DOCSLIB.ORG

September 2009 Volume IX No

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
September 2009 Volume IX No North Houston Astronomy Club North Star Newsletter September 2009 Volume IX No. 9 NHAC General Meeting August 28, 2009 Novice Program Advanced Program “September Skies: A Teapot Full of “Venus: A Clouded Mystery” Surprises” By: Mr. Bill Leach 6:30-7:15PM - CLA 221, The Cosmic Forum By: Mr. Bruce Pollard 6:30-7:15PM - CLA 225, Physics Lab Main Presentation Beginning at 7:30PM, in the building CLA Teaching Theater Featuring: NHAC news and announcements, “What's Up Doc?”, by Aaron Clevenson “Captain Comet” Update, by Don Pearce Our featured speaker: “Is A Surprise!” 1 NHAC North Star Newsletter September 2009 P a g e 2 Inside this issue: Upcoming Meeting Reminder 1 Table of Contents and Thank You 2 Members Marketplace 3 A Spot On Night for Observing Jupiter by Susan and Bruce Pollard 5 News and Tidbits 6 Mars Rover Update—Meteorite found on Mars 7 September Calendar 9 About NHAC 10 A Very special thank you to Paul Derrick for presenting the Novice program on “Learning the Night Sky by Regions” and for giving the Main presentation on “Our Expanding Universe”. 2 NHAC North Star Newsletter September 2009 P a g e 3 Members, Do you have any astronomical related goods or services to buy, sell, or barter? Well, this page has been created just for you! Please send your ad to me at [email protected] and I will put it in the next issue. ADVANTAGE Telescope Repair • Repair and upgrades for all makes • Custom painting • FOR SALE : Refurbished telescopes… all “supercharged” • Cleaning, collimation, and star testing • Fabrication • Machine work Call 713-569-7529 3 NHAC North Star Newsletter September 2009 P a g e 4 The Deadline for submissions for the next newsletter is September 13, 2009 Elected Officers President: Lorrie Patel Editor: Joe Wagner Membership Committee Chair- [email protected] [email protected] person: Stuart Davenport Vice President:: Bruce Pollard Webmaster: Ed Knapton [email protected] Vice presi- [email protected] Program Committee Chairper- son: Juan Carlos Reina [email protected] ALCOR: Aaron Clevenson [email protected] Secretary: Bill Leach [email protected] [email protected] Observation Committee Chair- Treasurer: George Marsden person: Dave Clark [email protected] [email protected] “ Two men look out through the same bars; one sees the mud and one the stars. Frederick Langbridge (1849—1923) Proud member of: 4 NHAC North Star Newsletter September 2009 P a g e 5 Observe - Learn - Share A Spot-On Night for Observing Jupiter By Susan and Bruce Pollard We (Bruce and Susan Pollard) went to the George Observatory on July 25 to help Jason McCollum, Bill and Linda Christian with the public viewing and then stayed late to have a look at the impact spot on Jupiter. The skies were cloudy early on so the public viewing was limited to a few stars between the clouds rolling through. We were cautiously optimistic about having a view of Jupiter later as clearing skies were predicted. We waited until about 1:30am and ventured out to the East Dome Telescope. The sky cleared and Jupiter with its new dark spot was very visible. Al- though the spot was reasonably clear, we tested different color filters to see if one made the impact spot most visible, but there was no improvement. In the research dome we looked through the 36 inch telescope but the best view of the impact site was through the 10 ½ inch refractor. It showed up quite well as a brown spot near the upper right section of the planet. As an added bonus Io was in transit across the face of Jupiter and could be seen as it crossed the edge of the planet. We owe Justin many thanks for his help in being able to spot this amazing sight. Europa moved behind the planet around 2am. In addition, to all the action taking place on Jupiter, it was a thrill to be one of a few people getting the chance to use these big tele- scopes. All in all it was an impressive night of viewing. We are looking for- ward to our next outing at the George! Susan and Bruce Pollard [email protected] 8/16/09 5 NHAC North Star Newsletter September 2009 P a g e 6 News and Tidbits Astronomy Day 2009 9th Annual Texas Gulf Coast Astronomy Meeting: Friday, October 23, 2009. Astronomy Day 2009: Saturday, October 24, 2009 at The George Observatory. http://www.astronomyday.org/ Upcoming Star Parties The Eldorado Star Party will be held Oct.12-18, 2009 at the X Bar Ranch Nature Retreat in Eldorado, Texas. For more information and registration go to their website at: http://www.texasstarparty.org/eldorado.html The Okie-Tex Star Party will be held September 12-20, 2009 at Camp Billy Joe in the Black Mesa Area of Oklahoma. For information and registration go to their website at: http://www.okie-tex.com/index.php Administaff Observatory The next public event is Friday September 11 starting at 7:30 and other future events are listed at the observatories website: www.humble.k12.tx.us/observatory.htm Parking : Please park in the front parking lot at Jack Fields Elementary. The observa- tory is a short walk back to the left of the school; just look for the red lights. 