DOCSLIB.ORG

Ganymede Titan Callisto Io Moon Europa Triton Mimas

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Ganymede Titan Callisto Io Moon Europa Triton Mimas News 8 Wednesday, July 10, 2013 Orange County Register 1 ASTRONOMY A LUNAR ROLL CALL There are a total of 146 moons in our solar system with another 25 awaiting official recognition by the International Astronomical Union. NASA’s official list of moons: EARTH MARS 1. Moon 1. Phobos MOONS 2. Deimos JUPITER It’s nice to know that whatever planet you visit — with the 1. Io 26. Isonoe exception of sun-drenched Mercury and Venus — you’ll find a 2. Europa 27. Praxidike 3. Ganymede 28. Autonoe gorgeous moon hitting your eye like a big pizza pie. Here’s a look at 4. Callisto 29. Thyone 5. Amalthea 30. Hermippe some of our solar system’s notable natural satellites: 6. Himalia 31. Aitne 7. Elara 32. Eurydome 8. Pasiphae 33. Euanthe 9. Sinope 34. Euporie Larger than Mercury and Pluto, Gany- 10. Lysithea 35. Orthosie GANYMEDE mede is three-quarters the size of Mars. 11. Carme 36. Sponde The surface of Ganymede is mostly ice, 12. Ananke 37. Kale NASA says, but with some rock thrown Orbits: 13. Leda 38. Pasithee Jupiter in. Deep grooves called “slucus” run Diameter: 14. Thebe 39. Hegemone 3,270 miles across the surface, yet the craters have 15. Adrastea 40. Mneme Discovered: 1640 little depth to them. Ganymede has an 16. Metis 41. Aoede by Italian astronomer oxygen atmosphere, but far too thin to 17. Callirrhoe 42. Thelxinoe Galileo Galilei support life as we know it. 18. Themisto 43. Arche 19. Megaclite 44. Kallichore 20. Taygete 45. Helike Titan is the only moon in the solar 21. Chaldene 46. Carpo TITAN system known to have clouds and a 22. Harpalyke 47. Eukelade thick, planet-like atmosphere. The 23. Kalyke 48. Cyllene atmosphere is mostly nitrogen but with Orbits: 24. Iocaste 49. Kore Saturn methane and ethane present. NASA 25. Erinome 50. Herse Diameter: 3,202 miles speculates that the rain there could be Discovered: 1655 “gasoline-like” liquids. Air pressure on PROVISIONAL MOONS by Dutch astronomer Titan’s surface is roughly the same 51. S/2003 J2 59. S/2003 J16 Christiaan Huygens found at the bottom of a swimming pool. 52. S/2003 J3 60. S/2003 J18 53. S/2003 J4 61. S/2003 J19 54. S/2003 J5 62. S/2003 J23 Nearly the size of Mercury, Callisto is 55. S/2003 J9 63. S/2010 J 1 CALLISTO the most heavily-cratered object in the 56. S/2003 J10 64. S/2010 J 2 solar system. NASA considers it a dead 57. S/2003 J12 65. S/2011 J1 world — it’s the largest object in our 58. S/2003 J15 66. S/2011 J2 Orbits: Jupiter solar system that has no geological Diameter: 2,996 miles activity. Its orbit keeps it well outside Discovered: 1640 of Jupiter’s radiation belts and the tidal SATURN by Italian astronomer forces that give its sister moon, Io, 1. Mimas 28. Skathi Galileo Galilei volcanic life. 2. Enceladus 29. Siarnaq 3. Tethys 30. Thrymr 4. Dione 31. Narvi Io’s elliptical orbit around the enor- 5. Rhea 32. Methone IO mous planet Jupiter creates tides of 6. Titan 33. Pallene 330 feet. This results in heat that 7. Hyperion 34. Polydeuces causes Io to be the most volcanically 8. Iapetus 35. Daphnis Orbits: Jupiter active body in the solar system. Volca- 9. Erriapus 36. Aegir Diameter: 2,264 miles nic plumes rise nearly 200 miles above 10. Phoebe 37. Bebhionn Discovered: 1640 the surface. Scientists think Io is 11. Janus 38. Bergelmir by Italian astronomer mostly molten sulfur and that its 12. Epimetheus 39. Bestla Galileo Galilei atmosphere is mostly sulfur dioxide. 