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Synthèse à basse et à très haute pression et caractérisation structurale de quelques oxydes mixtes de fer et de vanadium.Muller, Jean, Unknown Date (has links)
Th.--Sci. phys.--Grenoble 1, 1977. N°: 52.
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Chemistry and characterization of vanadyl phosphate catalystsNguyen, Phong T. 21 June 1995 (has links)
Graduation date: 1996
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The effects of higher temperatures in the leaching of vanadium from certain Colorado Plateau oresKing, Edwin Brown, 1927- January 1950 (has links)
No description available.
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The dissolution of some vanadium mineralsRex, Halder John, 1910- January 1939 (has links)
No description available.
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A study of heterogeneous equilibria in aqueous solutions of the sulfates of tetravalent vanadium at 30⁰ C.,Rohrer, Charles Stephens, January 1942 (has links)
Thesis (Ph. D.)--Columbia University, 1942. / Reproduced from type-written copy. Vita. eContent provider-neutral record in process. Description based on print version record. "Literature references": p. [16].
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A study of heterogeneous equilibria in aqueous solutions of the sulfates of tetravalent vanadium at 30⁰ C.,Rohrer, Charles Stephens, January 1942 (has links)
Thesis (Ph. D.)--Columbia University, 1942. / Reproduced from type-written copy. Vita. Description based on print version record. "Literature references": p. [16].
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The effect of nickel and nitrogen on void formation in vanadiumLott, Randy George. January 1979 (has links)
Thesis--University of Wisconsin--Madison. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 176-182).
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The fluorides of vanadiumCavell, Ronald George January 1962 (has links)
The density, surface tension and viscosity of liquid vanadium pentafluoride have been measured. The high value of the viscosity indicates that the liquid is probably associated in a somewhat similar manner to antimony pentafluoride, thus supporting recent evidence which has suggested that inter-molecular association is also an important process in these associated fluorides
The infrared spectrum of vanadium pentafluoride vapor has been measured in the region 250 to 3500 cm- ¹ and the results have been interpreted in terms of a monomeric trigonal bipyramid molecular structure in view of the normal vapor density
Vanadium pentafluoride formed a 1:1 complex with selenium tetrafluoride The apparently similar sulphur tetrafluoride complex was extremely unstable
Vanadium tetrafluoride is best prepared by fluorinatmg vanadium tetrachloride with anhydrous hydrogen fluoride in trichlorofluoromethane solution Vanadium tetrafluoride disproportionates readily at 100° in vacuum into the trifluoride and the pentafluoride Solid vanadium tetrafluoride also sublimes slowly at 100-120° in vacuum
The available structural information suggests that in vanadium tetrafluoride the vanadium atom is surrounded by six fluorine atoms to form an octahedral VF₆ unit Four fluorines are shared with adjacent vanadium atoms thus forming a polymeric fluorine -bridge-bonded structure The infrared spectrum of solid VF₄ has been interpreted in terms of this model
Bromine trifluoride and gaseous fluorine readily fluorinated vanadium tetrafluoride to the penta-fluoride In the presence of iodine pentafluoride, nitryl fluoride oxidised vanadium tetrafluoride and formed the nitryl salt NO₂VF₆. Ammonia, pyridine and selenium tetrafluoride formed 1.1 complexes with VF₄ Vanadium tetrafluoride did not react with sulphur tetrafluoride, sulphur trioxide or sulphur dioxide
Potassium hexafluorovanadate (IV) was prepared frpm potassium fluoride and vanadium tetrafluoride in selenium tetrafluoride solution. The trigonal form was obtained with lattice constants of a = 5 68, c = 4 66 A. Alkaline earth fluorides did not form hexafluorovanadate salts with vanadium tetrafluoride in iodine pentafluoride KVF₅ could not be prepared from equimolar proportions of potassium fluoride and vanadium tetrafluoride in iodine pentafluoride solution
All of the tetravalent vanadium fluoride compounds which have been studied obeyed the Curie-Weiss law, with very high values of the Weiss Constant Separation of antiferromagnetism and spm-orbit interaction is not possible as both effects are likely to arise from the proposed fluorine bridging
The heat of hydrolysis of vanadium tetrafluoride in water has been found to be -27 5 kcal /mole, and this value was used in a Hess law calculation to obtain -332 kcal /mole for the heat of formation of vanadium tetrafluoride Vanadium pentafluoride was hydrolysed under similar conditions in a dilute alkali solution and the resultant heat of hydrolysis, -141 kcal /mole, was used to calculate the heat of formation of - 352 kcal /mole for vanadium pentafluoride.
Lattice energies were estimated from a simple formula given by Kapustmskii and used in a Born-Haber cycle to calculate heats of formation Using the calculated heat of formation of vanadium trifluoride and the experimental values for vanadium tetrafluoride and vanadium pentafluoride, the spontaneity of the disproportionation of vanadium tetrafluoride was confirmed.
The heat of hydrolysis of vanadium tetrachloride in water is -68 8 kcal /mole With this value, the heat of formation of the aqueous vanadyl ion was calculated as -113 kcal /mole / Science, Faculty of / Chemistry, Department of / Graduate
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The simultaneous determination of vanadium and molybdenumStuart, Frank Albert January 1940 (has links)
[No abstract submitted] / Science, Faculty of / Chemistry, Department of / Graduate
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The electrical resistance of niobium and vanadium single crystals at low temperaturesClayton, John Frederick January 1963 (has links)
An investigation into the variation of electrical resistance with temperature for high purity niobium and vanadium single crystals has been carried out.
Niobium was studied over the temperature range -30°C to -146°C. It was found that in its highest purity there was little or no anomaly. At lower purities an anomaly in the region of -120°C was discovered which was attributed to oxygen or nitrogen or both changing their position on the lattice to one of higher strain energy because of changes in energy associated with the bonding between interstitials and the lattice.
Hydrogen doping of niobium produced an overall increase in resistivity. A drop in the resistance curve was noted at -100°C which was thought to be due to hydrogen, being mobile and non-bonded, moving off the high strain energy sites under the influence of thermal contraction. Hydrogen embrittlement was attributed to hydrogen occupation of high strain energy-sites.
Vanadium was found to have a slope change at.-170° when tested between -130°C and -196°C. No definite explanation of this is suggested.
Ultrasonic testing of vanadium showed attenuation minima at -100°C and -170°C. / Applied Science, Faculty of / Materials Engineering, Department of / Graduate
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