6 NHAC North Star Newsletter September 2009 P a g e 7 Meteorite Found on Mars Yields Clues about Planet's Past This view of a rock called "Block Island," the largest meteorite yet found on Mars, comes from the panoramic camera (Pancam) on NASA's Mars Exploration Rover Opportunity PASADENA, Calif. -- NASA's Mars Rover Opportunity is investigating a metallic meteorite the size of a large watermelon that is providing researchers more details about the Red Planet's environ- mental history. The rock, dubbed "Block Island," is larger than any other known meteorite on Mars. Scientists cal- culate it is too massive to have hit the ground without disintegrating unless Mars had a much thicker atmosphere than it has now when the rock fell. Atmosphere slows the descent of meteorites. Addi- tional studies also may provide clues about how weathering has affected the rock since it fell. Two weeks ago, Opportunity had driven approximately 600 feet past the rock in a Mars region called Meridiani Planum. An image the rover had taken a few days earlier and stored was then transmitted back to Earth. The image showed the rock is approximately 2 feet in length, half that in height, and has a bluish tint that distinguishes it from other rocks in the area. The rover team decided to have Opportunity backtrack for a closer look, eventually touching Block Island with its robotic arm. 7 NHAC North Star Newsletter September 2009 P a g e 8 Meteorite Found on Mars Yields Clues about Planet's Past Continued "There's no question that it is an iron-nickel meteorite," said Ralf Gellert of the University of Guelph in Ontario, Can- ada. Gellert is the lead scientist for the rover's alpha particle X-ray spectrometer, an instrument on the arm used for identifying key elements in an object. "We already investigated several spots that showed elemental variations on the sur- face. This might tell us if and how the metal was altered since it landed on Mars." The microscopic imager on the arm revealed a distinctive triangular pattern in Block Island's surface texture, matching a pattern common in iron-nickel meteorites found on Earth. "Normally this pattern is exposed when the meteorite is cut, polished and etched with acid," said Tim McCoy, a rover team member from the Smithsonian Institution in Washington. "Sometimes it shows up on the surface of meteorites that have been eroded by windblown sand in deserts, and that appears to be what we see with Block Island." Opportunity found a smaller iron-nickel meteorite, called "Heat Shield Rock," in late 2004. At about a half ton or more, Block Island is roughly 10 times as massive as Heat Shield Rock and several times too big to have landed intact without more braking than today's Martian atmosphere could provide. "Consideration of existing model results indicates a meteorite this size requires a thicker atmosphere," said rover team member Matt Golombek of NASA's Jet Propulsion Laboratory in Pasadena, Calif. "Either Mars has hidden reserves of carbon-dioxide ice that can supply large amounts of carbon-dioxide gas into the atmosphere during warm periods of more recent climate cycles, or Block Island fell billions of years ago." Spectrometer observations have already identified variations in the composition of Block Island at different points on the rock's surface. The differences could result from interaction of the rock with the Martian environment, where the metal becomes more rusted from weathering with longer exposures to water vapor or liquid. "We have lots of iron-nickel meteorites on Earth. We're using this meteorite as a way to study Mars," said Albert Yen, a rover team member at JPL. "Before we drive away from Block Island, we intend to examine more targets on this rock where the images show variations in color and texture. We're looking to see how extensively the rock surface has been altered, which helps us understand the history of the Martian climate since it fell." When the investigation of Block Island concludes, the team plans to resume driving Opportunity on a route from Victoria Crater, which the rover explored for two years, toward the much larger Endeavour Crater. Opportunity has covered about one-fifth of the 12-mile route plotted for safe travel to Endeavour since the rover left Victoria nearly a year ago.
