TABELA PERIÓDICA DOS ELEMENTOS Α Lu Β Lr Ε Ζ

Total Page:16

File Type:pdf, Size:1020Kb

TABELA PERIÓDICA DOS ELEMENTOS Α Lu Β Lr Ε Ζ 1 2 1 2 1766 Cavendish 1868 Ramsay/Cleve H TABELA PERIÓDICA DOS ELEMENTOS He Hidrogênio Hélio Hidrogenium Helium Unium/U Bium/B 3 4 5 6 7 8 9 10 [He] 1 [He] 2 [He] 2-1 [He] 2-2 [He] 2-3 [He] 2-4 [He] 2-5 [He] 2-6 1817 Arfvedson 1798 Vauquelin 1808 Davy/Gay-Lussac 3750 aC Desconhecido 1772 Rutherford 1771 Priestley/Scheele 1810 Moissan 1898 Ramsay/Travers Li Be B C N O F Ne Lítio Berílio Boro Carbono Nitrogênio Oxigênio Flúor Neônio Lithium Beryllium Borium Carbonium Nitrogenium Oxygenium Fluorum Neon Trium/T Quadium/Q Pentium/P Hexium/H Septium/S Octium/O Ennium/E Unilium/Un 11 12 13 14 15 16 17 18 [Ne] 1 [Ne] 2 [Ne] 2-1 [Ne] 2-2 [Ne] 2-3 [Ne] 2-4 [Ne] 2-5 [Ne] 2-6 1807 Davy 1755 Black 1825 Oersted 1824 Berzelius 1669 Brandt 2000 aC Desconhecido 1774 Scheele 1894 Ramsay/Rayleigh Na Mg Al Si P S Cl Ar Sódio Magnésio Alumínio Silício Fósforo Enxofre Cloro Argônio Natrium Magnesium Aluminium Silicium Phosphorum Sulphur Chlorum Argon Ununium/Uu Unbium/Ub Untrium/Ut Unquadium/Uq Unpentium/Up Unhexium/Uh Unseptium/Us Unoctium/Uo 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 [Ar] 1 [Ar] 2 [Ar] 2-1 [Ar] 2-2 [Ar] 2-3 [Ar] 2-4 [Ar] 2-5 [Ar] 2-6 [Ar] 2-7 [Ar] 2-8 [Ar] 2-9 [Ar] 2-10 [Ar] 2-10-1 [Ar] 2-10-2 [Ar] 2-10-3 [Ar] 2-10-4 [Ar] 2-10-5 [Ar] 2-10-6 1807 Davy 1808 Davy 1879 Nilson 1791 Gregor/Klaproth 1801 del Rio 1797 Vauquelin 1774 Gahn 5000 aC Desconhecido 1732 Brandt 1751 Cronstedt 9000 aC Desconhecido 1000 aC Desconhecido 1875 Boiskaudran 1886 Winkler 2500 aC Alb. Magnus 1817 Berzelius 1825 Balard 1898 Ramsay/Travers K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr Potássio Cálcio Escândio Titânio Vanádio Cromo Manganês Ferro Cobalto Níquel Cobre Zinco Gálio Germânio Arsênio Selênio Bromo Criptônio Kalium Calcium Scandium Titanium Vanadium Cromium Manganum Ferrum Cobaltum Niccolum Cuprum Zincum Gallium Germanium Arsenicum Selenium Bromum Krypton Unennium/Ue Binilium/Bn Biunium/Bu Bibium/Bb Bitrium/Bt Biquadium/Bq Bipentium/Bp Bihexium/Bh Biseptium/Bs biotium/Bo Biennium/Be Trinilium/Tn Triunium/Tu Tribium/Tb Tritrium/Tt Triquadium/Tq Tripentium/Tp Trihexium/Th 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 [Kr] 1 [Kr] 2 [Kr] 2-1 [Kr] 2-2 [Kr] 2-3 [Kr] 2-4 [Kr] 2-5 [Kr] 2-6 [Kr] 2-7 [Kr] 2-8 [Kr] 2-9 [Kr] 2-10 [Kr] 2-10-1 [Kr] 2-10-2 [Kr] 2-10-3 [Kr] 2-10-4 [Kr] 2-10-5 [Kr] 2-10-6 1861 Bunsen/Kirchhoff 1787 Crawford 1794 Gadolin 1789 Klaproth 1801 Hatchet 1778 Scheele 1937 Perrier/Segrè 1844 Claus 1804 Wollaston 1803 Wollaston 5000 aC Desconhecido 1817 Stromeyer 1863 Reich/Richter 