DOCSLIB.ORG

The Sun and the Stars

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Sun and the Stars The Sun and the Stars The Sun and the Stars Dr Matt Burleigh The Sun and the Stars Dr Matt Burleigh The Sun and the Stars Classification of stellar spectra Potted History : 1802 William Wallaston – showed that the spectrum of the sun is not simply a continuous spectrum, but is broken up by a series of dark lines (absorption lines). 1814 Joseph Fraunhofer identified ~600 lines in the solar spectrum and measured wavelengths for approx half. that number. Lines now known as Fraunhofer lines. 1863 Angelo Secchi – crude spectral typing 1864 William Huygens matched some of the Fraunhofer lines to absorption lines seen in the spectra of other stars. 1890s Edward Pickering (Harvard College Observatory) starts project to obtain spectra of all stars observed down to 8th magnitude Subsequently shown that : small number of distinct patterns of absorption lines seen in stellar spectra → Spectral classification Dr Matt Burleigh The Sun and the Stars Spectral Classification – Harvard Classification scheme Work originally started by Henry Draper, continued by Annie Jump Cannon in 1910s, results published in the Henry Draper Catalogue. Extended version of HD catalogue contains spectra of 225,000 stars down to 9th magnitude. Annie Jump Cannon – spectra are dominated by lines of Hydrogen and Helium and small amounts of metals. Original scheme had classes OBAFGKM (now extended to L, T and Y dwarfs) Most important lines are Balmer series of H, neutral and singly ionised He, Fe, Ca H and K doublet, the G band (CH molecule), neutral Ca, metal lines and Ti O. excitation-ionisation sequence Scheme is based on (i) absence of lines (ii) line strengths (W(λ)) (iii) line ratios Dr Matt Burleigh The Sun and the Stars The Hertzsprung-Russell Diagram (E. Hertzsprung and H.N. Russell) Plot of surface temperature versus luminosity, or colour (e.g. B-V) versus absolute magnitude M, and various other combinations bright Can distinguish between early type and late-type stars dim Hot Cool Dr Matt Burleigh The Sun and the Stars HCS is a temperature classification scheme – why? Once a star has formed, there is little mixing of the core and surface material, and few chemical reactions → spectral differences reflect primarily differences in the surface temperature O 50,000 K strong He+ lines, no H lines B 20,000 K strong neutral He lines, v. weak H lines A 10,000 K Strongest H lines, weak Ca+ emerge F 7,500 K H grows weaker,Ca+ becomes stronger, metals G 6,000 K Strong Ca+,Fe+ and other metals , H weaker K 4,000 K Strong metal lines, weak CH,CN bands emerge M 3,500 K strong TiO and VO emerge and strengthen Cannon - further subdivided classes from 0 to 9 (0 hotter, 9 cooler), so that F5, lies halfway between F0 and G0. In this scheme the Sun is classed as G2 Dr Matt Burleigh The Sun and the Stars Harvard classification scheme Type Colour Surface Temp. Characteristics Examples O Blue >25,000 K singly ionised He in emission or 10 Lac absorption. Strong UV continuum B Blue 11,000-25,000 neutral He lines in absorption Rigel, Spica A Blue 7,500-11,000 H lines at max strength for AO, Sirius, Vega decreasing from AO-A9 F Blue to White 6000-7500 metallic lines emerge and strengthen Canopus, Procyon G White to Yellow 5000-6000 lines of neutral metals, Ca+ Fe+ Sun, Capella K Orange to Red 3500-5000 metallic lines dominate, weak blue Arcturus, continuum Aldebaran M Red <3,500 molecular bands of TiO noticeable Betelgeuse Dr Matt Burleigh Dr Matt Burleigh The Sun and the Stars Examples spectral classification sequences Dr Matt Burleigh The Sun and the Stars 1943 Yerkes SCS (or MKK – named after Morgan, Keenan and Kellman) Extends Harvard classification by using line shapes to estimate surface gravities GM * g s = 2 R* MKK luminosity classification Ia luminous Supergiants Ib less luminous Supergiants II luminous Giants III normal Giants IV sub Giants V main sequence stars (dwarfs) VI sub Dwarfs In this extended scheme the sun is classified as G2V Dr Matt Burleigh dwarf stars : smaller radii higher surface gravity c.f. giants therefore higher surface density and higher surface pressure – under higher pressure atoms collide more frequently, collisions shorten lifetime of excited state. smaller Δt, larger ΔE (ΔE Δt ≈ h/2π) => lines are broader! also at a given temperature, T, atoms are thermalised more easily at lower