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  • 1
    Electronic Resource
    Electronic Resource
    A study of the seasonal migration of ITCZ and the quasi-periodic oscillations in a simple monsoon system using an energy balance model (1989)
    Springer
    Meteorology and atmospheric physics 41 (1989), S. 191-211 
    Details
    ISSN: 1436-5065
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geography , Physics
    Notes: Summary A zonally averaged global energy balance model with feedback mechanisms was constructed to simulate (i) the poleward limits of ITCZ over the continent and over the ocean and (ii) a simple monsoon system as a result of differential heating between the continent and the ocean. Three numerical experiments were performed with lower boundary as (1) global continent, (2) global ocean and (3) continent-ocean, with freezing latitudes near the poles. Over the continent, midlatitude deserts were found and the ITCZ migrates 25° north and south with seasons. Over a global swamp ocean results do not show migration of ITCZ with time but once the ocean currents are introduced the ITCZ migrates 5° north and south with seasons. It was found that the seasonal migration of ITCZ strongly depends on the meridional distribution of the surface temperature. It was also found that continent influences the location of the oceanic ITCZ. In the tropics northward progression of quasi-periodic oscillations called “events” are found during the pre- and post-monsoon periods with a period of 8 to 15 days. This result is consistent with the observed quasi-periodic oscillations in the tropical region. Northward propagation of the surface temperature perturbation appears to cause changes in the sensible heat flux which in turn causes perturbations in vertical velocity and latent heat flux fields.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01026110
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  • 2
    Electronic Resource
    Electronic Resource
    Vaporization of In2Te3(s) (1986)
    Springer
    Monatshefte für Chemie 117 (1986), S. 695-712 
    Details
    ISSN: 1434-4475
    Keywords: Indium telluride, thermodynamics, vaporization chemistry ; Torsion effusion ; Knudsen effusion ; High temperature mass spectrometry
    Source: Springer Online Journal Archives 1860-2000
    Topics: Chemistry and Pharmacology
    Description / Table of Contents: Zusammenfassung Die Chemie der Verdampfung von In2Te3(s) wurde mittels automatisierter gleichzeitiger Anwendung derKnudsen- und Torsions-Effusion, mittels Hochtem-peraturmassenspektrometrie und entsprechenden Hilfsmethoden untersucht. Es wird über die ersten absoluten Messungen des Dampfdrucks von In2Te3 berichtet. In2Te3(s) verdampfte inkongruent im Temperaturbereich von 701–889 K, wobei Te2(g) und eine feste Lösung mit der ZusammensetzungX In=0.42 undX Te=0.58 entstand. Die Standard-Enthalphie der Reaktion bei 298 K, ΔH° (298 K), war nach der Methode des dritten Gesetzes 136.0±0.3 kJ/mol. Die erwähnte feste Lösung verdampfte inkongruent unter Bildung von InTe(s) und einem Dampf, der aus Te2(g) und In2Te(g) bestand. InTe(s) verdampfte im Bereich von 701–887 K kongruent unter Bildung von Te2(g) und In2Te(g); ΔH v ° (298 K) nach dem dritten Gesetz war 201.5±1.0 kJ/mol. Diese Ergebnisse sind im Gegensatz zu Literaturangaben zur Verdampfung von In2Te3, wobei sowohl kongruente als auch inkongruente Verdampfung zu InTe(s) berichtet wurden. Außerdem wurde InTe(s) als inkongruent verdampfend beschrieben. Diese Abweichungen werden diskutiert.
    Notes: Abstract The vaporization chemistry of In2Te3(s) was studied by the computer-automated simultaneousKnudsen-effusion and torsion-effusion method, by high-temperature mass spectrometry, and by ancillary methods. The first absolute measurements of the vapor pressure of In2Te3 are reported. In2Te3(s) vaporized incongruently in the temperature range 701–889 K and produced Te2(g) and a solid-solution, (X In=0.42 andX Te=0.58). The standard enthalpy of the reaction at 298 K, ΔH° (298 K) by the third-law method was 136.0±0.3 kJ/mol of vapor. The above solid solution vaporized incongruently and produced InTe(s) and a vapor which consisted of Te2(g) and In2Te(g). InTe(s) vaporized congruently in the range 701–887 K and produced Te2(g) and In2Te(g); the third-law ΔH v ° (298 K) was 201.5±1.0 kJ/mol. These results were at variance with the literature on vaporization of In2Te3 where both congruent vaporization and incongruent vaporization to give InTe(s) are separately reported. Further, InTe(s) was reported to vaporize incongruently. These differences are discussed.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF00810061
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  • 3
    Electronic Resource
    Electronic Resource
    Variations in sintering kinetics and microstructure of alumina with chromium and molybdenum additions (1987)
    Springer
    Journal of materials science 22 (1987), S. 3161-3166 
    Details
    ISSN: 1573-4803
    Source: Springer Online Journal Archives 1860-2000
    Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics
    Notes: Abstract Chromium and molybdenum were introduced into alumina through gel synthesis. Both elements are soluble in aluminium hydroxide and low-temperature (〈1400°C) aluminium oxide. In the course of transformation from hydroxide to oxide, the evaporation-condensation of vapour phase (below 1000° C) causes shrinkage of the porous compact due to particle rearrangement and growth through capillary drag and adsorption. Subsequently, differences in agglomerate structure, grain growth, solute atmosphere and densification arise because of variations in the crystal lochemical behaviour of chromium and molybdenum. The solute atmospheres of chromia-vacancy and molybdenum metal reveal sub-grain boundaries and dislocations. In chromia-alumina solid solution these defects annihilate and contribute to densification (98%th) with increase in temperature to 1600° C. However, with further rise in temperature to 1700° C, the solid solution desinters to 85%th and creep cavities show transition from grain boundary to lattice creep. In Mo-Al2O3 composite the defects are locked by molybdenum solute, and as a result there is an insignificant increase in densification (30%th at 1600°C).
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01161177
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    Paper (German National Licenses)
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