"Primary" or "secondary" origin of wulfenite

Joseph, Phineas Eleasor, 1891-

January 1916

No description available.

Metallurgy.

Wulfenite.

A text book on the flotation process

Stander, H. J.

January 1916

No description available.

Flotation.

Metallurgy.

The effects of higher temperatures in the leaching of vanadium from certain Colorado Plateau ores

King, Edwin Brown, 1927-

January 1950

No description available.

Vanadium -- Metallurgy.

Oxidation of copper concentrates to water-soluble copper

Dorris, Michael Calvin, 1941-

January 1966

No description available.

Copper -- Metallurgy.

Experimental study in the rapid dissolution of gold in cyanide solution

Meaders, George Edward, 1902-

January 1935

No description available.

Gold -- Metallurgy.

Experimental work in the recovery of elemental sulphur by the Hall process

Michaelson, James Paul, 1913-

January 1937

No description available.

Sulfur -- Metallurgy.

A study of gold associations in a refractory ore

Roberts, Malcolm Lindsey, 1914-

January 1937

No description available.

Gold -- Metallurgy.

Recovery of gold from carbonaceous material

Evans, Fred Leroy, 1912-

January 1938

No description available.

Gold -- Metallurgy.

The dissolution of some vanadium minerals

Rex, Halder John, 1910-

January 1939

No description available.

Vanadium -- Metallurgy.

Effect of substitutional elements on dynamic strain aging in steel

Cunningham, Sandra, 1974-

January 1999

Distinct serrations had been observed on the stress-strain curves of various steels tested previously at high temperatures (950--1100°C) at McGill University. An explanation proposed for this behavior was that dynamic strain aging (DSA), caused by the presence of substitutional elements, was taking place. To investigate the possibility that the jerky flow was caused by an interaction between dislocations and substitutional elements, the conditions of temperature and strain rate under which serrated yielding had previously been observed were explored. In addition, some of the same material was utilized in the testing. / Much of the previous work on DSA in steel has focused on the effect of interstitials, namely, carbon and nitrogen, rather than that of substitutional elements. These studies have been conducted in the blue brittle region (i.e. 100--400°C), where the diffusivity of the interstitial elements is sufficiently rapid for them to keep up with the moving dislocations. However, for substitutional elements to obtain enough mobility to induce DSA, the temperature range must be significantly higher. / The effect of substitutional elements on DSA in steel was examined in torsion and, although numerous tests were formulated and carried out in an attempt to gather evidence for this phenomenon, no firm data for the occurrence of DSA were obtained. Further experiments and analysis will be required to gain a better understanding of the behavior of DSA at elevated temperatures, particularly for the case where dynamic recrystallization is taking place. A testing method might then be devised that could make the effect of DSA more evident.

Engineering, Metallurgy.