DOCSLIB.ORG

List of Publications

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
List of Publications 1 Prof. A. El Goresy BAYERISCHES GEOINSTITUT UNIVERSITÄT BAYREUTH D-95440 BAYREYTH GERMANY List of Publications 1. El Goresy, A. (1964): Neue Beobachtungen an der Nickel-Magnetkies-Lagerstätte von Abu Suwajel, Ägypten. N.Jb.Miner.Abh. 102, 1, 107-113. 2. El Goresy, A. (1964): Die Erzmineralien in den Ries- und Bosumtwi-Kratergläsern und ihre genetische Deutung. Geochim.Cosmochim.Acta 28, 1881-1891. 3. El Goresy, A. (1965): Mineralbestand und Strukturen der Graphit- und Sulfideinschlüsse in Eisenmeteoriten. Geochim.Cosmochim. Acta 29, 1131-1151. 4. El Goresy, A. (1965): Baddeleyite and its significance in impact glasses. J.Geophys.Res. 70,14, 3455-3456. 5. El Goresy, A. and Meixner, H. (1965): Brannerit aus den Eisenspatlagerstätten von Olsa bei Friesach, Kärnten. N.Jahrb.Miner. 103, 94-98. 6. El Goresy, A. (1966): Metallic spherules in Bosumtwi crater glasses. Earth Planet.Sci.Lett. 1, 23-24. 7. Antun, P., El Goresy, A. and Ramdohr, P. (1966): Ein neuartiger Typ "hydrothermaler" Cu-Ni-Lagerstätten. Mineral.Depos. 2, 113-132. 8. El Goresy, A. and Fechtig, H. (1967): Fusion crust of iron meteorites and mesosiderites and the production of cosmic spherules. In: "Meteor Orbits and Dust", pp. 391-397. 9. El Goresy, A. and Fechtig, H. (1967): Die Opakmineralien in Einschlagsgläsern. Fortschr.Miner. 44, 143. 2 10. El Goresy, A. (1967): The opaque minerals in impactite glasses. In: "Shock Metamorphism of Natural Materials" (eds. B.M. French & N.M. Short), pp. 531-553. 11. El Goresy, A. (1967): Quantitative electron microprobe analyses of coexisting sphalerite, daubreelite and troilite in the Odessa iron meteorite and their genetic implications. Geochim.Cosmochim. Acta 31, 1667-1676. 12. El Goresy, A. (1968): Electron microprobe analysis and ore microscopic study of magnetic spherules and grains collected from the Greenland ice. Contr.Mineral.Petrol. 17, 331-346. 13. Kullerud, G. and El Goresy, A. (1968): Sulfide assemblage in the Odessa meteorite. Ann.Rep. of the Director, Geophys.Lab., Carnegie Inst. Washington, Yearbook 67, 187-192. 14. Bell, P.M., El Goresy, A. and Kullerud, G. (1968): Synthesis of β Cr2FeS4 at 35 kilobars. Ann.Rep. of the Director, Geophys.Lab., Carnegie Inst. Washington, Yearbook 67, 197-198. 15. El Goresy, A. and Donnay, G. (1968): A new allotropic form of carbon from the Ries Crater. Science 161, 363-364. 16. Bell, P.M., England, J.L., Kullerud, G. and El Goresy, A. (1969): Pressure-temperature diagram for Cr2FeS4. Ann.Rep. of the Director, Geophys.Lab., Carnegie Inst. Washington, Yearbook 68, 277-278. 17. El Goresy, A. and Kullerud, G. (1969): Phase relations in the system Cr-Fe-S. In: "Meteorite Research" (ed. P.M. Millman), pp. 638-656. 18. El Goresy, A. (1969): Eine neue Kohlenstoff-Modifikation aus dem Nördlinger Ries. Naturwiss. 56, 493-494. 19. Ramdohr, P. and El Goresy, A. (1969): "Peckelsheim": A new bronzite achondrite. Naturwiss. 56, 512. 3 20. Ramdohr, P. and El Goresy, A. (1970): Opaque minerals of the lunar rocks and dust from Mare Tranquillitatis. Science 167, 615- 618. 