13. Helene 40. Farbauti 14. Telesto 41. Fenrir 15. Calypso 42. Fornjot Earth’s lone companion has no atmo- 16. Kiviuq 43. Hati MOON sphere to burn up meteors, resulting in 17. Atlas 44. Hyrrokkin the familiar rough, pockmarked surface. 18. Prometheus 45. Kari The lighter areas are mountains. The 19. Pandora 46. Loge Orbits: Earth darker areas are flatter areas where 20. Pan 47. Skoll Diameter: 2,152 miles lava pooled from no-longer-active 21. Ymir 48. Surtur volcanoes. Recent studies have 22. Paaliaq 49. Greip suggested there may be water ice 23. Tarvos 50. Jarnsaxa present at the lunar poles, NASA says. 24. Ijiraq 51. Tarqeq 25. Suttungr 52. Anthe 26. Mundilfari 53. Aegaeon Scientists think Europa contains twice 27. Albiorix EUROPA as much water as does Earth — what you PROVISIONAL MOONS see there might be a thin crust of ice covering slushy, salty ice. Europa’s 54. S/2004 S7 59. S/2006 S3 Orbits: Jupiter elliptical orbit creates strong tides, 55. S/2004 S12 60. S/2007 S2 Diameter: 1,940 miles which may explain the enormous cracks 56. S/2004 S13 61. S/2007 S3 Discovered: 1640 in the ice. These tidal forces also warm 57. S/2004 S17 62. S/2009 S1 by Italian astronomer the moon just a bit, giving scientists 58. S/2006 S1 Galileo Galilei hope that life might possibly exist there. URANUS Triton’s surface resembles a canta- 1. Cordelia 15. Francisco TRITON loupe, NASA says. Ice volcanoes spew 2. Ophelia 16. Ariel what is probably a mixture of liquid 3. Bianca 17. Umbriel nitrogen, methane and dust into the air, 4. Cressida 18. Titania Orbits: Neptune where it freezes and snows back onto 5. Desdemona 19. Oberon Diameter: 1,682 miles the surface. Triton orbits in a direction 6. Juliet 20. Caliban Discovered: 1846 opposite Neptune’s rotation. As a 7. Portia 21. Stephano by English astronomer result, the moon is gradually slowing 8. Rosalind 22. Trinculo William Lassell and dropping closer to the surface. 9. Mab 23. Sycorax 10. Belinda 24. Margaret 11. Perdita 25. Prospero Compared to the other moons on this 12. Puck 26. Setebos MIMAS list, Mimas is tiny. But it’s famous for 13. Cupid 27. Ferdinand an obvious reason: That enormous 14. Miranda crater — 88 miles across and with walls Orbits: Saturn three miles high — makes this moon look NEPTUNE Diameter: 246 miles a lot like the Death Star space station Discovered: 1789 in the “Star Wars” movies. Mimas’ orbit 1. Triton 8. Proteus by English astronomer is thought to be responsible for gaps 2. Nereid 9. Halimede William Herschel and lumps in some of Saturn’s rings. 3. Naiad 10. Psamathe 4. Thalassa 11. Sao 5. Despina 12. Laomedeia Source: NASA’S Jet ALL IMAGES FROM NASA AND NASA’S COMPILED BY CHARLES APPLE, 6. Galatea 13. Neso Propulsion Laboratory JET PROPULSION LABORATORY ORANGE COUNTY REGISTER 7. Larissa.