Load more

Recommended publications
  • Meteorites on Mars Observed with the Mars Exploration Rovers C
    JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 113, E06S22, doi:10.1029/2007JE002990, 2008 Meteorites on Mars observed with the Mars Exploration Rovers C. Schro¨der,1 D. S. Rodionov,2,3 T. J. McCoy,4 B. L. Jolliff,5 R. Gellert,6 L. R. Nittler,7 W. H. Farrand,8 J. R. Johnson,9 S. W. Ruff,10 J. W. Ashley,10 D. W. Mittlefehldt,1 K. E. Herkenhoff,9 I. Fleischer,2 A. F. C. Haldemann,11 G. Klingelho¨fer,2 D. W. Ming,1 R. V. Morris,1 P. A. de Souza Jr.,12 S. W. Squyres,13 C. Weitz,14 A. S. Yen,15 J. Zipfel,16 and T. Economou17 Received 14 August 2007; revised 9 November 2007; accepted 21 December 2007; published 18 April 2008. [1] Reduced weathering rates due to the lack of liquid water and significantly greater typical surface ages should result in a higher density of meteorites on the surface of Mars compared to Earth. Several meteorites were identified among the rocks investigated during Opportunity’s traverse across the sandy Meridiani plains. Heat Shield Rock is a IAB iron meteorite and has been officially recognized as ‘‘Meridiani Planum.’’ Barberton is olivine-rich and contains metallic Fe in the form of kamacite, suggesting a meteoritic origin. It is chemically most consistent with a mesosiderite silicate clast. Santa Catarina is a brecciated rock with a chemical and mineralogical composition similar to Barberton. Barberton, Santa Catarina, and cobbles adjacent to Santa Catarina may be part of a strewn field. Spirit observed two probable iron meteorites from its Winter Haven location in the Columbia Hills in Gusev Crater.
    [Show full text]
  • ELEMENTAL ABUNDANCES in the SILICATE PHASE of PALLASITIC METEORITES Redacted for Privacy Abstract Approved: Roman A
    AN ABSTRACT OF THE THESIS OF THURMAN DALE COOPER for theMASTER OF SCIENCE (Name) (Degree) in CHEMISTRY presented on June 1, 1973 (Major) (Date) Title: ELEMENTAL ABUNDANCES IN THE SILICATE PHASE OF PALLASITIC METEORITES Redacted for privacy Abstract approved: Roman A. Schmitt The silicate phases of 11 pallasites were analyzed instrumen- tally to determine the concentrations of some major, minor, and trace elements.The silicate phases were found to contain about 98% olivine with 1 to 2% accessory minerals such as lawrencite, schreibersite, troilite, chromite, and farringtonite present.The trace element concentrations, except Sc and Mn, were found to be extremely low and were found primarily in the accessory phases rather than in the pure olivine.An unusual bimodal Mn distribution was noted in the pallasites, and Eagle Station had a chondritic nor- malized REE pattern enrichedin the heavy REE. The silicate phases of pallasites and mesosiderites were shown to be sufficiently diverse in origin such that separate classifications are entirely justified. APPROVED: Redacted for privacy Professor of Chemistry in charge of major Redacted for privacy Chairman of Department of Chemistry Redacted for privacy Dean of Graduate School Date thesis is presented June 1,1973 Typed by Opal Grossnicklaus for Thurman Dale Cooper Elemental Abundances in the Silicate Phase of Pallasitic Meteorites by Thurman Dale Cooper A THESIS submitted to Oregon State University in partial fulfillment of the requirements for the degree of Master of Science June 1974 ACKNOWLEDGMENTS The author wishes to express his gratitude to Prof. Roman A. Schmitt for his guidance, suggestions, discussions, and thoughtful- ness which have served as an inspiration.