21. Anderson, A.T., Bunch, T.E., Cameron, E.N., Haggerty, S.E., Boyd, F.R., Finger, L.W., James, O.B., Keil, K., Prinz, M., El Goresy, A. and Ramdohr (1970): Armalcolite: A new mineral from the Apollo 11 samples. Proc. Apollo 11 Lunar Sci.Conf., Vol. 1, 55-63. 22. Ramdohr, P. and El Goresy, A. (1970): Mikroskopische Untersuchung der Mondproben des Apollo-11 Unternehmens. Naturwiss. 57, 98-106. 23. Ramdohr, P. and El Goresy, A. (1970): Zur Mineralogie des Mondes. Aufschluss 21, 219-224. 24. El Goresy, A. (1971): Mineralogische Zusammensetzungen der Mondmaterie aus dem Meer der Ruhe. In: "Physik und Kosmologie, Stand und Zukunftsaspekte naturwiss. Forschung in Deutschland". Colloq. Verlag Berlin, S. 63-69. 25. Lovering, J.F., Bunch, T.E., El Goresy, A., Ramdohr, P., Brown, G.M., Peckett, A., Philipps, R., Cameron, E.N.,Jr, Douglas, A.V. and Plant, A.G. (1971): Tranquillityite: A new silicate mineral from Apollo 11- and 12 basaltic rocks. Proc. Lunar Sci.Conf. 2nd, Vol.1, 39-45. 26. El Goresy, A., Ramdohr, P. and Taylor, L.A. (1971): The opaque minerals in the lunar rocks from Oceanus Procellarum. Proc. Lunar Sci.Conf. 2nd, Vol.1, 219-235. 27. El Goresy, A. (1971): Meteoritic rutile: A niobium-bearing mineral. Earth Planet.Sci.Lett. 11, 356-361. 28. El Goresy, A., Ramdohr, P. and Taylor, L.A. (1971): The geochemistry of the opaque minerals in Apollo 14 crystalline rocks. Earth Planet.Sci.Lett. 13, 121-129. 4 29. El Goresy, A., Grögler, N. and Ottemann, J. (1971): Djerfisherite composition in Bishopville, Peña Blanca Spring, St. Marks and Toluca meteorites. Chemie d. Erde, Festband Heide, Bd. 30, H. 1/4. 30. Ramdohr, P. and El Goresy, A. (1971): Einiges über den Meteoriten von Mundrabilla in Westeaustralien. Chemie d. Erde, Festband Heide, Bd. 30, H. ¼, 269-282. 31. El Goresy, A., Taylor, L.A. and Ramdohr, P. (1972): Fra Mauro crystalline rocks: Mineralogy, geochemistry and subsolidus reduction of the opaque minerals. Proc. Lunar Sci.Conf. 3rd, Vol.1, 333-349. 32. Pavicevic, M.K., Ramdohr, P. and El Goresy, A. (1972): Microprobe investigations of the oxidation states of Fe and Ti in ilmenite in Apollo 11, Apollo 12, and Apollo 14 crystalline rocks. Proc. Lunar Sci.Conf. 3rd, Vol.1, 295-303. 33. El Goresy, A., Ramdohr, P., Pavicevic, M.K., Medenbach, O., Müller, O. and Gentner, W. (1973): Zinc, lead, chlorine and FeOOH-bearing assemblages in the Apollo 16 sample 66095: Origin by impact of a comet or a carbonaceous chondrite? Earth Planet.Sci.Lett. 18, 411- 419. 34. El Goresy, A., Ramdohr, P. and Medenbach, O. (1973): Lunar samples from the Descartes site: Opaque mineralogy and geochemistry. Proc. Lunar Sci.Conf. 4th, Vol.1, 733-750. 35. El Goresy, A., Ramdohr, P., Medenbach, O. and Bernhardt, H.-J. (1974): Mineralogy and geochemistry of the opaques in lithic fragments from the Apollo 17 landing site. Meteoritics 8, 263-264. 36. El Goresy, A., Taylor, L.A. and Ramdohr, P. (1973): Apollo 15 opaque minerals: Geochemistry, mineralogy, and subsolidus reduction. Meteoritics 8, 32. 37. El Goresy, A. (1974): Spinellchemismus als Beweis für einen weitgehend differenzierten Mond. In: "Analyse Extraterrestrischen Materials" (Hrsg.: W. Kiesl & H. Malissa, jun.). Springer Wien-New York, S. 249-263. 