学位论文详细信息
The Reduction and Dissolution of Manganese(III) and (IV) Oxides by Organics
Environmental engineering science, catechol;hydroquinone;Infrared spectroscopy;mineral synthesis;Redox Reactions;Surface reactions
Stone, Alan Thomas ; Morgan, James J.
University:California Institute of Technology
Department:Engineering and Applied Science
关键词: Environmental engineering science, catechol;    hydroquinone;    Infrared spectroscopy;    mineral synthesis;    Redox Reactions;    Surface reactions;   
Others  :  https://thesis.library.caltech.edu/3462/1/Stone_at_1983.pdf
美国|英语
来源: Caltech THESIS
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【 摘 要 】

Although it is known that manganese oxides are solubilized by reduction in anoxic waters, the chemical processes are poorly understood. A study of the reduction and dissolution of manganese oxide suspensions by twenty-seven organic substrates that have chemical structures similar to those of natural organics was undertaken to determine the rates and mechanisms of the solubilization reactions.

Dissolution of suspensions by hydroquinone in the pH range 6.5 < pH < 8.5 is described by the following experimental rate law:

(d[Mn2+])/dt = k1{H+}0.46[HQ]1.0(MnT - [Mn2+])

where [Mn2+] is the amount of dissolved manganese, [HQ] is the hydroquinone concentration, and MnT is the initial amount of manganese oxide. The apparent activation energy of the reaction was found to be +37 kJ/mole. The Mn(III,IV) oxide suspension was prepared by oxidizing a Mn(OH)2(s.) suspension with oxygen, and has a composition characterized by MnO1.66. Suspension particles were between 0.2 and 1.0 microns in diameter. Calcium and phosphate were found to inhibit the dissolution reaction, by adsorbing on the oxide surface.

Dihydroxybenzenes and methoxyphenols dissolved the suspensions at appreciable rates. Of the aliphatic substrates examined, only ascorbate, oxalate, and pyruvate dissolved the oxide. Dissolution by marine fulvic acid was found to be photocatalyzed.

A model was developed to explain the observed rate dependence and the relative reactivity of different organic substrates. The model assumes that complexes between substrate and surface sites form prior to electron transfer and dissolution. The pH dependence is not explained by this model; involvement of H+ in the dissolution of reduced surface sites may be responsible for the observed fractional order with respect to H+.

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