    [Show full text]
  • The Event That Produced Heat Shield Rock and Its Implications
    Lunar and Planetary Science XXXVII (2006) 1431.pdf THE EVENT THAT PRODUCED HEAT SHIELD ROCK AND ITS IMPLICATIONS. J. E. Chappelow1,2 and V. L. Sharpton2, 1Arctic Region Supercomputing Center, University of Alaska Fairbanks, PO Box 756020, Fairbanks, AK, USA, 99775-6020, 2Geophysical Institute, University of Alaska Fairbanks, PO Box 757320, Fair- banks, Alaska, USA, 99775-7320. Email addresses: [email protected]; [email protected]. Introduction: The January, 2005 discovery of the A weight-factor, W(mo,vo,θo)=Pm(mo)Pv(vo)Pθ(θo), iron meteorite "Heat Shield Rock" (HSR) in Terra Me- was calculated for each test object, using entry-mass, - ridiani, Mars, led to some speculation that its presence velocity and -angle frequency distributions, Pm, Pv, and implies that Mars must have had a denser atmosphere Pθ [1,2]. These take the forms -1.27 when it landed. However, to date no quantitative work Pm(mo) ∝ mo [3] either supporting or countering this theory has been 2 v − 7 presented. Here we address this issue. P ()v ∝ exp− o [1] v o 8 and 2 Pθ ()θo ∝ sin θo respectively. All of the HSR-like meteorites were then sorted out of the results and the ranges of entry parameters (mo,vo,θo) that an impactor must have to be a potential HSR determined for each Patm of interest. The associ- ated weight-factors were added up, forming fractions of the original the meteoroid population under consid- 9 Figure 1: Martian meteorite "Heat Shield Rock". eration (40 kg ≤ mo ≤ 10 kg), that yielded HSR-like meteorites.
    [Show full text]
  • Pancam Visible/Near-Infrared Spectra of Large Fe-Ni Meteorites at Meridiani Planum, Mars
    41st Lunar and Planetary Science Conference (2010) 1974.pdf Pancam Visible/Near-Infrared Spectra of Large Fe-Ni Meteorites at Meridiani Planum, Mars. J.R. Johnson1, K.E. Herkenhoff1, J.F Bell III2, W.H. Farrand3, J. Ashley4, C. Weitz5, S.W. Squyres2, 1U.S. Geological Survey, 2255 N. Gemini Dr., Flagstaff, AZ 86001, [email protected], 2Cornell University, 3Space Science Institute, 4Arizona State Univ., 5Planetary Science Institute. Introduction: The Panoramic Camera (Pancam) on featureless, positive slope. The “purple” patches are the Mars Exploration Rover (MER) Opportunity darker at all wavelengths than the typical meteorite acquired visible/near-infrared (432-1009 nm) images surfaces for all rocks except Heat Shield Rock [1] of three cobble-sized Fe-Ni meteorites informally (HSR), for which the reverse is true for the named “Block Island”, “Shelter Island”, and unbrushed portions, and for the brushed spot at “Mackinac Island” between Sols 1961 (July 30, wavelengths > 600 nm. This may be a consequence 2009) and 2038 (Oct. 17, 2009) (Figure 1). Similar of the dearth of dust contamination compared to the to the Fe-Ni meteorite Heat Shield Rock (Meridiani other meteorites, based on the low 535 nm band Planum) imaged on Sol 352 (Jan. 19, 2005) [2], the depths (Table 1) and lack of a downturn from 934 nm surfaces of these three meteorites demonstrate to 1009 nm that is observed for all other rock variable degrees of dust contamination along with surfaces (Fig. 3) and pockets of airfall dust. discontinuous coatings that exhibit Pancam reflectance spectra consistent with ferric oxides, Table 1. Average 535 nm band depths suggestive of chemical weathering on portions of the Meteorite “Purple” patch Typical surface meteorite surfaces.
    [Show full text]
  • Tin £415 14-4^
    Tin £415 14-4^ Jr THE LIFE AND WORK OF KOBAYASHI ISSA. Patrick McElligott. Ph.D. Japanese. ProQuest Number: 11010599 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 com plete 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 11010599 Published by ProQuest LLC(2018). Copyright of the Dissertation is held by the Author. All rights reserved. This work is protected against unauthorized copying under Title 17, United States C ode Microform Edition © ProQuest LLC. ProQuest LLC. 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, Ml 48106- 1346 Patrick McElligott. "The Life and Work of Kobayashi Issa., Abstract. This thesis consists of three chapters. Chapter one is a detailed account of the life of Kobayashi Issa. It is divided into the following sections; 1. Background and Early Childhood. 2. Early Years in Edo. 3. His First Return to Kashiwabara. ,4. His Jiourney into Western Japan. 5. The Death of His Father. 6 . Life im and Around Edo. 1801-1813. 7. Life as a Poet in Shinano. 8 . Family Life in Kashiwabara.. 9* Conclusion. Haiku verses and prose pieces are introduced in this chapter for the purpose of illustrating statements made concerning his life. The second chapter traces the development of Issa*s style of haiku. It is divided into five sections which correspond to the.Japanese year periods in which Issa lived.