5 38. El Goresy, A., Ramdohr, P., Medenbach, O. and Bernhardt, H.-J. (1974): Taurus-Littrow TiO2-rich basalts: Opaque mineralogy and geochemistry. Proc. Lunar Sci.Conf. 5th, Vol.1, 627-652. 39. Bell, P.M., El Goresy, A. and Mao, H.K. (1974): A study of iron-rich particles on the surface of orange glass spheres from 74220. Proc. Lunar Sci.Conf. 5th, Vol.1, 187. 40. Mao, H.K., El Goresy, A. and Bell, P.M. (1974): Evidence of extensive chemical reduction in lunar regolith samples from the Apollo 17 site. Proc. Lunar Sci.Conf. 5th, Vol.1, 673-684. 41. El Goresy, A. and Yoder, H.S. (1974): Natural and synthetic melilite compositions. Ann.Rep.Geophys.Lab., Carnegie Inst. Washington, 359. 42. El Goresy, A. and Ramdohr, P. (1975): Subsolidus reduction of lunar opaque oxides: Textures, assemblages, geochemistry and evidence for a late stage endogenic gaseous mixture. Proc. Lunar Sci.Conf. 6th, Vol.1, 729-745. 43. Ramdohr, P., Prinz, M. and El Goresy, A. (1975): Silicate inclusions in the Mundrabilla meteorite. Meteoritics 10, 477. 44. El Goresy, A. and Chao, E.C.T. (1976): Identification and significance of armalcolite in the Ries glass. Earth Planet.Sci.Lett. 30, 200-208. 45. El Goresy, A., Prinz, M. and Ramdohr, P. (1976): Zoning in spinels as an indicator of the crystallization histories of mare basalts. Proc. Lunar Sci.Conf. 7th, Vol.1, 1261-1279. 46. El Goresy, A. and Chao, E.C.T. (1976): Evidence of the impacting body of the Ries crater - the discovery of Fe-Cr-Ni veinlets below the crater bottom. Earth Planet.Sci.Lett. 31, 330-340. 47. El Goresy, A. and Woermann, E. (1977): Opaque minerals as sensitive oxygen barometers and geothermometers in lunar basalts. In: "Thermodynamics in Geology" (ed. D.G. Fraser), pp. 249-277. 6 48. El Goresy, A. (1976): Opaque oxide minerals in meteorites. Miner.Soc.Am. Short Course Notes, Vol. 3, 47. (Short Course held at Golden, Col., Nov. 1976). 49. El Goresy, A. (1976): Oxide minerals in lunar rocks. Miner.Soc.Am. Short Course Notes, Vol.3, 1. (Short Course held at Golden, Col., Nov. 1976). 50. Bosch, F., El Goresy, A., Krätschmer, W., Martin, B., Povh, B., Nobiling, R., Traxel, K. and Schwalm, D. (1976): Comments on the reported evidence of primordial superheavy elements. Phys.Rev.Lett. 37, 22, 1515. 51. Bosch, F., El Goresy, A., Krätschmer, W., Martin, B., Povh, B., Nobiling, R., Traxel, K. and Schwalm, D. (1977): On the possible existence of superheavy elements in monazite. Z. Physik A280, 39. 52. Chao, E.C.T. and El Goresy, A. (1977): Shock attenuation and the implication of Fe-Cr-Ni veinlets in the compressed zone of the Ries research deep drill core. Geol.Bavar. 75, 289-304. 53. El Goresy, A. and Chao, E.C.T. (1977): Discovery, origin and significance of Fe-Cr-Ni veinlets in the compressed zone of the 1973 Ries research deep drill core. Geol.Bavar. 75, 305-321. 54. El Goresy, A. and Ramdohr, P. (1977): Apollo 17 TiO2-rich basalts: Reverse spinel zoning as evidence for subsolidus equilibration of the spinel-ilmenite assemblage. Proc. Lunar Sci.Conf. 8th, Vol.2, 1611- 1624. 55. Knecht, B., Simons, B., Woermann, E. and El Goresy, A. (1977): Phase relations in the system Fe-Cr-Ti-O and their application in lunar thermometry. Proc. Lunar Sci.Conf.
