contents Welcome to the European Week of Astronomy & Space Science ...................................................... iii How space, and a few stars, came to Hatfield ............................................................................... v Plenary I: UK Solar Physics (UKSP) and Magnetosphere, Ionosphere and Solar Terrestrial (MIST) ....... 1 Plenary II: European Organisation for Astronomical Research in the Southern Hemisphere (ESO) ....... 2 Plenary III: European Space Agency (ESA) .................................................................................. 3 Plenary IV: Square Kilometre Array (SKA), High-Energy Astrophysics, Asteroseismology ................... 4 Symposia (1) The next era in radio astronomy: the pathway to SKA .............................................................. 5 (2) The standard cosmological models - successes and challenges .................................................. 17 (3) Understanding substellar populations and atmospheres: from brown dwarfs to exo-planets .......... 28 (4) The life cycle of dust ...........................................................................................................
[Show full text]
Cycle 14 Approved Programs
Cycle 14 Approved Programs as of 04/05/05 Science First Name Last Name Type Phase II ID Institution Country Title Category Physical Processes in Orion's Veil: A High Resolution Nicholas Abel AR 10636 University of Kentucky USA Star Formation UV Absorption Study of the Line of Sight Towards the Trapezium University of Eric Agol GO 10486 USA Cosmology A Cosmic String Lens Candidate Washington University of Eric Agol AR 10637 USA Cool Stars Finding Terrestrial Planets with HST Washington Space Telescope NGC 4449: a Testbed for Starbursts in the Low- and Alessandra Aloisi GO 10585 Science Institute - USA Galaxies High-Redshift Universe ESA Space Telescope The Rosetta Stone without a Distance: Hunting for Alessandra Aloisi GO 10586 Science Institute - USA Galaxies Cepheids in the "Primordial" Galaxy I Zw 18 ESA University of Timing Studies of the X-ray Binary Populations in Scott Anderson GO 10615 USA Hot Stars Washington Globular Clusters The Johns Hopkins A Search for Debris Disks in the Coeval Beta Pictoris David Ardila GO 10487 USA Star Formation University Moving Group University of Colorado Thomas Ayres AR 10638 USA Cool Stars StarCAT at Boulder Studies of Europa's Plasma Interactions and Gilda Ballester AR 10639 University of Arizona USA Solar System Atmosphere with HST/STIS FUV Images Edward Baltz GO 10543 Stanford University USA Galaxies Microlensing in M87 and the Virgo Cluster University of HST Observations of MilliJansky Radio Sources from the Robert Becker AR 10640 USA Galaxies California - Davis VLA FIRST Survey European Southern
[Show full text]
A Super-Star Cluster in NGC 253: Mid-Infrared Properties
THE ASTROPHYSICAL JOURNAL, 518:183È189, 1999 June 10 ( 1999. The American Astronomical Society. All rights reserved. Printed in U.S.A. A SUPERÈSTAR CLUSTER IN NGC 253: MID-INFRARED PROPERTIES ERIC KETO,JOSEPH L. HORA, AND G. G. FAZIO Smithsonian Astrophysical Observatory, 60 Garden Street, Cambridge, MA 02138 WILLIAM HOFFMANN Steward Observatory, University of Arizona, Tucson, AZ 85721 AND LYNNE DEUTSCH Astronomy Department, Boston University, 725 Commonwealth Avenue, Boston, MA 02215 Received 1998 February 26; accepted 1999 January 12 ABSTRACT We observed the nearby starburst galaxy NGC 253 in the mid-infrared to obtain a three-dimensional data set with arcsecond angular resolution and 0.2 km spectral resolution. The observations show the major spectral features in the upper half of the mid-IR window: the 11.3 km polycyclic aromatic hydro- carbon (PAH) line and the 12.8 km [Ne II] line as well as the broad silicate absorption feature at 9.7 km. We use the [Ne II] line to determine the emission measure of the ionized gas, and in combination with radio observations to predict the thermal and nonthermal contributions to the radio continuum. The amount of ionized gas is related to the rate of star formation. Based on the mid-IR spectra, we identify three major components in the nucleus of NGC 243: an AGN in the center of the galaxy, a superÈstar cluster also seen in optical images, and a larger scale di†use envelope composed of an older population of supernova remnants and lower mass stars. Subject headings: galaxies: individual (NGC 253) È galaxies: starburst È galaxies: star clusters 1.