Load more

Recommended publications
  • Cassini Update
    Cassini Update Dr. Linda Spilker Cassini Project Scientist Outer Planets Assessment Group 22 February 2017 Sols%ce Mission Inclina%on Profile equator Saturn wrt Inclination 22 February 2017 LJS-3 Year 3 Key Flybys Since Aug. 2016 OPAG T124 – Titan flyby (1584 km) • November 13, 2016 • LAST Radio Science flyby • One of only two (cf. T106) ideal bistatic observations capturing Titan’s Northern Seas • First and only bistatic observation of Punga Mare • Western Kraken Mare not explored by RSS before T125 – Titan flyby (3158 km) • November 29, 2016 • LAST Optical Remote Sensing targeted flyby • VIMS high-resolution map of the North Pole looking for variations at and around the seas and lakes. • CIRS last opportunity for vertical profile determination of gases (e.g. water, aerosols) • UVIS limb viewing opportunity at the highest spatial resolution available outside of occultations 22 February 2017 4 Interior of Hexagon Turning “Less Blue” • Bluish to golden haze results from increased production of photochemical hazes as north pole approaches summer solstice. • Hexagon acts as a barrier that prevents haze particles outside hexagon from migrating inward. • 5 Refracting Atmosphere Saturn's• 22unlit February rings appear 2017 to bend as they pass behind the planet’s darkened limb due• 6 to refraction by Saturn's upper atmosphere. (Resolution 5 km/pixel) Dione Harbors A Subsurface Ocean Researchers at the Royal Observatory of Belgium reanalyzed Cassini RSS gravity data• 7 of Dione and predict a crust 100 km thick with a global ocean 10’s of km deep. Titan’s Summer Clouds Pose a Mystery Why would clouds on Titan be visible in VIMS images, but not in ISS images? ISS ISS VIMS High, thin cirrus clouds that are optically thicker than Titan’s atmospheric haze at longer VIMS wavelengths,• 22 February but optically 2017 thinner than the haze at shorter ISS wavelengths, could be• 8 detected by VIMS while simultaneously lost in the haze to ISS.
    [Show full text]
  • A Deeper Look at the Colors of the Saturnian Irregular Satellites Arxiv
    A deeper look at the colors of the Saturnian irregular satellites Tommy Grav Harvard-Smithsonian Center for Astrophysics, MS51, 60 Garden St., Cambridge, MA02138 and Instiute for Astronomy, University of Hawaii, 2680 Woodlawn Dr., Honolulu, HI86822 [email protected] James Bauer Jet Propulsion Laboratory, California Institute of Technology 4800 Oak Grove Dr., MS183-501, Pasadena, CA91109 [email protected] September 13, 2018 arXiv:astro-ph/0611590v2 8 Mar 2007 Manuscript: 36 pages, with 11 figures and 5 tables. 1 Proposed running head: Colors of Saturnian irregular satellites Corresponding author: Tommy Grav MS51, 60 Garden St. Cambridge, MA02138 USA Phone: (617) 384-7689 Fax: (617) 495-7093 Email: [email protected] 2 Abstract We have performed broadband color photometry of the twelve brightest irregular satellites of Saturn with the goal of understanding their surface composition, as well as their physical relationship. We find that the satellites have a wide variety of different surface colors, from the negative spectral slopes of the two retrograde satellites S IX Phoebe (S0 = −2:5 ± 0:4) and S XXV Mundilfari (S0 = −5:0 ± 1:9) to the fairly red slope of S XXII Ijiraq (S0 = 19:5 ± 0:9). We further find that there exist a correlation between dynamical families and spectral slope, with the prograde clusters, the Gallic and Inuit, showing tight clustering in colors among most of their members. The retrograde objects are dynamically and physically more dispersed, but some internal structure is apparent. Keywords: Irregular satellites; Photometry, Satellites, Surfaces; Saturn, Satellites. 3 1 Introduction The satellites of Saturn can be divided into two distinct groups, the regular and irregular, based on their orbital characteristics.