Load more

Recommended publications
  • Green Diamond Forest Habitat Conservation Plan Appendix B
    B-1 Appendix B. Profile of the Covered Species TABLE OF CONTENTS APPENDIX B. PROFILE OF THE COVERED SPECIES ................................................... B-1 B.1 NORTHERN SPOTTED OWL (STRIX OCCIDENTALIS CAURINA) .......................................... B-3 B.2 LISTING STATUS ......................................................................................................... B-3 B.2.1 Range and Distribution .......................................................................................... B-3 B.2.2 Life History ............................................................................................................ B-4 B.2.3 Habitat Requirements ............................................................................................ B-5 B.3 FISHER (PEKANIA PENNANTI) ....................................................................................... B-5 B.3.1 Listing Status ......................................................................................................... B-5 B.3.2 Range and Distribution .......................................................................................... B-6 B.3.3 Life History ............................................................................................................ B-8 B.3.4 Habitat Requirements ............................................................................................ B-9 B.3.5 Resting and Denning Habitat ............................................................................... B-10 B.3.6 Foraging Habitat .................................................................................................
    [Show full text]
  • General Index
    General Index Italicized page numbers indicate figures and tables. Color plates are in- cussed; full listings of authors’ works as cited in this volume may be dicated as “pl.” Color plates 1– 40 are in part 1 and plates 41–80 are found in the bibliographical index. in part 2. Authors are listed only when their ideas or works are dis- Aa, Pieter van der (1659–1733), 1338 of military cartography, 971 934 –39; Genoa, 864 –65; Low Coun- Aa River, pl.61, 1523 of nautical charts, 1069, 1424 tries, 1257 Aachen, 1241 printing’s impact on, 607–8 of Dutch hamlets, 1264 Abate, Agostino, 857–58, 864 –65 role of sources in, 66 –67 ecclesiastical subdivisions in, 1090, 1091 Abbeys. See also Cartularies; Monasteries of Russian maps, 1873 of forests, 50 maps: property, 50–51; water system, 43 standards of, 7 German maps in context of, 1224, 1225 plans: juridical uses of, pl.61, 1523–24, studies of, 505–8, 1258 n.53 map consciousness in, 636, 661–62 1525; Wildmore Fen (in psalter), 43– 44 of surveys, 505–8, 708, 1435–36 maps in: cadastral (See Cadastral maps); Abbreviations, 1897, 1899 of town models, 489 central Italy, 909–15; characteristics of, Abreu, Lisuarte de, 1019 Acequia Imperial de Aragón, 507 874 –75, 880 –82; coloring of, 1499, Abruzzi River, 547, 570 Acerra, 951 1588; East-Central Europe, 1806, 1808; Absolutism, 831, 833, 835–36 Ackerman, James S., 427 n.2 England, 50 –51, 1595, 1599, 1603, See also Sovereigns and monarchs Aconcio, Jacopo (d. 1566), 1611 1615, 1629, 1720; France, 1497–1500, Abstraction Acosta, José de (1539–1600), 1235 1501; humanism linked to, 909–10; in- in bird’s-eye views, 688 Acquaviva, Andrea Matteo (d.
    [Show full text]
  • A Multielement Isotopic Study of Refractory FUN and F Cais: 2 Mass-Dependent and Mass-Independent Isotope Effects 3 Levke Kööp1,2,3,*, Daisuke Nakashima4,5, Philipp R
    1 A multielement isotopic study of refractory FUN and F CAIs: 2 Mass-dependent and mass-independent isotope effects 3 Levke Kööp1,2,3,*, Daisuke Nakashima4,5, Philipp R. Heck1,2,3, Noriko T. Kita4, Travis J. Ten- 4 ner4,6, Alexander N. Krot7, Kazuhide Nagashima7, Changkun Park7,8, Andrew M. Davis1,2,3,9 5 1Department of the Geophysical Sciences, The University of Chicago, Chicago, IL 60637, 6 USA ([email protected]) 7 2Chicago Center for Cosmochemistry, The University of Chicago, Chicago, IL 60637, USA 8 3Robert A. Pritzker Center for Meteoritics and Polar Studies, Field Museum of Natural His- 9 tory, Chicago, IL, USA 10 4Department of Geoscience, University of Wisconsin, Madison, WI 53706, USA 11 5Division of Earth and Planetary Material Sciences, Faculty of Science, Tohoku University, 12 Aoba, Sendai, Miyagi 980-8578 Japan 13 6 Chemistry Division, Nuclear and Radiochemistry, Los Alamos National Laboratory, 14 MSJ514, Los Alamos, NM 87545, USA 15 7Hawai‘i Institute of Geophysics and Planetology, School of Ocean and Earth Science and 16 Technology, University of Hawai‘i at M!noa, Honolulu, HI 17 8Korea Polar Research Institute, Incheon 21990, Korea 18 9Enrico Fermi Institute, The University of Chicago, Chicago, IL 60637, USA. 19 20 *E-mail address of the corresponding author: [email protected] 21 ABSTRACT 22 Calcium-aluminum-rich inclusions (CAIs) are the oldest dated objects that formed inside the 23 Solar System. Among these are rare, enigmatic objects with large mass-dependent fractionation 24 effects (F CAIs), which sometimes also have large nucleosynthetic anomalies and a low initial 25 abundance of the short-lived radionuclide 26Al (FUN CAIs).