3500 aC Desconhecido 3000 aC Desconhecido 1782 von Reichenstein 1811 Courtois 1898 Ramsay/Travers Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe Rubídio Estrôncio Ítrio Zircônio Nióbio Molibdênio Tecnécio Rutênio Ródio Paládio Prata Cádmio Índio Estanho Antimônio Telúrio Iodo Xenônio Rubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Argentum Cadmium Indium Stannum Stibium Tellurium Iodum Xenon Triseptium/Ts Triumctium/To Triennium/Te Quadrinilium/Qn Quadriunium/Qu Quadribium/Qb Quadritrium/Qt Quadriquadium/Qq Quadripentium/Qp Quadrihexium/Qh Quadriseptium/Qs Quadriumctium/Qo Quadriennium/Qe Pentanilium/Pn Pentaunium/Pu Pentabium/Pb Pentatrium/Pt Pentaquadium/Pq 55 56 57-70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 [Xe] 1 [Xe] 2 [Xe] 2-14-1 [Xe] 2-14-2 [Xe] 2-14-3 [Xe] 2-14-4 [Xe] 2-14-5 [Xe] 2-14-6 [Xe] 2-14-7 [Xe] 2-14-8 [Xe] 2-14-9 [Xe] 2-14-10 [Xe] 2-14-10-1 [Xe] 2-14-10-2 [Xe] 2-14-10-3 [Xe] 2-14-10-4 [Xe] 2-14-10-5 [Xe] 2-14-10-6 1860 Kirchhoff/Bunsen 1772 Davy 1906 Urbain 1911 Coster/Hevesy 1802 Ekeberg 1781 Gebrüder Elhuyar 1908 Noddack/Tacke 1803 Tenant 1803 Tenant/Andere 1557 Scaliger 6000 aC Desconhecido 2000 aC Desconhecido 1861 Crookes 7000 aC Desconhecido 1753 Agricola 1898 Marie/P. Curie 1940 Corson/Mack. 1898 Dorn Cs Ba α Lu Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn Césio Bário Lutécio Háfnio Tântalo Tungstênio Rênio Ósmio Irídio Platina Ouro Mercúrio Tálio Chumbo Bismuto Polônio Astato Radônio Caesium Barium Lutetium Hafnium Tantalum Wolframium Rhenium Osmium Iridium Platinum Aurum Hydrargyrum Thallium Plumbum Bismuthum Polonium Astatum Radon Pentapentium/Pp Pentahexium/Ph Septaunium/Su Septabium/Sb Septatrium/St Septaquadium/Sq Septapentium/Sp Septahexium/Sh Septaseptium/Ss Septaoctium/So Septaennium/Se Octanilium/On Octaunium/Ou Octabium/Ob Octatrium/Ot Octaquadium/Oq Octapentium/Op Octahexium/Oh 87 88 89-102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 [Rn] 1 [Rn] 2 [Rn] 2-14-1 [Rn] 2-14-2 [Rn] 2-14-3 [Rn] 2-14-4 [Rn] 2-14-5 [Rn] 2-14-6 [Rn] 2-14-7 [Rn] 2-14-8 [Rn] 2-14-9 [Rn] 2-14-10 [Rn] 2-14-10-1 [Rn] 2-14-10-2 [Rn] 2-14-10-3 [Rn] 2-14-10-4 [Rn] 2-14-10-5 [Rn] 2-14-10-6 1939 Perey 1898 Marie/P. Curie 1961 Ghiorso 1968 Flerow o. Ghiorso 1970 Flerow o. Ghiorso 1974 Oganessian 1981 Oganessian 1984 Sociedade 1982 Sociedade 1994 Sociedade 1994 Sociedade 1996 Sociedade 2003 1999 Sociedade 2003 2000 Sociedade 2010 2002 Fr Ra β Lr Rf Db Sg Bh Hs Mt Ds Rg Cn Nh Fl Mc Lv Ts Og Frâncio Rádio Laurêncio Ruterfórdio Dúbnio Seabórgio Bóhrio Hássio Meitnério Darmstádio Roentgênio Copernício Nihônio Fleróvio Moscóvio Livermório Tenessínio Oganessônio Francium Radium Lawrencium