    [Show full text]
  • Astrometric Reduction of Cassini ISS Images of the Saturnian Satellites Mimas and Enceladus? R
    A&A 551, A129 (2013) Astronomy DOI: 10.1051/0004-6361/201220831 & c ESO 2013 Astrophysics Astrometric reduction of Cassini ISS images of the Saturnian satellites Mimas and Enceladus? R. Tajeddine1;3, N. J. Cooper1;2, V. Lainey1, S. Charnoz3, and C. D. Murray2 1 IMCCE, Observatoire de Paris, UMR 8028 du CNRS, UPMC, Université de Lille 1, 77 av. Denfert-Rochereau, 75014 Paris, France e-mail: [email protected] 2 Astronomy Unit, School of Physics and Astronomy, Queen Mary University of London, Mile End Road, London E1 4NS, UK 3 Laboratoire AIM, UMR 7158, Université Paris Diderot – CEA IRFU – CNRS, Centre de l’Orme les Merisiers, 91191 Gif-sur-Yvette Cedex, France Received 2 December 2012 / Accepted 6 February 2013 ABSTRACT Aims. We provide astrometric observations of two of Saturn’s main satellites, Mimas and Enceladus, using high resolution Cassini ISS Narrow Angle Camera images. Methods. We developed a simplified astrometric reduction model for Cassini ISS images as an alternative to the one proposed by the Jet Propulsion Labratory (JPL). The particular advantage of the new model is that it is easily invertible, with only marginal loss in accuracy. We also describe our new limb detection and fitting technique. Results. We provide a total of 1790 Cassini-centred astrometric observations of Mimas and Enceladus, in right ascension (α) and declination (δ) in the International Celestial Reference Frame (ICRF). Mean residuals compared to JPL ephemerides SAT317 and SAT351 of about one kilometre for Mimas and few hundreds of metres for Enceladus were obtained, in α cos δ and δ, with a standard deviation of a few kilometres for both satellites.
    [Show full text]
  • HOMERIC-ILIAD.Pdf
    Homeric Iliad Translated by Samuel Butler Revised by Soo-Young Kim, Kelly McCray, Gregory Nagy, and Timothy Power Contents Rhapsody 1 Rhapsody 2 Rhapsody 3 Rhapsody 4 Rhapsody 5 Rhapsody 6 Rhapsody 7 Rhapsody 8 Rhapsody 9 Rhapsody 10 Rhapsody 11 Rhapsody 12 Rhapsody 13 Rhapsody 14 Rhapsody 15 Rhapsody 16 Rhapsody 17 Rhapsody 18 Rhapsody 19 Rhapsody 20 Rhapsody 21 Rhapsody 22 Rhapsody 23 Rhapsody 24 Homeric Iliad Rhapsody 1 Translated by Samuel Butler Revised by Soo-Young Kim, Kelly McCray, Gregory Nagy, and Timothy Power [1] Anger [mēnis], goddess, sing it, of Achilles, son of Peleus— 2 disastrous [oulomenē] anger that made countless pains [algea] for the Achaeans, 3 and many steadfast lives [psūkhai] it drove down to Hādēs, 4 heroes’ lives, but their bodies it made prizes for dogs [5] and for all birds, and the Will of Zeus was reaching its fulfillment [telos]— 6 sing starting from the point where the two—I now see it—first had a falling out, engaging in strife [eris], 7 I mean, [Agamemnon] the son of Atreus, lord of men, and radiant Achilles. 8 So, which one of the gods was it who impelled the two to fight with each other in strife [eris]? 9 It was [Apollo] the son of Leto and of Zeus. For he [= Apollo], infuriated at the king [= Agamemnon], [10] caused an evil disease to arise throughout the mass of warriors, and the people were getting destroyed, because the son of Atreus had dishonored Khrysēs his priest. Now Khrysēs had come to the ships of the Achaeans to free his daughter, and had brought with him a great ransom [apoina]: moreover he bore in his hand the scepter of Apollo wreathed with a suppliant’s wreath [15] and he besought the Achaeans, but most of all the two sons of Atreus, who were their chiefs.