    [Show full text]
  • Addibischoffite, Ca2al6al6o20, a New Calcium Aluminate Mineral from The
    1 Revision 3 2 Addibischoffite, Ca2Al6Al6O20, a new calcium aluminate mineral from 3 the Acfer 214 CH carbonaceous chondrite: A new refractory phase from 4 the solar nebula 5 Chi Ma1,*, Alexander N. Krot2, Kazuhide Nagashima2 6 1Division of Geological and Planetary Sciences, California Institute of Technology, 7 Pasadena, California 91125, USA 8 2Hawai‘i Institute of Geophysics and Planetology, University of Hawai‘i at Mānoa, 9 Honolulu, Hawai‘i 96822, USA 10 11 ABSTRACT 12 Addibischoffite (IMA 2015-006), Ca2Al6Al6O20, is a new calcium aluminate mineral 13 that occurs with hibonite, perovskite, kushiroite, Ti-kushiroite, spinel, melilite, 14 anorthite and FeNi-metal in the core of a Ca-Al-rich inclusion (CAI) in the Acfer 15 214 CH3 carbonaceous chondrite. The mean chemical composition of type 16 addibischoffite by electron probe microanalysis is (wt%) Al2O3 44.63, CaO 15.36, 17 SiO2 14.62, V2O3 10.64, MgO 9.13, Ti2O3 4.70, FeO 0.46, total 99.55, giving rise to 18 an empirical formula of 3+ 3+ 2+ 19 (Ca2.00)(Al2.55Mg1.73V 1.08Ti 0.50Ca0.09Fe 0.05)Σ6.01(Al4.14Si1.86)O20. The general 20 formula is Ca2(Al,Mg,V,Ti)6(Al,Si)6O20. The end-member formula is Ca2Al6Al6O20. 21 Addibischoffite has the P1 aenigmatite structure with a = 10.367 Å, b = 10.756 Å, c 22 = 8.895 Å, α = 106.0°, β = 96.0°, γ = 124.7°, V = 739.7 Å3, and Z = 2, as revealed by 23 electron back-scatter diffraction. The calculated density using the measured 24 composition is 3.41 g/cm3.
    [Show full text]
  • Petrography and Mineral Chemistry of the Anhydrous Component of the Tagish Lake Carbonaceous Chondrite
    Meteoritics & Planetary Science 38, Nr 5, 813–825 (2003) Abstract available online at http://meteoritics.org Petrography and mineral chemistry of the anhydrous component of the Tagish Lake carbonaceous chondrite S. B. SIMON1* and L. GROSSMAN1, 2 1Department of the Geophysical Sciences, 5734 South Ellis Avenue, The University of Chicago, Chicago, Illinois 60637, USA 2The Enrico Fermi Institute, 5640 South Ellis Avenue, The University of Chicago, Chicago, Illinois 60637, USA *Corresponding author. E-mail: [email protected] (Received 30 August 2002; revision accepted 16 January 2003) Abstract–Most studies of Tagish Lake have considered features that were either strongly affected by or formed during the extensive hydrous alteration experienced by this meteorite. This has led to some ambiguity as to whether Tagish Lake should be classified a CI, a CM, or something else. Unlike previous workers, we have focused upon the primary, anhydrous component of Tagish Lake, recovered through freeze-thaw disaggregation and density separation and located by thin section mapping. We found many features in common with CMs that are not observed in CIs. In addition to the presence of chondrules and refractory forsterite (which distinguish Tagish Lake from the CIs), we found hibonite-bearing refractory inclusions, spinel-rich inclusions, forsterite aggregates, Cr-, Al-rich spinel, and accretionary mantles on many clasts, which clearly establishes a strong link between Tagish Lake and the CM chondrites. The compositions of isolated olivine crystals in Tagish Lake are also like those found in CMs. We conclude that the anhydrous inclusion population of Tagish Lake was, originally, very much like that of the known CM chondrites and that the inclusions in Tagish Lake are heavily altered, more so than even those in Mighei, which are more heavily altered than those in Murchison.