pressure Dr Matt Burleigh The Sun and the Stars MKK luminosity classification Dr Matt Burleigh Dr Matt Burleigh The Sun and the Stars Additional classes Wolf Rayet, W or WR – mostly He atmos. - dying supergiants with fast stellar winds subtypes WC, WN or WO (for Carbon, Nitrogen and Oxygen) (Possible GRB/Hypernovae progenitors) Carbon stars, C (originally R and N classification), red-giants/supergiants near end of lives with excess, Carbon in atmosphere WDs, D – stars are no longer undergoing thermonuclear reactions, simply cooling subclasses designated A,B,O,Q,Z,C,X depending on optical lines present (ie atmospheric composition) L stars,T,Y dwarfs – Cool stars, T and Y dwarfs are not massive enough to undergo nuclear fusion (Brown dwarfs) Dr Matt Burleigh The Sun and the Stars Since spectral type is essentially a temperature sequence, we can construct a colour-magnitude diagram, a diagram of Absolute magnitude Mv versus colour, e.g. Hyades open cluster Colour magnitude diagrams can be used to estimate distances – spectroscopic parallax Dr Matt Burleigh The Sun and the Stars Spectroscopic parallax From a stars spectrum, we can identify i) Spectral type (or colour) These fix a position on the HR diagram from which ii) Luminosity class we can measure Mv Since, m − M = 5logd − 5 , the observed apparent magnitude m gives us the distance modulus, and hence the distance to the star Dr Matt Burleigh The Sun and the Stars Colour-colour diagrams NB a colour is just a flux ratio If stars radiated like blackbodies then a colour-colour plot would BB be unique and follow a straight line The kink in the “lazy S” Is due to the Balmer U-B discontinuity (BD at 3640 falls into U-band) B-V Dr Matt Burleigh The Sun and the Stars When we looks at young clusters and globular clusters their colour-magnitude diagrams appear very different Globular clusters consist of ~half a million stars gravitationally bound, and located above the plane of the galaxy. They are old metal poor stars. Show extensive red-giant,AGB and horizontal branch As well as main sequence Young open clusters are metal rich pop 1 stars. Dominated by their main sequence stars, they are young so very few stars have evolved off of the main sequence. Age can be determined from the location of the turn-off point, younger clusters will turn off at higher luminosities Dr Matt Burleigh The Sun and the Stars Globular cluster schematic colour-magnitude diagram Dr Matt Burleigh .
Load more

Recommended publications
  • Stellar Spectral Classification of Previously Unclassified Stars Gsc 4461-698 and Gsc 4466-870" (2012)
    University of North Dakota UND Scholarly Commons Theses and Dissertations Theses, Dissertations, and Senior Projects January 2012 Stellar Spectral Classification Of Previously Unclassified tS ars Gsc 4461-698 And Gsc 4466-870 Darren Moser Grau Follow this and additional works at: https://commons.und.edu/theses Recommended Citation Grau, Darren Moser, "Stellar Spectral Classification Of Previously Unclassified Stars Gsc 4461-698 And Gsc 4466-870" (2012). Theses and Dissertations. 1350. https://commons.und.edu/theses/1350 This Thesis is brought to you for free and open access by the Theses, Dissertations, and Senior Projects at UND Scholarly Commons. It has been accepted for inclusion in Theses and Dissertations by an authorized administrator of UND Scholarly Commons. For more information, please contact [email protected]. STELLAR SPECTRAL CLASSIFICATION OF PREVIOUSLY UNCLASSIFIED STARS GSC 4461-698 AND GSC 4466-870 By Darren Moser Grau Bachelor of Arts, Eastern University, 2009 A Thesis Submitted to the Graduate Faculty of the University of North Dakota in partial fulfillment of the requirements For the degree of Master of Science Grand Forks, North Dakota December 2012 Copyright 2012 Darren M. Grau ii This thesis, submitted by Darren M. Grau in partial fulfillment of the requirements for the Degree of Master of Science from the University of North Dakota, has been read by the Faculty Advisory Committee under whom the work has been done and is hereby approved. _____________________________________ Dr. Paul Hardersen _____________________________________ Dr. Ronald Fevig _____________________________________ Dr. Timothy Young This thesis is being submitted by the appointed advisory committee as having met all of the requirements of the Graduate School at the University of North Dakota and is hereby approved.