    [Show full text]
  • Beauty on Display Plato and the Concept of the Kalon
    BEAUTY ON DISPLAY PLATO AND THE CONCEPT OF THE KALON JONATHAN FINE Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in the Graduate School of Arts and Sciences COLUMBIA UNIVERSITY 2018 © 2018 Jonathan Fine All rights reserved ABSTRACT BEAUTY ON DISPLAY: PLATO AND THE CONCEPT OF THE KALON JONATHAN FINE A central concept for Plato is the kalon – often translated as the beautiful, fine, admirable, or noble. This dissertation shows that only by prioritizing dimensions of beauty in the concept can we understand the nature, use, and insights of the kalon in Plato. The concept of the kalon organizes aspirations to appear and be admired as beautiful for one’s virtue. We may consider beauty superficial and concern for it vain – but what if it were also indispensable to living well? By analyzing how Plato uses the concept of the kalon to contest cultural practices of shame and honour regulated by ideals of beauty, we come to see not only the tensions within the concept but also how attractions to beauty steer, but can subvert, our attempts to live well. TABLE OF CONTENTS Acknowledgements ii 1 Coordinating the Kalon: A Critical Introduction 1 1 The Kalon and the Dominant Approach 2 2 A Conceptual Problem 10 3 Overview 24 2 Beauty, Shame, and the Appearance of Virtue 29 1 Our Ancient Contemporaries 29 2 The Cultural Imagination 34 3 Spirit and the Social Dimension of the Kalon 55 4 Before the Eyes of Others 82 3 Glory, Grief, and the Problem of Achilles 100 1 A Tragic Worldview 103 2 The Heroic Ideal 110 3 Disgracing Achilles 125 4 Putting Poikilia in its Place 135 1 Some Ambivalences 135 2 The Aesthetics of Poikilia 138 3 The Taste of Democracy 148 4 Lovers of Sights and Sounds 173 5 The Possibility of Wonder 182 5 The Guise of the Beautiful 188 1 A Psychological Distinction 190 2 From Disinterested Admiration to Agency 202 3 The Opacity of Love 212 4 Looking Good? 218 Bibliography 234 i ACKNOWLEDGEMENTS “To do philosophy is to explore one’s own temperament,” Iris Murdoch suggested at the outset of “Of ‘God’ and ‘Good’”.
    [Show full text]
  • The Orbits of Saturn's Small Satellites Derived From
    The Astronomical Journal, 132:692–710, 2006 August A # 2006. The American Astronomical Society. All rights reserved. Printed in U.S.A. THE ORBITS OF SATURN’S SMALL SATELLITES DERIVED FROM COMBINED HISTORIC AND CASSINI IMAGING OBSERVATIONS J. N. Spitale CICLOPS, Space Science Institute, 4750 Walnut Street, Suite 205, Boulder, CO 80301; [email protected] R. A. Jacobson Jet Propulsion Laboratory, California Institute of Technology, 4800 Oak Grove Drive, Pasadena, CA 91109-8099 C. C. Porco CICLOPS, Space Science Institute, 4750 Walnut Street, Suite 205, Boulder, CO 80301 and W. M. Owen, Jr. Jet Propulsion Laboratory, California Institute of Technology, 4800 Oak Grove Drive, Pasadena, CA 91109-8099 Received 2006 February 28; accepted 2006 April 12 ABSTRACT We report on the orbits of the small, inner Saturnian satellites, either recovered or newly discovered in recent Cassini imaging observations. The orbits presented here reflect improvements over our previously published values in that the time base of Cassini observations has been extended, and numerical orbital integrations have been performed in those cases in which simple precessing elliptical, inclined orbit solutions were found to be inadequate. Using combined Cassini and Voyager observations, we obtain an eccentricity for Pan 7 times smaller than previously reported because of the predominance of higher quality Cassini data in the fit. The orbit of the small satellite (S/2005 S1 [Daphnis]) discovered by Cassini in the Keeler gap in the outer A ring appears to be circular and coplanar; no external perturbations are appar- ent. Refined orbits of Atlas, Prometheus, Pandora, Janus, and Epimetheus are based on Cassini , Voyager, Hubble Space Telescope, and Earth-based data and a numerical integration perturbed by all the massive satellites and each other.