    [Show full text]
  • Planet Mars III 28 March- 2 April 2010 POSTERS: ABSTRACT BOOK
    Planet Mars III 28 March- 2 April 2010 POSTERS: ABSTRACT BOOK Recent Science Results from VMC on Mars Express Jonathan Schulster1, Hannes Griebel2, Thomas Ormston2 & Michel Denis3 1 VCS Space Engineering GmbH (Scisys), R.Bosch-Str.7, D-64293 Darmstadt, Germany 2 Vega Deutschland Gmbh & Co. KG, Europaplatz 5, D-64293 Darmstadt, Germany 3 Mars Express Spacecraft Operations Manager, OPS-OPM, ESA-ESOC, R.Bosch-Str 5, D-64293, Darmstadt, Germany. Mars Express carries a small Visual Monitoring Camera (VMC), originally to provide visual telemetry of the Beagle-2 probe deployment, successfully release on 19-December-2003. The VMC comprises a small CMOS optical camera, fitted with a Bayer pattern filter for colour imaging. The camera produces a 640x480 pixel array of 8-bit intensity samples which are recoded on ground to a standard digital image format. The camera has a basic command interface with almost all operations being performed at a hardware level, not featuring advanced features such as patchable software or full data bus integration as found on other instruments. In 2007 a test campaign was initiated to study the possibility of using VMC to produce full disc images of Mars for outreach purposes. An extensive test campaign to verify the camera’s capabilities in-flight was followed by tuning of optimal parameters for Mars imaging. Several thousand images of both full- and partial disc have been taken and made immediately publicly available via a web blog. Due to restrictive operational constraints the camera cannot be used when any other instrument is on. Most imaging opportunities are therefore restricted to a 1 hour period following each spacecraft maintenance window, shortly after orbit apocenter.
    [Show full text]
  • Appendix I Lunar and Martian Nomenclature
    APPENDIX I LUNAR AND MARTIAN NOMENCLATURE LUNAR AND MARTIAN NOMENCLATURE A large number of names of craters and other features on the Moon and Mars, were accepted by the IAU General Assemblies X (Moscow, 1958), XI (Berkeley, 1961), XII (Hamburg, 1964), XIV (Brighton, 1970), and XV (Sydney, 1973). The names were suggested by the appropriate IAU Commissions (16 and 17). In particular the Lunar names accepted at the XIVth and XVth General Assemblies were recommended by the 'Working Group on Lunar Nomenclature' under the Chairmanship of Dr D. H. Menzel. The Martian names were suggested by the 'Working Group on Martian Nomenclature' under the Chairmanship of Dr G. de Vaucouleurs. At the XVth General Assembly a new 'Working Group on Planetary System Nomenclature' was formed (Chairman: Dr P. M. Millman) comprising various Task Groups, one for each particular subject. For further references see: [AU Trans. X, 259-263, 1960; XIB, 236-238, 1962; Xlffi, 203-204, 1966; xnffi, 99-105, 1968; XIVB, 63, 129, 139, 1971; Space Sci. Rev. 12, 136-186, 1971. Because at the recent General Assemblies some small changes, or corrections, were made, the complete list of Lunar and Martian Topographic Features is published here. Table 1 Lunar Craters Abbe 58S,174E Balboa 19N,83W Abbot 6N,55E Baldet 54S, 151W Abel 34S,85E Balmer 20S,70E Abul Wafa 2N,ll7E Banachiewicz 5N,80E Adams 32S,69E Banting 26N,16E Aitken 17S,173E Barbier 248, 158E AI-Biruni 18N,93E Barnard 30S,86E Alden 24S, lllE Barringer 29S,151W Aldrin I.4N,22.1E Bartels 24N,90W Alekhin 68S,131W Becquerei
    [Show full text]
  • Pseudomonas Stutzeri Biology Of