Rutherfordium Dubnium Seaborgium Bohrium Hassium Meitnerium Darmstadtium Roentgenium Copernicium Nihonium Flerovium Moscovium Livermorium Tennesine Oganesson Octaseptium/Os Octaoctium/Oo Unniltrium/Unt Unnilquadium/Unq Unnilpentium/Unp Unnilhexium/Unh Unnilseptium/Uns Unniloctium/Uno Unnilennium/Une Ununilium/Uun Unununium/Uuu Ununbium/Uub Ununtrium/Uut Ununquadium/Uuq Ununpentium/Uup Ununhexium/Uuh Ununseptium/Uus Ununoctium/Uuo 119 120 121-152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 [Og] 1 [Og] 2 [Og] 2-18-14-1 [Og] 2-18-14-2 [Og] 2-18-14-3 [Og] 2-18-14-4 [Og] 2-18-14-5 [Og] 2-18-14-6 [Og] 2-18-14-7 [Og] 2-18-14-8 [Og] 2-18-14-9 [Og] 2-18-14-10 [Og] 2-18-14-10-1 [Og] 2-18-14-10-2 [Og] 2-18-14-10-3 [Og] 2-18-14-10-4 [Og] 2-18-14-10-5 [Og] 2-18-14-10-6 2007 Michael Serra 2007 Michael Serra 2007 Michael Serra 2007 Michael Serra 1992 Peter A. Fields 430 aC Ésquilo 1967 Art Wallace 1962 Stan Lee/Lieber 1968 JRR Tolkien 1992 John Byrne/J. Lee 2014 John J. Miller 2007 Michael Serra 2007 Michael Serra Cb Ma γ Tu Oo Nm Sf Nl Ad T Ur M Bl Ss Cc Ct Km Ao It Calerbano Maristênio Tundrânio Osmásio Nítrio Semafer Náuplio Adamântio Tritânio Urídio Mitrílio Belênio Sargássio Carbonádio Cortosis Cermétio Antiópio Ilítio Calerbanum Maristhenium Tundranium Osmasium Nitrium Semaferium Nauplium Adamantium Tritanium Uridium Mithrilium Belenium Sargassium Carbonadium Cortosium Kermethium Antiopium Ilithium Ununennium/Uue Unbinilium/Ubn Unpentatrium/Upt Unpentaquadium/Upq Unpentapentium/Upp Unpentahexium/Uph Unpentaseptium/Ups Unpentaoctium/Upo Unpentaennium/Upe Unhexanilium/Uhn Unhexaunium/Uhu Unhexabium/Uhb Unhexatrium/Uht Unhexaquadium/Uhq Unhexapentium/Uhp Unhexahexium/Uhh Unhexaseptium/Uhs Unhexaoctium/Uho 169 170 171-202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 [It] 1 [It] 2 [It] 2-18-14-1 [It] 2-18-14-2 [It] 2-18-14-3 [It] 2-18-14-4 [It] 2-18-14-5 [It] 2-18-14-6 [It] 2-18-14-7 [It] 2-18-14-8 [It] 2-18-14-9 [It] 2-18-14-10 [It] 2-18-14-10-1 [It] 2-18-14-10-2 [It] 2-18-14-10-3 [It] 2-18-14-10-4 [It] 2-18-14-10-5 [It] 2-18-14-10-6 2007 Michael Serra 2007 Michael Serra 1975 Stanley Ross 1997 Mark Garland 1986 M. Kurumada 1901 HG Wells 1994 Akira Toriyama 1940 Gardner Fox 2007 "Valve" 1966 Stan Lee 360 aC Platão 2015 Roland Lesterlin 1966 G. Roddenberry 1914 HG Wells 1930 Edgar Burroughs 1994 M. Straczynski 1989 Sam Rolfe 2006 B. Sanderson Ke Aa δ Fn Td Gm Cv Kt Nt Oz Vi Oc Bv Du Ch Hb Dm Nn Aw Kerílio Amarântio Fêmino Trélio Gamânio Cavório Catim Nítio Austrálio Vibrânio Oricalco Bavário Durânio Carolino Harbênio Dirídio Norânio Átio Kerilium Amarantium Feminum Trellium Gammanium Cavorium Kattinium Nthium Australium Vibranium