    [Show full text]
  • New Insights Into the Mineralogy and Weathering of the Meridiani Planum Meteorite, Mars
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Stirling Online Research Repository Meteoritics & Planetary Science 46, Nr 1, 21–34 (2011) doi: 10.1111/j.1945-5100.2010.01141.x New insights into the mineralogy and weathering of the Meridiani Planum meteorite, Mars Iris FLEISCHER1*, Christian SCHRO¨ DER2,Go¨ star KLINGELHO¨ FER1, Jutta ZIPFEL3, Richard V. MORRIS4, James W. ASHLEY5, Ralf GELLERT6, Simon WEHRHEIM1, and Sandro EBERT1 1Institut fu¨ r Anorganische und Analytische Chemie, Johannes-Gutenberg-Universita¨ t Mainz, Staudinger Weg 9, 55128 Mainz, Germany 2Universita¨ t Bayreuth und Eberhard Karls Universita¨ tTu¨ bingen, Sigwartstr. 10, 72076 Tu¨ bingen, Germany 3Senckenberg Forschungsinstitut und Naturmuseum Frankfurt, Sektion Meteoritenforschung, Senckenberganlage 25, 60325 Frankfurt, Germany 4ARES Code KR, NASA Johnson Space Center, 2101 NASA Parkway, Houston, Texas 77058, USA 5Mars Space Flight Facility, School of Earth and Space Exploration, Arizona State University P.O. Box 876305, Tempe, Arizona 85287–6305, USA 6Department of Physics, University of Guelph, 50 Stone Road East, Guelph, Ontario N1G 2W1, Canada *Corresponding author. E-mail: fl[email protected] (Received 18 November 2009; revision accepted 15 October 2010) Abstract–Meridiani Planum is the first officially recognized meteorite find on the surface of Mars. It was discovered at and named after the landing site of the Mars Exploration Rover Opportunity. Based on its composition, it was classified as a IAB complex iron meteorite. Mo¨ ssbauer spectra obtained by Opportunity are dominated by kamacite (a-Fe-Ni) and exhibit a small contribution of ferric oxide. Several small features in the spectra have been neglected to date.
    [Show full text]
  • Martian Rock Types Analysis of Surface Composition
    Martian rock types Analysis of surface composition • Most of the knowledge from the surface compostion of Mars comes from: • Orbital spacecraft’s spectroscopic data • Analysis by rovers on the surface • Analysis of meteroites Southern Highlands • Mainly Basalts – Consists primarily of Olivine, Feldspars and Pyroxenes Northern Lowlands • Mainly Andesite – More evolved forms of magma – Highly volatile – Constitutes the majority of the crust Intermediate Felsic Types • High Silica Rocks • Exposed on the surface near Syrtis Major • Uncommon but include: • Dacites and Granitoids • Suggest diverse crustal composition Sedimentary Rocks • Widespread on the surface • Makes up the majority of the Northern lowlands deposists – May have formed from sea/lake deposits – Some show cross‐bedding in their layers – Hold the best chance to find fossilized life Carbonate Rocks • Formed through hydrothermal precipitation Tracks from rover unveil different soil types • Most soil consists of finely ground basaltic rock fragments • Contains iron oxide which gives Mars its red color • Also contains large amounts of sulfur and chlorine Tracks from rover unveil different soil types • Light colored soil is silica rich • High concentrations suggest water must have been involved to help concentrate the silica Blueberries • Iron rich spherules Meteorites on Mars What is a Martian meteorite? • Martian meteorites are achondritic meteorites with strong linear correlations of gases in the Martian atmosphere. Therefore, the gas trapped in each meteorite matches those that the Viking Lander found in Mar’s atmosphere. The graph below explains this correlation. • Image: http://www.imca.cc/mars/martian‐meteorites.htm Types of Martian Meteorites • 34 meteorites have been found that are Martian and they can be separated into 4 major categories with sub‐categories.