    Biology of Pseudomonas stutzeri Jorge Lalucat, Antoni Bennasar, Rafael Bosch, Elena García-Valdés and Norberto J. Palleroni Microbiol. Mol. Biol. Rev. 2006, 70(2):510. DOI: 10.1128/MMBR.00047-05. Downloaded from Updated information and services can be found at: http://mmbr.asm.org/content/70/2/510 These include: http://mmbr.asm.org/ REFERENCES This article cites 395 articles, 145 of which can be accessed free at: http://mmbr.asm.org/content/70/2/510#ref-list-1 CONTENT ALERTS Receive: RSS Feeds, eTOCs, free email alerts (when new articles cite this article), more» on January 28, 2014 by Red de Bibliotecas del CSIC Information about commercial reprint orders: http://journals.asm.org/site/misc/reprints.xhtml To subscribe to to another ASM Journal go to: http://journals.asm.org/site/subscriptions/ MICROBIOLOGY AND MOLECULAR BIOLOGY REVIEWS, June 2006, p. 510–547 Vol. 70, No. 2 1092-2172/06/$08.00ϩ0 doi:10.1128/MMBR.00047-05 Copyright © 2006, American Society for Microbiology. All Rights Reserved. Biology of Pseudomonas stutzeri Jorge Lalucat,1,2* Antoni Bennasar,1 Rafael Bosch,1 Elena Garcı´a-Valde´s,1,2 and Norberto J. Palleroni3 Departament de Biologia, Microbiologia, Universitat de les Illes Balears, Campus UIB, 07122 Palma de Mallorca, Spain1; Institut Mediterrani d’Estudis Avanc¸ats (CSIC-UIB), Campus UIB, 07122 Palma de Mallorca, Spain2; and Department of Biochemistry and Microbiology, Rutgers University, Cook Campus, 3 New Brunswick, New Jersey 08901-8520 Downloaded from INTRODUCTION .......................................................................................................................................................511
    [Show full text]
  • Grossite and Hibonite Bearing Refractory Inclusions in the CO3.1 Chondrite Miller Range 090019. D. K. Ross1 and J. I. Simon2, 1U
    49th Lunar and Planetary Science Conference 2018 (LPI Contrib. No. 2083) 2559.pdf Grossite and Hibonite Bearing Refractory Inclusions in the CO3.1 Chondrite Miller Range 090019. D. K. Ross1 and J. I. Simon2, 1University of Texas El Paso/Jacobs Technology/NASA-JSC-ARES (2224 Bay Area Blvd. Houston TX 77058, USA ([email protected]), 2NASA-Johnson Space Center-ARES ([email protected]). Introduction: We have characterized 142 refract- finer grained particles with substantial porosity. Ongo- ory objects by EDS hyperspectral X-ray mapping in the ing reaction with nebular gases produces down-temper- CO3.1 chondrite MIL 090019-13. These include 127 ature phases partially replacing earlier formed phases Ca-Al rich inclusions (CAIs), 14 amoeboidal olivine ag- and infilling porosity, leading to densified objects. gregates (AOAs) and one Al-rich chondrule. These data Most CAIs are not fully equilibrated, but exhibit miner- are being used to reveal the mineralogy, texture and alogy reflecting a considerable range of temperature, bulk composition of these inclusions, and to identify ob- with relict phases. Hibonite is typically intergrown with, jects that represent endmembers within cogenetic popu- and partially replaced by spinel, violating the predicted lations of primitive inclusions, which will be further in- crystallization order from thermodynamic calcula- vestigated by future isotopic studies. Previous work re- tions[3], in which melilite should precede spinel crystal- lated to these refractory inclusions in this chondrite also lization. appear in [1] and [2]. Twenty six inclusions are hibonite-bearing, 18 are grossite-bearing and one inclusion is corundum-rich. In seven of these inclusions, grossite and hibonite coexist.