    [Show full text]
  • Between Arcadia and Crete: Callisto in Callimachus' Hymn to Zeus The
    Between Arcadia and Crete: Callisto in Callimachus’ Hymn to Zeus The speaker of Callimachus’ Hymn to Zeus famously asks Zeus himself whether he should celebrate the god as “Dictaean,” i.e. born on Mt. Dicte in Crete, or “Lycaean,” born on Arcadian Mt. Lycaeus (4-7). When the response comes, “Κρῆτες ἀεὶ ψεῦσται” (“Cretans are always liars,” 8), the hymnist agrees, and for support recalls that the Cretans built a tomb for Zeus, who is immortal (8-9). In so dismissing Cretan claims to truth, the hymnist justifies an Arcadian setting for his ensuing birth narrative (10-41). Curiously, however, after recounting Zeus’s birth and bath, the hymnist suddenly locates the remainder of the god’s early life in Crete after all (42-54). The transition is surprising, not only because it runs counter to the previous rejection of Cretan claims, but also because the Arcadians themselves held that Zeus was both born and raised in Arcadia (Paus. 8.38.2). While scholars have focused on how the ambiguity of two place names (κευθμὸν... Κρηταῖον, 34; Θενάς/Θεναί, 42, 43) misleads the audience and/or prepares them for the abrupt move from Arcadia to Crete (Griffiths 1970 32-33; Arnott 1976 13-18; McLennan 1977 66, 74- 75; Tandy 1979 105, 115-118; Hopkinson 1988 126-127), this paper proposes that the final word of the birth narrative, ἄρκτοιο (“bear,” 41), plays an important role in the transition as well. This reference to Callisto a) allusively justifies the departure from Arcadia, by suggesting that the Arcadians are liars not unlike the Cretans; b) prepares for the hymnist’s rejection of the Cretan account of Helice; and c) initiates a series of heavenly ascents that binds the Arcadian and Cretan portions of the hymn and culminates climactically with Zeus’s own accession to the sky.
    [Show full text]
  • Respicite Astra: a Historic Journey in Astronomy Through Books
    0 Respicite Astra: A Historic Journey in Astronomy through Books RReessppiicciittee AAssttrraa A Historic Journey in Astronomy through Books The Astronomiicall Sociiety of Mallta The Natiionall Liibrary of Mallta The Astronomical Society of Malta The National Library of Malta 1 Respicite Astra: A Historic Journey in Astronomy through Books Respicite Astra A Historic Journey in Astronomy through Books Exhibition held between 25 September – 18 October 2010-09-21 at the National Library, Valletta, Malta on the occasion of Notte Bianca 2010 Introductory Text Mr Victor Farrugia Captions Mr Leonard Ellul Mercer – Pgs 23-24, 57 Mr Alexander Pace – Pgs 25-26, 58, 63, 70 Prof Frank Ventura – Pgs 4, 6-13, 15-18, 21, 27-31, 33, 35-38, 40, 42- 43, 45-48, 50-56, 60-62, 65-69, 72-76, 80, 85, 87, 93 Acknowledgements The Committee of the Astronomical Society of Malta would like to acknowledge the following persons for their kind and generous help in setting up this Exhibition at the Main Hall of the National Library starting on 25th September 2010 during the Notte Bianca event: Mr Fabio Agius (MaltaPost Philatelic Archives) Ms C Michelle Buhagiar (National Library of Malta) Ms Maroma Camilleri National Library of Malta) Mr Leonard Ellul Mercer (Personal capacity) Victor Farrugia (Astronomical Society of Malta) Mr Alexander Pace (Astronomical Society of Malta) Arch Alexei Pace (Astronomical Society of Malta) Ms Joanne Sciberras (National Library of Malta) Mr Tony Tanti (Astronomical Society of Malta) Prof Frank Ventura (University of Malta) Staff of the National Library of Malta Front Image Great Orion Nebula by Mr Leonard Ellul Mercer Production The Astronomical Society of Malta P.O.