    [Show full text]
  • The 10 Parsec Sample in the Gaia Era?,?? C
    A&A 650, A201 (2021) Astronomy https://doi.org/10.1051/0004-6361/202140985 & c C. Reylé et al. 2021 Astrophysics The 10 parsec sample in the Gaia era?,?? C. Reylé1 , K. Jardine2 , P. Fouqué3 , J. A. Caballero4 , R. L. Smart5 , and A. Sozzetti5 1 Institut UTINAM, CNRS UMR6213, Univ. Bourgogne Franche-Comté, OSU THETA Franche-Comté-Bourgogne, Observatoire de Besançon, BP 1615, 25010 Besançon Cedex, France e-mail: [email protected] 2 Radagast Solutions, Simon Vestdijkpad 24, 2321 WD Leiden, The Netherlands 3 IRAP, Université de Toulouse, CNRS, 14 av. E. Belin, 31400 Toulouse, France 4 Centro de Astrobiología (CSIC-INTA), ESAC, Camino bajo del castillo s/n, 28692 Villanueva de la Cañada, Madrid, Spain 5 INAF – Osservatorio Astrofisico di Torino, Via Osservatorio 20, 10025 Pino Torinese (TO), Italy Received 2 April 2021 / Accepted 23 April 2021 ABSTRACT Context. The nearest stars provide a fundamental constraint for our understanding of stellar physics and the Galaxy. The nearby sample serves as an anchor where all objects can be seen and understood with precise data. This work is triggered by the most recent data release of the astrometric space mission Gaia and uses its unprecedented high precision parallax measurements to review the census of objects within 10 pc. Aims. The first aim of this work was to compile all stars and brown dwarfs within 10 pc observable by Gaia and compare it with the Gaia Catalogue of Nearby Stars as a quality assurance test. We complement the list to get a full 10 pc census, including bright stars, brown dwarfs, and exoplanets.
    [Show full text]
  • Henry Draper Catalogue Identifications for Tycho-2 Stars
    A&A 386, 709–710 (2002) Astronomy DOI: 10.1051/0004-6361:20020249 & c ESO 2002 Astrophysics Henry Draper catalogue identifications for Tycho-2 stars?,?? C. Fabricius1, V. V. Makarov1,2,3,J.Knude1, and G. L. Wycoff3 1 Copenhagen University Observatory, Juliane Maries Vej 30, 2100 Copenhagen Ø, Denmark 2 Universities Space Research Association, 300 D Street S.W., Washington DC 20024, USA 3 United States Naval Observatory, 3450 Massachusetts Ave N.W., Washington DC 20392-5420, USA Received 4 January 2002 / Accepted 14 February 2002 Abstract. We present identifications in the Tycho-2 Catalogue, for 99.8 per cent of the stars in the Henry Draper Catalogue and for 96 per cent of the Henry Draper Extensions. Key words. stars: fundamental parameters – catalogs 1. Introduction Table 1. The number of stars in various parts of the Henry Draper catalogue, and the final number found in Tycho-2. The The recently published Tycho-2 Catalogue (Høg et al. section of HDE covering the Large Magellanic Cloud is shown 2000), provides only cross references to the Tycho-1 and separately. Hipparcos Catalogues (ESA 1997). HD identifications are widely used and give direct access to the one dimen- catalogue stars found rate sional spectral classifications in the HD catalogue (Cannon HD 225 300 224 869 0.998 & Pickering 1918–1924; Cannon 1925–1936; Cannon & HDE\LMC 44 950 43 356 0.965 Mayall 1949) and to the two dimensional classifications HDE∩LMC 1900 1459 0.768 in the Michigan catalogue (Houk et al. 1975–1999), which HDEC 86 933 83 789 0.964 presently covers the basic HD stars south of declina- all 359 083 353 473 0.984 tion +5◦.