[Show full text]
Unlocking Galactic Wolf-Rayet Stars with $\Textit {Gaia} $ DR2 II: Cluster
MNRAS 000,1{19 (2019) Preprint 7 May 2020 Compiled using MNRAS LATEX style file v3.0 Unlocking Galactic Wolf-Rayet stars with Gaia DR2 II: Cluster and Association membership Gemma Rate,? Paul A. Crowther, Richard J. Parkery Department of Physics and Astronomy, University of Sheffield, Sheffield, S3 7RH, UK Accepted XXX. Received YYY; in original form ZZZ ABSTRACT Galactic Wolf-Rayet (WR) star membership of star forming regions can be used to constrain the formation environments of massive stars. Here, we utilise Gaia DR2 parallaxes and proper motions to reconsider WR star membership of clusters and associations in the Galactic disk, supplemented by recent near-IR studies of young massive clusters. We find that only 18{36% of 553 WR stars external to the Galac- tic Centre region are located in clusters, OB associations or obscured star-forming regions, such that at least 64% of the known disk WR population are isolated, in contrast with only 13% of O stars from the Galactic O star Catalogue. The fraction located in clusters, OB associations or star-forming regions rises to 25{41% from a global census of 663 WR stars including the Galactic Centre region. We use simu- lations to explore the formation processes of isolated WR stars. Neither runaways, nor low mass clusters, are numerous enough to account for the low cluster member- ship fraction. Rapid cluster dissolution is excluded as mass segregation ensures WR stars remain in dense, well populated environments. Only low density environments consistently produce WR stars that appeared to be isolated during the WR phase.
[Show full text]
The Low-Mass Stellar Content of Westerlund 1
The low-mass stellar content of Westerlund 1 Morten Andersen (Gemini South) Galactic young massive star clusters • Connection between local and global SF. • Can resolve the stellar populations to low masses • Star counts instead of integrated properties • Directly measure the IMF The IMF in resolved massive clusters Only scale-free part probed Westerlund 1 • Distance of ~4 Kpc, age 3-5 Myr • Total mass estimated to be 50000 Msun • High foreground extinction • Best opportunity for resolving the low mass content in a young massive cluster • HST J (F125W) and H (F160W) band imaging Westerlund 1 from ground 5pc 4.5’ SOfI JHK, Brandner et al. 2007, Gennaro et al. Early lessons • Probe down to ~3 Msun, normal (Salpeter) IMF • Total mass of ~50000 Msun assuming standard IMF • Mass segregated, at least for high masses • Elliptical cluster • Currently difficult to improve from the ground Westerlund 1 with HST 5pc 4.5’ WFC3 F125W, F160W. Andersen et al. 2016 Color-magnitude diagrams Andersen et al. 2016 Foreground population Andersen et al. 2016 Red Clump Andersen et al. 2016 Background contamination Andersen et al. 2016 Cluster main sequence MS/PMS turn-on Andersen et al. 2016 Field star subtraction Andersen et al. 2016 Mass Functions Log-normal fit below 1 Msun to the 50% completeness limit. Power-law fit above 1 Msun (Siess 4 Myr isochrone) Change of fit parameters as a function of radius M < 1 Msun, log-normal ﬁts Comparable peak mass as the ﬁeld. More narrow distribution Change of fit parameters as a function of radius M > 1 Msun Evidence for mass segregation out to 1.5-2 pc Andersen et al.
[Show full text]
Spatial Distribution of Galactic Wolf–Rayet Stars and Implications for the Global Population
MNRAS 447, 2322–2347 (2015) doi:10.1093/mnras/stu2525 Spatial distribution of Galactic Wolf–Rayet stars and implications for the global population C. K. Rosslowe‹ andP.A.Crowther Department of Physics and Astronomy, University of Sheffield, Hicks Building, Hounsfield Road, S3 7RH, UK Accepted 2014 November 26. Received 2014 November 26; in original form 2014 September 5 ABSTRACT We construct revised near-infrared absolute magnitude calibrations for 126 Galactic Wolf– Rayet (WR) stars at known distances, based in part upon recent large-scale spectroscopic surveys. Application to 246 WR stars located in the field permits us to map their Galactic distribution. As anticipated, WR stars generally lie in the thin disc (∼40 pc half-width at half- maximum) between Galactocentric radii 3.5–10 kpc, in accordance with other star formation tracers. We highlight 12 WR stars located at vertical distances of ≥300 pc from the mid-plane. Analysis of the radial variation in WR subtypes exposes a ubiquitously higher NWC/NWN ratio than predicted by stellar evolutionary models accounting for stellar rotation. Models for non- rotating stars or accounting for close binary evolution are more consistent with observations. We consolidate information acquired about the known WR content of the Milky Way to build a simple model of the complete population. We derive observable quantities over a range of wavelengths, allowing us to estimate a total number of 1900 ± 250 Galactic WR stars, implying an average duration of ∼ 0.4 Myr for the WR phase at the current Milky Way star formation rate. Of relevance to future spectroscopic surveys, we use this model WR population to predict follow-up spectroscopy to KS 17.5 mag will be necessary to identify 95 per cent of Galactic WR stars.
