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  • AIME
    Institute of Metals Division - Orientation Relationships in Cast Germanium

    By J. Fageant, W. C. Ellis

    All major regions in a progressively solidified germanium ingot were related through successive orders of octahedral twinning. The occurrence of lineage structure and the generation and survival of or

    Jan 1, 1955

  • AIME
    Institute of Metals Division - Orientation Relationships in the Heterogenous Nucleation of Solid Lead from Liquid Lead

    By L. F. Mondolfo, B. E. Sundquist

    The crystallographic orientation relationships resulting when lead is nucleated from the liquid by Ni, Cu, Ag, and Ge were determined. For each nucleating agent several definite orientatioz relationsh

    Jan 1, 1962

  • AIME
    Institute of Metals Division - Orientation Relationships in the Recrystallization of Deformed Copper Single Crystals

    By J. N. Hobstetter, J. J. Becker

    Deformed copper single crystals exhibited, upon annealing, a recrystallized twinned grain with a twin plane parallel to an active deformation plane, rotated approximately 22" about its pole, or else d

    Jan 1, 1954

  • AIME
    Institute of Metals Division - Orientations of Large Grains in Tungsten Wire (TN)

    By A. J. Opinsky, J. L. Orehotsky, L. L. Seigle

    TUNGSTEN incandescent lamp filaments possess a typical structure of elongated crystals generated upon heating the silica-alumina doped wire rapidly to 2200°C or above.' It is known that these ver

    Jan 1, 1962

  • AIME
    Institute of Metals Division - Origin of Porosity in Castings of Magnesium-Aluminum and Other Alloys

    By E. J. Whittenberger, F. N. Rhines

    The formation of casting porosity is viewed as a nucleation and growth process with solidification shrinkage and gas precipitation as cooperative driving forces. Experimental evidence evaluating the i

    Jan 1, 1953

  • AIME
    Institute of Metals Division - Oxidation Kinetics of Tantalum in Carbon Dioxide

    By M. E. Wadsworth, K. J. Richards

    The oxidation rates of tantalum in various partial pressures of carbon dioxide in the temperature range 700°to 950°C were measured with a thermo-gravimetric balance. Oxidation involved a surface -cont

    Jan 1, 1964

  • AIME
    Institute of Metals Division - Oxidation of Cobalt Metal

    By R. E. Carter, C. Wagner, F. D. Richardson

    By means of inert markers of radio-platinum, it has been shown that cobalt metal oxidizes by out-ward diffusion of cobalt atoms through the oxide. Oxidation rates have been measured at various tempera

    Jan 1, 1956

  • AIME
    Institute of Metals Division - Oxidation of Molybdenum Silicides at High Temperatures and Low Pressures

    By P. R. Gage, R. W. Bartlett

    At high temperatues and reduced oxygen pressuves, molybdenum silicicles oxidize to form SiO(g) vathev than a passivating SiO2 film. This is a sevious problem for low-pressure applications of sili-cide

    Jan 1, 1965

  • AIME
    Institute of Metals Division - Oxidation of Single-Crystal and Polycrystalline Zirconium

    By T. L. MacKay

    Oxidation rates of single-crystal and poly crystalline zirconium in oxygen at temperatures from 307° to 815°C obey the parabolic rate law for short ex-posure time, 4 to 6 hr. The activation energy fo

    Jan 1, 1963

  • AIME
    Institute of Metals Division - Oxidation of the Uranium-Copper Intermetallic Compound UCu5 in Carbon Dioxide between 350° and 850°C

    By R. J. Pearce, I. Whittle, J. J. Stobbs

    The oxidation kinetics of UCu5 in carbon dioxide have been studied over the temperature range 350° to 850°C. At any one temperature, two successive parabolic rate constants are obtained. Up to 650°C,

    Jan 1, 1965

  • AIME
    Institute of Metals Division - Oxidation of Tin (TN)

    By Charles Luner

    ALTHOUGH the kinetics of the atmospheric oxidation of tin have been studied,1-3 the kinetics in pure oxygen have not been reported. This note presents some results of the kinetics of the oxidation of

    Jan 1, 1961

  • AIME
    Institute of Metals Division - Oxidation of Titanium

    By C. E. Birchenall, M. H. Davis

    The rate of oxidation of titanium in the temperature range 650° to 950°C has been measured. 'The linear rate law obtained is explained by interface reaction control of the process. Tracer experim

    Jan 1, 1952

  • AIME
    Institute of Metals Division - Oxidation-Nitrification of Chromium at 1000°C

    By A. U. Seybolt, D. H. Haman

    The rate of oxidation of the lowest nitride of chromium, Cr2N, was measured to be equal to the rate of oxidation of chromium metal. It was found that, while the presence of Cr2N in chromium does not a

    Jan 1, 1964

  • AIME
    Institute of Metals Division - Oxide Bonding and the Creep-Rupture Strength of Nickel

    By T. R. Cass, M. R. Achter

    A technique for measuring the creep and rupture strength of nickel specimens bonded by sintered oxide layers has been developed for the investigation of the role of grain-boundary oxide in the oxidati

    Jan 1, 1962

  • AIME
    Institute of Metals Division - Partial Titanium-Vanadium Phase Diagram

    By Pol Duwez, Paul Pietrokowsky

    Titanium and vanadium form a complete series of solid solutions at temperatures above 885°C. Below 885°C, vanadium is slightly soluble in a titanium (about 1.5 pct V at 650°C) and a two-phase a plus ß

    Jan 1, 1953

  • AIME
    Institute of Metals Division - Penetration of Liquid Bismuth into the Grain Boundaries of a Nickel Alloy

    By C. W. Spencer, F. G. Hochgraf, R. F. Cheney

    Columnar grained specimens of nickel, containing 0.25 pct Si and 0.22 pct Mn, have been exposed to liquid bismuth in the temperature range 670° to 1050°C. Under isothermal conditions the liquid penet

    Jan 1, 1962

  • AIME
    Institute of Metals Division - Phase Changes in Precipitation Hardening Nickel-Chromium-Iron Alloys during Prolonged Heating

    By C. C. Clark, J. S. Iwanski

    The purpose of this investigation was to study mi-crostructural changes that take place in a commercial nickel-chromium-iron alloy, such as Incoloy "901," over long periods of time at temperatures up

    Jan 1, 1960

  • AIME
    Institute of Metals Division - Phase Diagram and Thermodynamic Properties of the Thorium-Zinc System

    By K. J. Gill, P. Chiotti

    Thermal, metallographic, and vapor pressure data were obtained to establish the phase diagram for the thorium-zinc system. Four compounds corresponding to the stoichiometric formulas Th2Zn, ThZn2, ThZ

    Jan 1, 1962

  • AIME
    Institute of Metals Division - Phase Diagram and Thermodynamic Properties of the Yttrium-Zinc System

    By K. J. Gill, P. Chiotti, J. T. Mason

    Thermal, metallographic, and vapor pressure data were obtained to establish the pkase boundaries and the standard free energy, enthalpy, and entropy of formation for the compounds in the Y-Zn system.

    Jan 1, 1963

  • AIME
    Institute of Metals Division - Phase Equilibria and Elevated-Temperature Properties of Some Alloys in the System Ni3Cr-Ni3Al

    By C. H. Li, R. J. Stokes, T. L. Johnston

    A portion of the Ni3Cr-Ni3Al phase dzagram has been investigated, including the precipitation of 1 (Ni3Al) as well as the existence of ordered Y (Ni matrix), Extensive metallographic studies by electr

    Jan 1, 1962