    [Show full text]
  • A History of Star Catalogues
    A History of Star Catalogues © Rick Thurmond 2003 Abstract Throughout the history of astronomy there have been a large number of catalogues of stars. The different catalogues reflect different interests in the sky throughout history, as well as changes in technology. A star catalogue is a major undertaking, and likely needs strong justification as well as the latest instrumentation. In this paper I will describe a representative sample of star catalogues through history and try to explain the reasons for conducting them and the technology used. Along the way I explain some relevent terms in italicized sections. While the story of any one catalogue can be the subject of a whole book (and several are) it is interesting to survey the history and note the trends in star catalogues. 1 Contents Abstract 1 1. Origin of Star Names 4 2. Hipparchus 4 • Precession 4 3. Almagest 5 4. Ulugh Beg 6 5. Brahe and Kepler 8 6. Bayer 9 7. Hevelius 9 • Coordinate Systems 14 8. Flamsteed 15 • Mural Arc 17 9. Lacaille 18 10. Piazzi 18 11. Baily 19 12. Fundamental Catalogues 19 12.1. FK3-FK5 20 13. Berliner Durchmusterung 20 • Meridian Telescopes 21 13.1. Sudlich Durchmusterung 21 13.2. Cordoba Durchmusterung 22 13.3. Cape Photographic Durchmusterung 22 14. Carte du Ciel 23 2 15. Greenwich Catalogues 24 16. AGK 25 16.1. AGK3 26 17. Yale Bright Star Catalog 27 18. Preliminary General Catalogue 28 18.1. Albany Zone Catalogues 30 18.2. San Luis Catalogue 31 18.3. Albany Catalogue 33 19. Henry Draper Catalogue 33 19.1.
    [Show full text]
  • The Astronomical Zoo: Discovery and Classification
    Theme 6: The Astronomical Zoo: discovery and classification 6.1 Discovery As discussed earlier, astronomy is atypical among the exact sciences in that discovery normally precedes understanding, sometimes by many years. Astronomical discovery is usually driven by availability of technology rather than by theoretical predictions or speculation. Figure 6.1, redrawn from Martin Harwit’s Cosmic Discovery (MIT Press, 1984), show how the rate of disco- very of “astronomical phenomena” (i.e. classes of object, rather than properties such as dis- tance) has increased over time (the line is a rough fit to an exponential), and 50 the age of the necessary technology at the time the discovery was made. (I 40 have not attempted to update Harwit’s data, because the decision as to what 30 constitutes a new phenomenon is sub- 20 jective to some degree; he puts in seve- ral items that I would not have regar- 10 ded as significant, omits some I would total numberof classes have listed, and doesn’t always assign 0 the same date as I would.) 1550 1600 1650 1700 1750 1800 1850 1900 1950 date Note that the pace of discoveries accel- erates in the 20th century, and the time Impact of new technology lag between the availability of the ne- 15 cessary technology and the actual dis- covery decreases. This is likely due to 10 the greater number of working astro- <1954 nomers: if the technology to make the 5 discovery exists, someone will make it. 1954-74 However, Harwit also makes the point 0 that the discoveries made in the period Numberof discoveries <5 5-10 10-25 25-50 >50 1954−74 were generally (~85%) made Age of required technology (years) by people who were not initially trained in astronomy (mostly physi- Figure 6.1: astronomical discoveries.