    [Show full text]
  • Cassini Observations of Saturn's Irregular Moons
    EPSC Abstracts Vol. 12, EPSC2018-103-1, 2018 European Planetary Science Congress 2018 EEuropeaPn PlanetarSy Science CCongress c Author(s) 2018 Cassini Observations of Saturn's Irregular Moons Tilmann Denk (1) and Stefano Mottola (2) (1) Freie Universität Berlin, Germany ([email protected]), (2) DLR Berlin, Germany 1. Introduction two prograde irregulars are slower than ~13 h, while the periods of all but two retrogrades are faster than With the ISS-NAC camera of the Cassini spacecraft, ~13 h. The fastest period (Hati) is much slower than we obtained photometric lightcurves of 25 irregular the disruption rotation barrier for asteroids (~2.3 h), moons of Saturn. The goal was to derive basic phys- indicating that Saturn's irregulars may be rubble piles ical properties of these objects (like rotational periods, of rather low densities, possibly as low as of comets. shapes, pole-axis orientations, possible global color variations, ...) and to get hints on their formation and Table: Rotational periods of 25 Saturnian irregulars evolution. Our campaign marks the first utilization of an interplanetary probe for a systematic photometric Moon Approx. size Rotational period survey of irregular moons. name [km] [h] Hati 5 5.45 ± 0.04 The irregular moons are a class of objects that is very Mundilfari 7 6.74 ± 0.08 distinct from the inner moons of Saturn. Not only are Loge 5 6.9 ± 0.1 ? they more numerous (38 versus 24), but also occupy Skoll 5 7.26 ± 0.09 (?) a much larger volume within the Hill sphere of Suttungr 7 7.67 ± 0.02 Saturn.
    [Show full text]
  • A Newly-Discovered Accurate Early Drawing of M51, the Whirlpool Nebula
    Journal of Astronomical History and Heritage , 11(2), 107-115 (2008). A NEWLY-DISCOVERED ACCURATE EARLY DRAWING OF M51, THE WHIRLPOOL NEBULA William Tobin 6 rue Saint Louis, 56000 Vannes, France. E-mail: [email protected] and J.B. Holberg Lunar and Planetary Laboratory, University of Arizona, 1541 East University Boulevard, Tucson, AZ 85721, U.S.A. E-mail: [email protected] Abstract: We have discovered a lost drawing of M51, the nebula in which spiral structure was first discovered by Lord Rosse. The drawing was made in April 1862 by Jean Chacornac at the Paris Observatory using Léon Foucault’s newly-completed 80-cm silvered-glass reflecting telescope. Comparison with modern images shows that Chacornac’s drawing was more accurate with respect to gross structure and showed fainter details than any other nineteenth century drawing, although its superiority would not have been apparent at the time without nebular photography to provide a standard against which to judge drawing quality. M51 is now known as the Whirlpool Nebula, but the astronomical appropriation of ‘whirlpool’ predates Rosse’s discovery. Keywords: reflecting telescopes, nebulae, spiral structure, Léon Foucault, Lord Rosse, M51, Whirlpool Nebula 1 REFLECTING TELESCOPES AND SPIRAL STRUCTURE The French physicist Léon Foucault (1819–1868) is the father of the reflecting telescope in its modern form, with large, optically-perfect, metallized glass or ceramic mirrors. Foucault achieved this breakthrough while working as ‘physicist’ at the Paris Observatory in the late 1850s. The largest telescope that he built (Foucault, 1862) had a silvered-glass, f/5.6 primary mirror of 80-cm diameter in a Newtonian configura- tion (see Figure 1).