Orichalcum Bavarium Duranium Carolinum Harbenium Diridium Noranium Atium Unhexaennium/Uhe Unseptanilium/Usn Biniltrium/bnt Binilquadium/Bnq Binilpentium/Bnp Binilhexium/Bnh Binilseptium/Bns Biniloctium/Bno Binilennium/Bne Biunilium/Bun Biununium/Buu Biunbium/Bub Biuntrium/But Biunquadium/Buq Biunpentium/Bup Biunhexium/Buh Biunseptium/Bus Biunoctium/Buo 219 220 221-274 275 276 277 278 279 280 281 282 283 284 285 286 287 288 289 290 [Aw] 1 [Aw] 2 [Aw] 2-22-18-14-1 [Aw] 2-22-18-14-2 [Aw] 2-22-18-14-3 [Aw] 2-22-18-14-4 [Aw] 2-22-18-14-5 [Aw] 2-22-18-14-6 [Aw] 2-22-18-14-7 [Aw] 2-22-18-14-8 [Aw] 2-22-18-14-9 [Aw] 2-22-18-14-10 [Aw] 2-22-18-14-10-1 [Aw] 2-22-18-14-10-2 [Aw] 2-22-18-14-10-3 [Aw] 2-22-18-14-10-4 [Aw] 2-22-18-14-10-5 [Aw] 2-22-18-14-10-6 1991 C.
Recommended publications
  • Acoustic Properties of Solids
    Acoustic Properties of Solids Ref Material Vendor VL VS D ZL F Loss mm/:s mm/:s g/cm3 MRayl dB/cm AS Alumina Mason 10.52 3.86 40.6 CRC Aluminum - rolled 6.42 3.04 2.70 17.33 0.355 RLB Aluminum - 6262-T9 6.38 2.73 17.41 AMD Res-in-all - 502/118, 5:1 AMD 2.67 1.35 3.61 AMD Res-in-all - 502/118, 9:1 AMD 2.73 1.35 3.68 JA Araldite - 502/956 Ciba 2.62 1.16 3.04 JA Araldite - 502/956, 10phe C5W Ciba,Li 2.60 1.23 3.19 JA Araldite - 502/956, 20phe C5W Ciba,Li 2.54 1.39 3.52 JA Araldite - 502/956, 30phe C5W Ciba,Li 2.41 1.50 3.62 JA Araldite - 502/956, 40phe C5W Ciba,Li 2.31 1.67 3.86 JA Araldite - 502/956, 50phe C5W Ciba,Li 2.13 1.95 4.14 JA Araldite - 502/956, 60phe C5W Ciba,Li 2.10 2.24 4.70 JA Araldite - 502/956, 70phe C5W Ciba,Li 1.88 3.17 5.95 JA Araldite - 502/956, 80phe C5W Ciba,Li 1.72 4.71 8.11 JA Araldite - 502/956, 50phe 325mesh W Ciba,Li 2.16 2.86 6.17 JA Araldite - 502/956, 60phe 325mesh W Ciba,Li 1.91 2.78 5.33 JA Araldite - 502/956, 70phe 325mesh W Ciba.Li 1.82 3.21 5.84 JA Araldite - 502/956, 80phe 325mesh W Ciba,Li 1.64 4.55 7.45 JA Araldite - 502/956, 90phe 325mesh W Ciba,Li 1.52 8.40 12.81 AS Arsenic tri sulphide As2 S3 Ch 2.58 1.40 3.20 8.25 0.29 Bacon P38 Bacon 4.00 2.17 1.90 7.60 0.29 13.5 @ 5 M Bearing babbit 2.30 10.1 23.2 CRC Beryllium 12.89 8.88 1.87 24.10 0.046 Bismuth 2.2 1.1 9.8 21.5 0.33 Boron carbide 11.0 2.4 26.4 PK Boron nitride 5.03 3.86 1.965 9.88 Brass - yellow, 70% Cu, 30% Zn 4.70 2.10 8.64 40.6 0.38 Brick 4.3 1.7 7.4 Cadmium 2.8 1.5 8.6 24.0 0.30 AS Carbon -pyrolytic, soft, variable properties 3.31 2.21 7.31 AS Carbon - vitreous, very hard material Fl 4.26 2.68 1.47 6.26 0.17 Updated April 11, 2003 Page 1 of 7 Acoustic Properties of Solids Ref Material Vendor VL VS D ZL F Loss mm/:s mm/:s g/cm3 MRayl dB/cm AS Carbon - vitreous, Sigradur K Si 4.63 1.59 7.38 Columbium (same as Niobium) m.p.