    [Show full text]
  • Minerals in Meteorites
    APPENDIX 1 Minerals in Meteorites Minerals make up the hard parts of our world and the Solar System. They are the building blocks of all rocks and all meteorites. Approximately 4,000 minerals have been identified so far, and of these, ~280 are found in meteorites. In 1802 only three minerals had been identified in meteorites. But beginning in the 1960s when only 40–50 minerals were known in meteorites, the discovery rate greatly increased due to impressive new analytic tools and techniques. In addition, an increasing number of different meteorites with new minerals were being discovered. What is a mineral? The International Mineralogical Association defines a mineral as a chemical element or chemical compound that is normally crystalline and that has been formed as a result of geological process. Earth has an enormously wide range of geologic processes that have allowed nearly all the naturally occurring chemical elements to participate in making minerals. A limited range of processes and some very unearthly processes formed the minerals of meteorites in the earliest history of our solar system. The abundance of chemical elements in the early solar system follows a general pattern: the lighter elements are most abundant, and the heavier elements are least abundant. The miner- als made from these elements follow roughly the same pattern; the most abundant minerals are composed of the lighter elements. Table A.1 shows the 18 most abundant elements in the solar system. It seems amazing that the abundant minerals of meteorites are composed of only eight or so of these elements: oxygen (O), silicon (Si), magnesium (Mg), iron (Fe), aluminum (Al), calcium (Ca), sodium (Na) and potas- sium (K).
    [Show full text]
  • The Study of Exogenic Rocks on Mars—An Evolving Subdiscipline in Meteoritics
    CosmoELEMENTS THE STUDY OF EXOGENIC ROCKS ON MARS—AN EVOLVING SUBDISCIPLINE IN METEORITICS James W. Ashley* History is replete with entertaining anecdotes predicts that meteorite-type proportions on the stony-iron candidates. They are brecciated of meteorites found and lost on Earth. That Mars would approximate those found on and contain varying amounts of kamacite (an chronicle has recently been expanded to Earth, where some 94 percent are stony (chon- Fe–Ni alloy) and troilite (FeS), but they do not include the exotic saga of meteorite search, drite and achondrite) varieties. resemble known meteorite varieties (Schröder discovery, and assessment on another planet et al. 2010). They may represent either a type using roving spacecraft. The inventory of OBSERVATIONS of meteorite not found in Earth-based collec- confi rmed and candidate meteorites on Mars tions or some species of impact breccia that As with most discoveries in the planetary sci- currently stands at a minimum of 21 fi nds preserves materials from the impacting bolide. ences, some observations confi rm theory while from three widely separated rover landing If meteoritic, the rocks are probably members others raise baffl ing questions. For example, to sites (TABLE 1). Using a combination of remote of a single-fall strewn fi eld. Further studies date not a single chondritic meteorite has been sensing and direct-measurement instruments are underway. The tendency for most irons to identifi ed on Mars, and the suite is dominated on Opportunity and Spirit (Mars Exploration be found in groups is also almost certainly instead by large (30–200 cm) iron–nickel mete- Rovers, MERs), and most recently on Curiosity an indication of specimens being members orites (see TABLE 1).
    [Show full text]
  • Recherche D Indices De Vie Sur Mars
    THÈSE de doctorat de L’UNIVERSITÉ PARIS DENIS DIDEROT (Paris 7) École doctorale des Sciences de l’Environnement d’Ile de France Présentée par Fabien STALPORT le vendredi 30 novembre 2007 SPÉCIALITÉ : Chimie de la Pollution Atmosphérique et Physique de l’Environnement Recherche d’indices de vie sur Mars : détermination de signatures spécifiques de biominéraux et étude expérimentale de l’évolution de molécules organiques dans des conditions environnementales martiennes tel-00274870, version 1 - 21 Apr 2008 Commission d’examen composée de : Michel DELAMAR Professeur, Univ. Paris 7 Président Max BERNSTEIN Directeur de recherche, NASA Rapporteur François POULET Astronome-Adjoint, IAS Rapporteur Sylvestre MAURICE Astronome, CESR Examinateur Cyril SZOPA Maître de conférences, Univ. Paris 6 Codirecteur de thèse Patrice COLL Maître de conférences, Univ. Paris 7 Directeur de thèse Alain PERSON Maître de conférences, Univ. Paris 6 Invité Francis ROCARD Astrophysicien, CNES Invité Université Paris 7, Université Paris 12 et CNRS (UMR 7583) Faculté des Sciences et Technologie, 61 avenue du Général de Gaulle, 94010 CRETEIL Cedex tel-00274870, version 1 - 21 Apr 2008 tel-00274870, version 1 - 21 Apr 2008 tel-00274870, version 1 - 21 Apr 2008 REMERCIEMENTS : Figure 0 : Signe du destin ? Source : Image de la collection « les Crados », sorti dans les cours de récréation de primaire en 1989, que j’ai âprement gagné lors d’un duel d’images épique, pleins de rebondissements et de suspenses. Un jour de classe préparatoire, ma maîtresse d’école me mis entre mes petites mains un livre sur les espèces fossiles, telles que les dinosaures et les reptiles mammaliens. Certes je ne comprenais pas tous les mots, mais j’eus à l’instant une profonde fascination lorsque je découvris les représentations artistiques de ces « reptiles terribles » surdimensionnés.
