Oxidations of aromatic ketoximes.

Frojmovic, Maurice Mony.

January 1967

No description available.

Ketoximes.

Oxidation

Oxidation of magnetite.

Jue, Bruce Cameron.

January 1967

No description available.

Magnetite

Oxidation

Synthesis and Oxidative Reactivity of Organopolysulphides

Derbesy, Gérard

January 1994

Note:

Polysulfides

Oxidation

Investigation of the oxidations effected by thionyl chloride /

Higa, Tatsuo

January 1971

No description available.

Chemistry

Oxidation

Oxidation of ethanol and phenols with permanganate for chemiluminescence analysis

Al-Mutawah, Jameela Isa

05 August 1994

Graduation date: 1995

Chemiluminescence

Alcohol -- Oxidation

Phenols -- Oxidation

OXIDIZING PROPERTIES OF SELENIUM COMPOUNDS

White, Joe Wade, 1940-

January 1967

No description available.

Selenium compounds -- Oxidation.

Selenium -- Oxidation.

Autoxidation of lacunar iron(II) dioxygen carriers /

Dickerson, Lyndel Dwayne

January 1985

No description available.

Chemistry

Oxidation

Oxidation

Oxygen

Iron

The Liquid Phase Oxidation of 1,3-Pentadiene

Reaves, Carl B.

01 January 1977

The liquid phase autoxidation of 1,3-pentadiene to 2,4-pentadienoic acid utilizing gaseous oxygen at atmospheric pressure was investigated as a possible route for direct utilization of piperylene obtained during the cracking of naptha to ethylene. Catalyst system consisting of cobalt, manganese, and iron salts promoted by sodium, potassium and hydrogen bromides, were used under a variety of condition of catalyst concentration, temperature, oxygen flow and piperylene purity. Under all conditions studied, a large number of oxidation products were formed. Maximum yields of 2,4-pentadienoic acid were obtained using a cobalt acetate bromide catalyst at 85°C.

Oxidation

Oxidation reduction reaction

Chemistry

Oxidation chemistry of cis-dioxoosmium (VI) and Ruthenium-Oxo complexes bearing a C2 symmetry chelating ligand

余永耀, Yu, Wing-yiu.

January 1993

published_or_final_version / Chemistry / Doctoral / Doctor of Philosophy

Osmium compounds - Oxidation.

Ruthenium compounds - Oxidation.

Ligands.

Alkenes - Oxidation.

SURFACE CHARACTERIZATION OF TITANIUM AND TITANIUM DEUTERIDE GAS-PHASE AND SOLUTION-PHASE OXIDATION PROCESSES (SURFACE ANALYSIS, ANGER ELECTRON SPECTROSCOPY).

Burrell, Michael Craig

January 1984

The reactions of atomically clean, titanium film surfaces with oxygen, deuterium, and water have been investigated. Auger Electron Spectroscopy was utilized to monitor the formation 9f a surface oxide in the case of oxygen exposure, and to characterize the deuteride which formed upon deuterium absorption, and its subsequent oxidation. Quantification of surface oxide stoichiometries was facilitated by novel data acquisition and treatment schemes. The quartz crystal microbalance was used to measure the mass of adsorbed oxygen or deuterium with submonolayer sensitivity. Electron energy loss spectroscopy was sensitive to the presence of Ti⁺³ in the surface oxide. The initial oxidation of the titanium surface was characterized by the dissociative adsorption of three mono1ayers of oxygen atoms at a constant rate. The oxide formed during this reaction stage was a Ti₂0₃/Ti0₂ mixture with a total thickness of 13 A. The rate of oxygen adsorption then decreased such that oxide growth was logarithmic with time. When the oxide had attained a total thickness of 20 A, the initial suboxide was converted to Ti0₂, and subsequent oxide formed was purely Ti0₂. Oxide growth occurred by oxygen anion migration under the influence of an electrostatic field, set up across the oxide layer by electron transfer from the metal to adsorbed oxygen species. The pressure dependence of the oxide growth rate and terminal thickness suggested a constant field growth mechanism. Clean titanium films reacted with deuterium to form a bulk deuteride TiDₓ (x<2). The oxide layer which resulted from oxygen exposure was characterized by the above techniques. Oxide layers greater than 20 A completely inhibited deuterium absorption by prohibiting 02 dissociation, but did not act as a diffusional barrier when additional dissociation sites were provided. Iron adlayers were found to accelerate the D₂ absorption reaction. Removal of the titanium films from the vacuum chamber to an isolable electrochemical reaction chamber, without exposure to the atmosphere, allowed a determination of the effect of the various gas/solid reactions on the subsequent electrochemical oxidation processes.

Titanium.

Oxidation.

Oxide coating.

Electrolytic oxidation.

Metals -- Anodic oxidation.