    [Show full text]
  • Prof. Andrei A. Seryi John Adams Institute Lecture 1: Basics Of
    Prof. Andrei A. Seryi John Adams Institute Lecture 1: Basics of accelerators and the art of inventiveness USPAS 2016 LHC sketches by Sergio Cittolin (CERN) – used with permission June 2016 Accelerators can study art This painting “Patch of grass” by Vincent van Gogh was the first one analysed by a particle accelerator It showed a portrait of a woman underneath http://photon-science.desy.de/news__events/research_highlights/archive/visualizing_a_lost_painting_by_vincent_van_gogh/index_eng.html USPAS Course 2016, A. Seryi, JAI 2 Accelerators in archaeology The interior of samples can be studied using accelerators without destroying them Pottery from Armenia, dating back to 1300 BC, is set up for a synchrotron experiment Image: Argonne National Laboratory USPAS Course 2016, A. Seryi, JAI 3 Particle accelerators can read hidden text Accelerators can detect the X-ray ‘signature’ of iron in ancient pigments A written message can be revealed even on a folded manuscript which is too brittle to open This method has also been used to analyse Photo: Graham Davis & Tim Wess manuscripts and paintings that have layers of information from different authors USPAS Course 2016, A. Seryi, JAI 4 Accelerators can make food taste better Cadbury used X-rays from a particle accelerator to study how cocoa crystallises Of the six possible crystal forms, the fifth (form V) produces the best quality chocolate USPAS Course 2016, A. Seryi, JAI 5 Accelerators can help spot art forgeries Ion Beam Analysis shows us the chemical composition of pigments used in paint This allows art historians to compare them with paints available to artists like Leonardo da Vinci USPAS Course 2016, A.
    [Show full text]
  • Download Our Special Issue of Science & Technology Review
    SPECIAL ISSUE DESIGNER MATERIALS Also in this issue: Materials for National Security Materials Theory and Simulation Materials for Laser Systems SPECIAL ISSUE Contents Welcome from Bob Maxwell MATERIALS FOR NATIONAL SECURITY DESIGNER 2 Piecing Together a Nuclear Fireball By studying how different elements react inside a nuclear fireball, MATERIALS researchers gain valuable insight into predetonation conditions. 6 Detonation Science Blasts into a New Frontier Also in this issue: Using an advanced experimental facility, scientists gain insight Materials for National Security Materials Theory and Simulation into the nanoscale processes of high-explosive detonations. Materials for Laser Systems 10 Agent Defeat Efforts Strike Gold MATERIALS SCIENCE RESEARCH The cover image shows a three-dimensionally A highly effective payload material can destroy chemical printed carbon fiber part created using a Livermore- and biological weapons facilities. developed direct ink writing process. Laboratory SUPPORTS NATIONAL SECURITY researchers use and refine a range of advanced DESIGNER MATERIALS manufacturing techniques and technologies to create tailor-made, high-performance materials. 14 A New Composite-Manufacturing Approach Takes Shape Livermore researchers leverage chemistry, engineering, and computational expertise to develop a new manufacturing technique for high-performance composites. 18 Mimicking Mother Nature to Mitigate Climate Change Bioengineering and additive manufacturing come together ATERIALS are central to our national security missions
    [Show full text]
  • Thinking About America's Defense
    THE ARTS This PDF document was made available CHILD POLICY from www.rand.org as a public service of CIVIL JUSTICE the RAND Corporation. EDUCATION ENERGY AND ENVIRONMENT Jump down to document6 HEALTH AND HEALTH CARE INTERNATIONAL AFFAIRS The RAND Corporation is a nonprofit NATIONAL SECURITY research organization providing POPULATION AND AGING PUBLIC SAFETY objective analysis and effective SCIENCE AND TECHNOLOGY solutions that address the challenges SUBSTANCE ABUSE facing the public and private sectors TERRORISM AND HOMELAND SECURITY around the world. TRANSPORTATION AND INFRASTRUCTURE Support RAND WORKFORCE AND WORKPLACE Purchase this document Browse Books & Publications Make a charitable contribution For More Information Visit RAND at www.rand.org Explore RAND Project AIR FORCE View document details Limited Electronic Distribution Rights This document and trademark(s) contained herein are protected by law as indicated in a notice appearing later in this work. This electronic representation of RAND intellectual property is provided for non-commercial use only. Unauthorized posting of RAND PDFs to a non-RAND Web site is prohibited. RAND PDFs are protected under copyright law. Permission is required from RAND to reproduce, or reuse in another form, any of our research documents for commercial use. For information on reprint and linking permissions, please see RAND Permissions. This product is part of the RAND Corporation occasional paper series. RAND occasional papers may include an informed perspective on a timely policy issue, a discussion of new research methodologies, essays, a paper presented at a conference, a conference summary, or a summa- ry of work in progress. All RAND occasional papers undergo rigorous peer review to ensure that they meet high standards for research quality and objectivity.