[Show full text]
Resolving the Low-Mass Content of Westerlund 1 Using MCAO
Resolving the low-mass content of Westerlund 1 using MCAO M. Andersena, B. Neichelb, A. Bernardb, and V. Garrela aGemini Observatories, Casilla 603 La Silla, Chile bAix Marseille Université,CNRS, LAM (Laboratoire d'Astrophysique de Marseille) UMR 7326, 13388 Marseille, France ABSTRACT We present deep Ks band Gemini GeMS/GSAOI observations of Westerlund 1, the most massive young Galactic star cluster known. The high spatial resolution combined with a relatively stable point spread function across a large field of view provide unique possibilities to resolve the low-mass content of the cluster. We show that the clean point spread function is crucial in handling the source detection in this crowded field suffering extremely high contrast from the brightest hypergiants in the cluster to faint brown dwarfs. Keywords: star clusters: Westerlund 1, Initial Mass Function, Photometry, MCAO, Laser Guide Star Systems 1. INTRODUCTION Much progress has been made in the last decades in our understanding of low-mass star forming regions. Detailed observations of individual objects have made it possible to characterise them in detail and to determine the star formation history and the impact of environment. 4 Similar studies of massive star clusters (more than 10 M ) are much less detailed. However, they differ fundamentally from nearby regions in terms of their central densities and large content of massive stars that may have influenced the star formation process within the cluster. These clusters are rare and the nearest ones known are an order of magnitude more distant than the nearby low-mass regions. This, together with their higher densities, means that high spatial resolution observations are necessary to resolve the low-mass content of the clusters.
[Show full text]
Characterizing the Super Star Cluster Populations in Lirgs
The SUNBIRD survey: characterizing the super star cluster populations in LIRGs Zara Randriamanakoto South African Astronomical Observatory Petri Vaisanen (SAAO) Erkki Kankare (Univ. Belfast) Andres Escala (Uni de Chile) Seppo Mattila (Turku/FINCA) Stuart Ryder (AAO) Jari Kotilainen (Turku/FINCA) Outline · Luminous infrared galaxies (LIRGs) · The survey · Super star clusters (motivation) · Current results Luminous infrared galaxies · Total luminosities: 10 - 100 times the luminosity of the Milky Way · ~90% of energy emitted at IR wavelengths · Galaxy evolution is hidden behind dust! 11 12 · 10 <LIR(L ) < 10 ⊙ The Bird · Almost all are interacting and/or merging systems Vaisanen+2007 1 · SFR typically above 50M yr− ⊙ The Antennae May also have AGN contribution Whitmore+1997 · (especially in the most luminous ones -- e.g. ULIRGs) · A significant contribution toward the cosmic SFR LIRGs and the co-moving IR energy density The IR luminosity function of galaxies at z =1andz ∼ 233 TOTAL 1e+09 TOTAL Elbaz+2012 LIRG ) -3 Le Floch+2005 Cowie+2004 Mpc ULIRG sun LIRG Caputi+2007 (L IR Gruppioni+2013 ! 1e+08 ULIRG 0 0.5 1 1.5 2 Redshift Caputi+2007Fig. 15.— The evolution of the comoving bolometric IR luminosity density with redshift. The ﬁlled upward-pointing triangle and circle at redshifts z =1andz =1.93 indicate the estimations of the respective bolometric IR luminosity density obtained in this work: ± × 9 +1.2 × 8 −3 ΩIR =(1.2 0.2) 10 and (6.6−1.0) 10 L"Mpc .Thedensityatz =0.2hasbeenobtainedfromthebolometricIRLFderived from the 8 µmLF byHuangetal. (2006). Theredthicksolidlinecorresponds to an interpolation between these redshifts, assuming a x [(1+z2)/(1+z1)] evolution.
[Show full text]