    [Show full text]
  • Supplement Abstracts.Fm
    Abstracts for the 61st Annual Meeting of the Meteoritical Society Item Type Article; text Citation Abstracts for the 61st Annual Meeting of the Meteoritical Society. Meteoritics & Planetary Science, 43(S7), 15-178 (2008). DOI 10.1111/j.1945-5100.2008.tb00711.x Publisher The Meteoritical Society Journal Meteoritics & Planetary Science Rights Copyright © The Meteoritical Society Download date 28/09/2021 00:01:36 Item License http://rightsstatements.org/vocab/InC/1.0/ Version Final published version Link to Item http://hdl.handle.net/10150/656517 Meteoritics & Planetary Science 43, Nr 7, Supplement, A15–A178 (2008) http://meteoritics.org Abstracts 5316 5030 ROSETTA FLYBY TARGET ASTEROID (2867) STEINS: AN VARIETIES OF CARBON MINERALS IN ANTARCTIC ENSTATITE ACHONDRITE ANALOGUE CARBONACEOUS CHONDRITES BY TEM AND THEIR P. A. Abell 1, 2, P. R. Weissman3, M. D. Hicks3, Y. J. Choi3, and S. C. Lowry3. IMPLICATIONS 1Planetary Science Institute, 1700 E. Fort Lowell, Suite 106, Tucson, AZ Junji Akai1, Takayuki Aoki2, and Hikaru Ohtani1. 1Department of Geology, 85719, USA. E-mail: [email protected]. 2NASA Johnson Space Center, Fac. Sci., Niigata University, Niigata, Japan. 2Asahi Carbon Co., Niigata, Houston, TX 77058, USA. 3Jet Propulsion Laboratory, 4800 Oak Grove Japan. Drive, Pasadena, CA 91109, USA. A variety of fine-grained carbonaceous materials are contained in Introduction: On September 5, 2008, the European Space Agency’s carbonaceous chondrite (CC) matrix. However, Antarctic meteorites have not Rosetta spacecraft will fly by the main-belt asteroid
    [Show full text]
  • Curiosity Finds a Melted Space Metal Meteorite on the Surface of Mars 2 November 2016, by Matt Williams
    Curiosity finds a melted space metal meteorite on the surface of Mars 2 November 2016, by Matt Williams The chemical analysis revealed that the rock was composed of metal, which explained its melted appearance. In essence, it is likely the rock became molten as it entered Mars' atmosphere, leading to the metal softening and flowing. Once it reached the surface, it cooled to the point that this appearance became frozen on its face. Such a find is quite exciting, if not entirely unexpected. In the past, Curiosity and other rovers has spotted the remains of other metallic meteorites. For instance, back in 2005, the Opportunity rover spotted a pitted, basketball-sized iron meteorite that was named "Heat Shield Rock". Image from Curiosity's Mast Camera (Mastcam), which captured a small rock believed to be a meteorite on Sol 153. Credit: NASA/JPL-Caltech/LANL/ASU Since it landed on the surface of the Red Planet in 2012, the Curiosity rover has made some rather surprising finds. In the past, this has included evidence that liquid water once filled the Gale Crater, the presence of methane and organic molecules today, curious sedimentary formations, and even a strange ball-shaped rock. And most recently, Curiosity's Mast Camera (Mastcam) captured images of what appeared to be a ball of melted metal. Known as "Egg Rock" (due to its odd, ovoid appearance) this object has been identified as a small meteorites, most likely composed of nickel and iron. Egg Rock was first noticed in an image that was snapped by Curiosity on Oct.
    [Show full text]