    [Show full text]
  • [Target 50–60M, Actual 76M Incl 73-87 on Materialss]
    [target 50–60m, actual 76m incl 73-87 on materialss] Integrative design for radical energy and materials efficiency at lower cost IIASA internal seminar Laxenburg, 02 September 2019 M OUN KY T C A I O N R I N E STIT U T Amory B. Lovins Cofounder and Chairman Emeritus, RMI (www.rmi.org) Independent contractor, Lovins Associates LLC [email protected] Copyright © 2019 Lovins Associates LLC. All rights reserved. Thank you for this opportunity to “re-mind” you about how to design whole systems for radical efficiency in using energy, water, metals, and other resources. The practice I’ll summarize applies orthodox engineering principles but asks different design questions in a different order and therefore gets very different answers. I recently presented this material as a six-day intensive course, and my team is developing various other tools to help turn this approach from rare to common. * Clean watts are the easy part I won’t be talking today (rather tomorrow) about energy supply. Modern renewables now provide two-thirds of the world’s net additions of electric capacity, thanks to their powerful business case. Our bigger challenge is capturing modern negawatts. * Reduced energy intensity has had 30× the impact of renewable growth (United States, 1965–2018p, not weather-normalized, EIA data) 250 Primary energy use if at 1975 efficiency and structure 200 1975–2018p savings Energy saved by reduced intensity from intensity reduction: 150 2,589 qBTU 100 Primary energy use, 1965–1975 Actual primary energy use 50 Growth in renewable energy use 1975–2018p growth in total renewable output: U.S.
    [Show full text]
  • Terraforming
    TERRAFORMING Liverpool Science Fiction Texts and Studies, 55 Liverpool Science Fiction Texts and Studies Editor David Seed, University of Liverpool Editorial Board Mark Bould, University of the West of England Veronica Hollinger, Trent University Rob Latham, University of California Roger Luckhurst, Birkbeck College, University of London Patrick Parrinder, University of Reading Andy Sawyer, University of Liverpool Recent titles in the series 30. Mike Ashley Transformations: The Story of the Science-Fiction Magazine from 1950–1970 31. Joanna Russ The Country You Have Never Seen: Essays and Reviews 32. Robert Philmus Visions and Revisions: (Re)constructing Science Fiction 33. Gene Wolfe (edited and introduced by Peter Wright) Shadows of the New Sun: Wolfe on Writing/Writers on Wolfe 34. Mike Ashley Gateways to Forever: The Story of the Science-Fiction Magazine from 1970–1980 35. Patricia Kerslake Science Fiction and Empire 36. Keith Williams H. G. Wells, Modernity and the Movies 37. Wendy Gay Pearson, Veronica Hollinger and Joan Gordon (eds.) Queer Universes: Sexualities and Science Fiction 38. John Wyndham (eds. David Ketterer and Andy Sawyer) Plan for Chaos 39. Sherryl Vint Animal Alterity: Science Fiction and the Question of the Animal 40. Paul Williams Race, Ethnicity and Nuclear War: Representations of Nuclear Weapons and Post-Apocalyptic Worlds 41. Sara Wasson and Emily Alder, Gothic Science Fiction 1980–2010 42. David Seed (ed.), Future Wars: The Anticipations and the Fears 43. Andrew M. Butler, Solar Flares: Science Fiction in the 1970s 44. Andrew Milner, Locating Science Fiction 45. Joshua Raulerson, Singularities 46. Stanislaw Lem: Selected Letters to Michael Kandel (edited, translated and with an introduction by Peter Swirski) 47.