    [Show full text]
  • COMMISSIONS 27 and 42 of the I.A.U. INFORMATION BULLETIN on VARIABLE STARS Nos. 4101{4200 1994 October { 1995 May EDITORS: L. SZ
    COMMISSIONS AND OF THE IAU INFORMATION BULLETIN ON VARIABLE STARS Nos Octob er May EDITORS L SZABADOS and K OLAH TECHNICAL EDITOR A HOLL TYPESETTING K ORI KONKOLY OBSERVATORY H BUDAPEST PO Box HUNGARY IBVSogyallakonkolyhu URL httpwwwkonkolyhuIBVSIBVShtml HU ISSN 2 CONTENTS 1994 No page E F GUINAN J J MARSHALL F P MALONEY A New Apsidal Motion Determination For DI Herculis ::::::::::::::::::::::::::::::::::::: D TERRELL D H KAISER D B WILLIAMS A Photometric Campaign on OW Geminorum :::::::::::::::::::::::::::::::::::::::::::: B GUROL Photo electric Photometry of OO Aql :::::::::::::::::::::::: LIU QUINGYAO GU SHENGHONG YANG YULAN WANG BI New Photo electric Light Curves of BL Eridani :::::::::::::::::::::::::::::::::: S Yu MELNIKOV V S SHEVCHENKO K N GRANKIN Eclipsing Binary V CygS Former InsaType Variable :::::::::::::::::::: J A BELMONTE E MICHEL M ALVAREZ S Y JIANG Is Praesep e KW Actually a Delta Scuti Star ::::::::::::::::::::::::::::: V L TOTH Ch M WALMSLEY Water Masers in L :::::::::::::: R L HAWKINS K F DOWNEY Times of Minimum Light for Four Eclipsing of Four Binary Systems :::::::::::::::::::::::::::::::::::::::::: B GUROL S SELAN Photo electric Photometry of the ShortPeriod Eclipsing Binary HW Virginis :::::::::::::::::::::::::::::::::::::::::::::: M P SCHEIBLE E F GUINAN The Sp otted Young Sun HD EK Dra ::::::::::::::::::::::::::::::::::::::::::::::::::: ::::::::::::: M BOS Photo electric Observations of AB Doradus ::::::::::::::::::::: YULIAN GUO A New VR Cyclic Change of H in Tau ::::::::::::::
    [Show full text]
  • WIDC-A-Ras Directory of Astronomical Data Files
    Tin Mo. '« i WIDC-A-RaS 78-05 National Space Science Data Center/ World Data Center A For Rockets and Satellites Directory of Astronomical Data Files September 1978 PREFACE This Directory of Astronomical Data Files has been prepared by the Data Task Force of the Interagency Coordination Committee for Astronomy (ICCA) in cooperation with the National Space Science Data Center (NSSDC). The purpose of the Directory is to provide a listing.which will enable a user to locate stellar and extragalactic data sources keyed along with sufficient descriptive information to permit him to assess the value of the files for his use as well as the status and availability of the com- pilations. An ad hoc committee of the Federal Council for Science and Technol- ogy, ICCA, was composed of representatives from each of the major Federal agencies funding astronomical research. Its charge to the Data Task Force was "to outline a sequence of steps that the Federal agencies might take to coordinate the archiving of astronomical data in order to maximize utility." Among the recommendations contained in its final report, the Task Force advocated that the Federal, agencies "prepare a directory of astronomical data centers and other sources for both machine-readable and non-machine-readable data, including type of data, description of file, method of access, person-in-charge, and location for distribution to agen- cies and the astronomical researchers they support." The ICCA subsequent- ly reappointed the Task Force with a revised charge to suggest appropriate steps to carry out its recommendations, including cost estimates and ac- ceptability to the astronomical community.