    [Show full text]
  • Appendix a Recovery of Ejecta Material from Confirmed, Probable
    Appendix A Recovery of Ejecta Material from Confirmed, Probable, or Possible Distal Ejecta Layers A.1 Introduction In this appendix we discuss the methods that we have used to recover and study ejecta found in various types of sediment and rock. The processes used to recover ejecta material vary with the degree of lithification. We thus discuss sample processing for unconsolidated, semiconsolidated, and consolidated material separately. The type of sediment or rock is also important as, for example, carbonate sediment or rock is processed differently from siliciclastic sediment or rock. The methods used to take and process samples will also vary according to the objectives of the study and the background of the investigator. We summarize below the methods that we have found useful in our studies of distal impact ejecta layers for those who are just beginning such studies. One of the authors (BPG) was trained as a marine geologist and the other (BMS) as a hard rock geologist. Our approaches to processing and studying impact ejecta differ accordingly. The methods used to recover ejecta from unconsolidated sediments have been successfully employed by BPG for more than 40 years. A.2 Taking and Handling Samples A.2.1 Introduction The size, number, and type of samples will depend on the objective of the study and nature of the sediment/rock, but there a few guidelines that should be followed regardless of the objective or rock type. All outcrops, especially those near industrialized areas or transportation routes (e.g., highways, train tracks) need to be cleaned off (i.e., the surface layer removed) prior to sampling.
    [Show full text]
  • 2020–21 Commencement Program
    Commencement UNIVERSITY OF COLORADO BOULDER MAY 6, 2021 One Hundred Forty-Fifth Year of the University NORLIN CHARGE TO THE GRADUATES The first commencement at the University of Colorado was held for six graduates on June 8, 1882, in the chapel of Old Main. It was not until 40 years later, on September 4, 1922, that the first summer commencement was held. Since the first commencement in 1882, the University of Colorado Boulder has awarded more than 350,000 degrees. The traditional Norlin Charge to the graduates was first read by President George Norlin to the June 1935 graduating class. You are now certified to the world at large as alumni of the university. She is your kindly mother and you her cherished sons and daughters. This exercise denotes not your severance from her, but your union with her. Commencement does not mean, as many wrongly think, the breaking of ties and the beginning of life apart. Rather it marks your initiation in the fullest sense into the fellowship of the university, as bearers of her torch, as centers of her influence, as promoters of her spirit. The university is not the campus, not the buildings on campus, not the faculties, not the students of any one time—not one of these or all of them. The university consists of all who come into and go forth from her halls, who are touched by her influence, and who carry on her spirit. Wherever you go, the university goes with you. Wherever you are at work, there is the university at work.
    [Show full text]
  • Hibonite-(Fe); (Fe; Mg)Al12o19; a New Alteration Mineral from The
    American Mineralogist, Volume 95, pages 188–191, 2010 LETTER Hibonite-(Fe), (Fe,Mg)Al12O19, a new alteration mineral from the Allende meteorite CHI MA* Division of Geological and Planetary Sciences, California Institute of Technology, Pasadena, California 91125, U.S.A. ABSTRA C T 2+ Hibonite-(Fe), (Fe,Mg)Al12O19, is the Fe -dominant analog of hibonite CaAl12O19, discovered in a highly altered Ca-,Al-rich refractory inclusion from the Allende meteorite. It occurs as scattered micrometer-sized single crystals within an aggregate of hercynite (Fe,Mg)Al2O4, adjacent to nepheline, ilmenite, ferroan spinel, perovskite, and hibonite. The mean chemical composition determined by electron microprobe analysis of hibonite-(Fe) is Al2O3 90.05 wt%, FeO 3.60, SiO2 2.09, MgO 1.61, Na2O 0.55, CaO 0.28, TiO2 0.04, V2O3 0.02, sum 98.25, corresponding to an empirical formula of 2+ (Fe 0.34Mg0.27Na0.12Al0.11Ca0.03)Σ0.87 (Al11.77Si0.23)Σ12.00O19. Hibonite-(Fe) is hexagonal, P63/mmc; a = 5.613 Å, c = 22.285 Å, V = 608.0 Å3 and Z = 2. Its electron backscatter diffraction pattern is a good match to that of the hibonite structure. Hibonite-(Fe) is apparently a secondary alteration product formed by iron-alkali-halogen metasomatism, whereas hibonite is a primary refractory phase. Keywords: Hibonite-(Fe), (Fe,Mg)Al12O19, a new Al-rich mineral, refractory inclusion, secondary alteration, Allende meteorite, carbonaceous chondrite, nanomineralogy INTRODU C TION material (Caltech Allende12A section D) has been deposited in Nanomineralogy is the study of Earth and planetary materi- the Smithsonian Institution’s National Museum of Natural His- als at nano-scales, focused on characterizing nanofeatures (like tory, Washington, D.C., and is cataloged under USNM 7554.
    [Show full text]