    [Show full text]
  • Ahead of the Herd Newsletter - 2018 Issue Forty Seven
    Ahead of the Herd Newsletter - 2018 Issue Forty Seven Saturday October 20th Building the most critical metals mine in America As a general rule, the most successful man in life is the man who has the best information In the movie Avatar, humans have depleted their natural resources to the point where there’s a severe energy crisis. The year is 2154. To maintain civilization, they must travel to a distant solar system to mine unobtanium (not the most original name for a rare metal) on Pandora, a densely forested moon inhabited by the Na’vi, a species of 10-foot tall “humanoids” who live in harmony with nature. Pandora’s atmosphere is poisonous to humans, so they employ Na’vi-human hybrids called avatars. The lead character, Jake Sully, is a paraplegic former Marine who replaces his dead identical twin brother as an avatar, and is sent to Pandora to act as a bodyguard. The story unfolds from there. James Cameron’s 2009 science fiction blockbuster plays on themes of colonialism and environmentalism, but it is also a good analog for the present situation the United States find itself in regarding access to critical minerals - obviously not yet for the survival of the human race, but for applications considered vital for the defense of the nation, and to supply materials needed for the inevitable shift from an economy powered by fossil fuels, to one more dependent on non-carbon- based sources of energy such as renewables, nuclear and hydroelectricity. Most people don’t know it, but the US is dependent on foreign countries for a number of these critical metals, including battery metals used in electronic devices like cell phones and electric vehicles.
    [Show full text]
  • Rare Earth Elements Development, Sustainability and Policy Issues
    The Extractive Industries and Society xxx (xxxx) xxx–xxx Contents lists available at ScienceDirect The Extractive Industries and Society journal homepage: www.elsevier.com/locate/exis Original article Rare earth elements: Development, sustainability and policy issues Julie Michelle Klinger Frederick S. Pardee School of Global Studies, Boston University, United States ARTICLE INFO ABSTRACT Keywords: Rare earth elements are essential to modern life as we know it. With their exceptional magnetic and conductive Rare earth elements properties, they enable the hardware of contemporary life to be faster, lighter, and stronger. Since the 2010 crisis Development precipitated in part by China’s then de facto monopoly over rare earth production, diverse actors across the globe Sustainability have pursued multiple and sometimes conflicting measures to transform the industry. These include efforts to History open new mines, lower prices, mitigate social and environmental harms, curtail black market activity, identify Popular culture substitutable elements, and achieve national-level supply security. These diverse efforts intersect with broader geopolitical, historical, and cultural struggles around the world. The outcomes of these efforts vary, though arguably few have generated intended results. Several years after the global (re)awakening to the importance of rare earth elements and the hazards associated with their production, the relationship between its industries and society, broadly defined, remains troubled in practice, poorly-conceived in policy, and under-examined in the social science literature. This special issue convenes emergent social science research into some of the devel- opment, sustainability, and historical issues surrounding rare earth elements in different times, places and sectors across the globe. 1.
    [Show full text]
  • What Is the Critical Materials Institute?
    What is the Critical Materials Institute? Alex King A measured response to a crisis 2 Materials criticality is affecting us today • The target date for transition to high-output T5 fluorescent lamps has been delayed by two years because manufacturers claim that there is a shortage of Eu and Tb for the phosphors. • Utility-scale wind turbine installations are overwhelmingly gearbox-driven units, despite the high failure-rate of the gearboxes, because of the cost and unavailability of Nd and Dy required for direct-drive units. 3 The Critical Materials Institute • An Energy Innovation Hub – Supported by the US Department of Energy, Advanced Manufacturing Office – One of only four such Hubs supported by DOE. • Budget of $120M, over five years • Led by the Ames Laboratory – Four national labs – Seven university partners – Seven industrial partners – Approximately 300 researchers • www.cmi.ameslab.gov 4 The Mission of CMI To assure supply chains of materials critical to clean energy technologies, enabling innovation in US manufacturing, and enhancing US energy security. 5 What is criticality? • Identifies the propensity for supply-chain problems to occur. It does not predict that they will. • Identifies the need for appropriate attention, not panic. • Depends on location, industry- sector, and time. DOE Medium Term Outlooks: 2015 – 2025 6 Critical materials for the European Union European Commission, May 2014 7 EU critical materials for decarbonization 8 A three-pillared research strategy Find ways to: • diversify our sources; • provide alternatives to the existing materials; • make better use of the existing supplies through recycling and re- use. Some of these approaches work better than others for specific materials.