    [Show full text]
  • Star Names.Cwk
    The Names of the Stars Naming stars is an enormous task. Even without a telescope, the eye can see thousands of stars. Several ways exist to name stars. Traditional Names: Many bright stars have names given to them in the past. Most of these names are Arabic. Vega, Capella, Betelgeuse and Sadr are examples of traditional Arabic names. Fewer than 1000 stars have such names. Bayer System: One way to name stars is to use a system. In the early seventeenth century the astronomer Johann Bayer created such a system. He gave the brightest star in each constellation a name consisting of the greek letter α (alpha) followed by the genitive form the constellation name (the genitive form is equivalent to the possessive case in English). Other stars receive names in order of brightness going down the greek alphabet. The Bayer system gives clues to a stars brightness and location. Unfortunately it Greek alphabet only has 24 letters. Flamsteed System: In the early eighteenth century John Flamsteed devised a new naming system that could name large numbers of stars. he gave each star a number starting with the westernmost star in each constellation. This system could name stars in large numbers. Catalog Names: Several large catalogs of stars exist. These catalogs gives stars numbers. The Bonner Durchmusterung gives stars BD numbers. Stars with HD numbers come from the Henry Draper Catalogue. The Smithsonian Astrophysical Observatory Star catalog uses SAO number while the Hubble Space Telescope Guide Star catalog gives stars HGC numbers. All these systems are in use. This makes it possible for the same star to have several names.
    [Show full text]
  • Harvard's Computers
    Prior to the nineteenth-century, little is written of women’s contributions in astronomy. In most astronomy texts, you will find no mention of Hypatia of Alexandria, considered the first woman astronomer. Most historians consider her brutal death in the early fifth-century to be the beginning of the “Dark Ages.” There is no mention of Hildegard von Bingen (1099-1179) whose ideas on “universal gravitation” predate Isaac Newton’s, nor Sophia Brahe, Tycho’s younger sister. It was not until the director of Harvard Observatory became disgruntled with the sloppy work of his male assistant, saying his housekeeper could do better, that women were readily accepted into the study of astronomy. 1 Harvard College Observatory was founded in 1839, a time when astronomy was beginning to be taught as a science subject in its own right, instead of as an extension of philosophy. This was also a time when universities were receiving funds for astronomical research, an endeavor previously pursued by learned men of means. Astronomy is a science requiring observations and exact calculations, particularly of positions of celestial objects. This was tedious work completed by “computers.” Originally, young men performed these tasks. This changed when Edward Charles Pickering became director of the observatory in 1877 and opened the doors of astronomy to women. 2 Pickering was sympathetic to the women’s suffrage movement and recognized that there was a new breed of women, women that were educated. He also realized that with the new technologies of the time, telescopes that were readily available and astrophotography, that the data collection was happening faster than could be catalogued so as to be useful.
    [Show full text]
  • Dust Around Main-Sequence and Supergiant Stars
    Dust around Main-Sequence and Supergiant Stars A Thesis submitted for the Degree of Doctor of Philosophy of the University of London by Roger James Sylvester UCL Department of Physics & Astronomy University College London University of London 1995 ProQuest Number: 10044337 All rights reserved INFORMATION TO ALL USERS The quality of this reproduction is dependent upon the quality of the copy submitted. In the unlikely event that the author did not send a complete manuscript and there are missing pages, these will be noted. Also, if material had to be removed, a note will indicate the deletion. uest. ProQuest 10044337 Published by ProQuest LLC(2016). Copyright of the Dissertation is held by the Author. All rights reserved. This work is protected against unauthorized copying under Title 17, United States Code. Microform Edition © ProQuest LLC. ProQuest LLC 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, Ml 48106-1346 A bstract This thesis is a study of the properties of the dust around two rather different types of star. The first part is concerned with the mid-infrared emission from a sample of 16 M-type supergiants. As weU as silicate emission features, seven of the stars showed the UIR (unidentified infrared) emission bands, associated with carbonaceous material. According to standard theory, aU the carbon in the outflows from these oxygen-rich stars should be bound up in CO molecules, preventing the formation of carbonaceous dust. The results were interpreted in terms of a non-equilibrium chemical model, which invoked chromospheric UV photons to dissociate CO, allowing carbonaceous material to form, and to excite the observed UIR-band emission.