    [Show full text]
  • When We Get Close, We Hear Things That Can't Be Heard from Afar. We
    THE 15TH SKOLL WORLD FORUM ON SOCIAL ENTREPRENEURSHIP | APRIL 10 -13, 2018, OXFORD UK When we get close, we hear things that can’t be heard from afar. We see things that can’t be seen. And sometimes that makes the difference between acting justly and injustly. – Bryan Stevenson – When we get close, we hear things that can’t be heard from afar. We see things that can’t be seen. And sometimes that makes the difference between acting justly and unjustly. “ – Bryan Stevenson – ” WELCOME TO THE 15TH SKOLL WORLD FORUM In order to address inequality and injustice, we must more deeply understand the current status quo—and how to disrupt it. There is no other way to do this than to engage with, and be close to the people and communities facing deep and persistent biases of all kinds. We’ll hear from community leaders, activists, social entrepreneurs, and innovators who bring a profound appreciation of our shared challenges and who have worked from within and side-by-side with communities to find solutions. THE 15TH SKOLL WORLD FORUM PAGE 4 Perspectives 14 Delegate Engagement 20 Monday 22 Tuesday 28 Wednesday 36 Skoll Awards For Social Entrepreneurship 54 Thursday 64 Friday Photo: Bill Hornstein PERSPECTIVES THE POWER OF PROXIMITY CLOSING DISTANCE & CELEBRATING DIFFERENCE TWEET YOUR EXPERIENCE AT #SKOLLWF 5 what they experience to be unfair. Areas of the human Like many children, my brain linked to recognizing granddaughter resists emotions in others operate according to a sort of ‘neural bedtime by sharing fears golden rule’, responding with that get her parents’ and my generous and altruistic behavior in direct correlation with our attention.
    [Show full text]
  • Homer and Hesiod, Which Ovid Appropriates
    Durham Research Online Deposited in DRO: 14 August 2018 Version of attached le: Published Version Peer-review status of attached le: Peer-reviewed Citation for published item: Ziogas, I. (2018) 'Ovid's Hesiodic voices.', in Oxford handbook to Hesiod. Oxford: Oxford University Press, pp. 377-393. Further information on publisher's website: https://doi.org/10.1093/oxfordhb/9780190209032.013.48 Publisher's copyright statement: Ziogas, Ioannis. Ovid's Hesiodic voices. In The Oxford Handbook of Hesiod. Oxford University Press, August 08, 2018. Oxford Handbooks Online, reproduced by permission of Oxford University Press https://doi.org/10.1093/oxfordhb/9780190209032.013.48 Additional information: Use policy The full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that: • a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders. Please consult the full DRO policy for further details. Durham University Library, Stockton Road, Durham DH1 3LY, United Kingdom Tel : +44 (0)191 334 3042 | Fax : +44 (0)191 334 2971 https://dro.dur.ac.uk Ovid’s Hesiodic Voices Oxford Handbooks Online Ovid’s Hesiodic Voices Ioannis Ziogas The Oxford Handbook of Hesiod Edited by Alexander C. Loney and Stephen Scully Print Publication Date: Sep 2018 Subject: Classical Studies, Classical Poetry Online Publication Date: Aug 2018 DOI: 10.1093/oxfordhb/9780190209032.013.48 Abstract and Keywords Ovid’s poetry opens a dialogue with the three major Hesiodic works: the Theogony, the Works and Days, and the Catalogue of Women.
    [Show full text]