    [Show full text]
  • Making Starships and Stargates the Science of Interstellar Transport and Absurdly Benign Wormholes
    Making Starships and Stargates The Science of Interstellar Transport and Absurdly Benign Wormholes James F. Woodward Making Starships and Stargates The Science of Interstellar Transport and Absurdly Benign Wormholes With illustrations by Nembo Buldrini and Foreword by John G. Cramer James F. Woodward Anaheim, California USA SPRINGER-PRAXIS BOOKS IN SPACE EXPLORATION ISBN 978-1-4614-5622-3 ISBN 978-1-4614-5623-0 (eBook) DOI 10.1007/978-1-4614-5623-0 Springer New York Heidelberg Dordrecht London Library of Congress Control Number: 2012948981 # James F. Woodward 2013 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. Exempted from this legal reservation are brief excerpts in connection with reviews or scholarly analysis or material supplied specifically for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Duplication of this publication or parts thereof is permitted only under the provisions of the Copyright Law of the Publisher’s location, in its current version, and permission for use must always be obtained from Springer. Permissions for use may be obtained through RightsLink at the Copyright Clearance Center. Violations are liable to prosecution under the respective Copyright Law. The use of general descriptive names, registered names, trademarks, service marks, etc.
    [Show full text]
  • Decolonising James Cameron's Pandora: Imperial History And
    Decolonising James Cameron’s Pandora: Imperial history and science fiction Dominic Alessio Richmond University, the American University in London Kristen Meredith University of Cambridge Abstract The science fiction film Avatar will be examined in light of the social-political context in which it was written, demonstrating the director’s highly charged critique of US foreign policy. Yet this paper also argues that the depiction of the alien native species remains problematic from a postcolonial perspective. “Decolonising Pandora” addresses too the ways that Avatar has been used for political ends by peoples throughout the world, while acting as a vehicle for a critical examination of traditional definitions of empire and imperial history overall. Introduction James Cameron’s science fiction (SF) blockbuster Avatar (2009) is a film about futuristic human-alien contact that takes place on a fictional moon called Pandora in the Alpha Centauri star system. It is famous for being the most expensive cinematic production ever made, its groundbreaking 3-D technology, and the fact that it has grossed over two billion US dollars worldwide. Yet it is of interest for more than just special effects and profit margins. Avatar has been also the subject of considerable media discussion regarding its anti-establishment political ideology and its historical revisionism. This paper has four aims. Firstly, Avatar will be examined in light of the social-political context in which it was written, namely the American-led invasion of Iraq at the start of the twenty-first century during the presidency of George W. Bush (2000-2008). The film’s dialogue references the requirement to “fight terror with terror,” “shock and awe,” and a “hearts and minds” strategy, while the plot centers on the need to gain control of a valuable energy source (“unobtainium” as opposed to oil).
    [Show full text]
  • What Are We Going to Make Magnets From?
    MagNews 25/05/20 What are we going to make magnets from? Prof Alex King Department of Materials Science and Engineering, Iowa State University Based on a keynote presentation delivered at the 2019 MMM-Intermag, Washington, USA he market for permanent magnets is dominated by ferrites at the low end of the T performance spectrum and rare earths at the high end. When the rare earth elements became the poster-children for critical materials in around 2010 [1], concerns grew about supplies of the elements that go into high-strength magnets based on the Nd2Fe14B formula – in which some of the neodymium can be replaced with praseodymium, dysprosium and/or terbium, depending on the intended applications of the magnets. All of those elements, however, are rare earths and rare earths are mined extracted from ores in which they co- exist, so a shortage of one tends to predict a shortage for others. Much effort has gone into finding replacements for Nd-Fe-B, in response to the rare earth supply-chain uncertainties. In 2008, 98% of the world’s supply of rare earths came from China, and it was reducing its exports. The Chinese government had begun imposing annual export quotas on rare earths in 2005, and it sharply reduced the quota in 2010, as its domestic industries increased their utilisation of these materials. Anxieties rose further in September of 2010, when it was reported that China had cut off all rare earth shipments to Japan in response to a collision between a Japanese Coast Guard vessel and a Chinese fishing boat in waters near a disputed group of islands in the East China Sea, known as Senkaku in Japan, and Diaoyu in China.
    [Show full text]