    [Show full text]
  • Journal of Double Star Observations Speckle Interferometry of Close Visual Binaries
    Journal of Double Star Observations Speckle Interferometry of Close Visual Binaries Editors: Russell Genet, Eric Weise, R. Kent Clark, & Vera Wallen Associate Editor: Meghan Legg Foreword: David Rowe Vol. 11 No. 1S September 15, 2015 Contents Editorial 177 Foreword 178 David Rowe Speckle Interferometry of Close Visual Binaries 183 Russell M. Genet Two New Triple Star Systems with Detectable Inner Orbital Motions and 200 Speckle Interferometry of 40 Other Double Stars Russell M. Genet, Henry Zirm, Francisco Rica, Joseph Richards, David Rowe, and Daniel Gray Double Star Research with Speckle Interferometry 214 Cameron Allen, Jason Goad, Ryan Morshead, Kaitlin McArdle, and Eric Weise A Novel System for Classifying Binary Orbital Solutions 219 Eric D. Weise and Russell M. Genet Portable Speckle Interferometry Camera Checkout at Kitt Peak 226 Russell Genet, Tom Smith, R. Kent Clark, Paul Wren, Hillary Mathis, Dave Summers, and Brent Hansey Kitt Peak Speckle Interferometry of Close Visual Binary Stars 234 David Rose, Tohams C. Smith, Alex Teiche, Richard Harshaw, Daniel Wallace, Eric Weise, Edward Wiley, Grady Boyce, Patrick Boyce, Detrick Branston, Kayla Chaney, R. Kent Clark, Chris Estrada, Reed Estrada, Thomas Frey, Wayne Green, Nathalie Haurberg, Greg Jones, John Kenney, Sheri Loftin, Izak McGieson, Rikita Patel, Josh Plummer, John Ridgely, Mark Truebood, Don Westergren, and Paul Wren First Speckle Interferometry Observation of Binary BU 1292 245 Meryl Adam, Stephanie Roberts, Miriam Schenk, Carmen VanRonk, Tara Loayza, Russell M. Genet, Bobby Johnson, Thomas C. Smith, and Paul Wren Speckle Interferometry Observation of Binary WDS 01528-0447 252 Meryl Adam, Eric Weiss, Bobby Johnson, Barron Lutes, Katie Huck, Ankur Patel, and Russell Genet International Speckle Interferometry Collaboration 256 Eric Weise, Yuan-Yuan Ding, Chaoyan Wang, and Russell M.
    [Show full text]
  • Nature of Stars 2
    Killer Skies ‣ Homework 6 due Monday ‣ Night Observing continuing ‣ Last time: Nature of Stars ‣ Today: Nature of Stars 2 Music: We are all connected – Symphony of Science 1 Night Observing Night Observing probably last week ‣ if you do it, need to go one night ‣ allow about 1 hour When: W, Th: 7-9pm (to see Venus south of Marrow Plots) 3 observing stations: ‣ Large telescope in observatory dome ‣ 2 outdoor telescopes ‣ Night sky constellation tour Subscribe to Night Observing Status Blog http://illinois.edu/blog/view/413 Get weather cancellation updates Assignment details on class website Read rubric before you go! ‣ Complete report due on or before Nov. 11th 2 Brightness vs. distance follows the inverse-square law If the distance 1 between two objects doubles, the apparent brightness drops by a factor of 4! units) Brightness (arbitrary 1/4 1/9 1/25 1 2 3 4 5 6 Distance (arbitrary units) 3 Graph shows how the brightness drops with distance. Thought Ques9on How would the apparent brightness of Alpha Centauri change if it were three times farther away? A. It would be only 1/3 as bright B. It would be only 1/6 as bright C. It would be only 1/9 as bright D. It would be three times brighter 4 Answer: C. 3 squared is 9. And it gets dimmer. So Now We Need the Distance We know that the stars must be very far away. ‣ They don’t move much as we orbit the Sun. But measuring the distance is a hard problem. We’ve only had the technology to do it for the last 200 yrs.
    [Show full text]