RAPID DEHYDROXYLATION OF NICKELIFEROUS GOETHITE IN LATERITIC NICKEL ORE: X-RAY DIFFRACTION AND TEM INVESTIGATION

A method for extracting Ni and other metals from laterilic ores by means of shock heating has been investigated. Shock heating releases some of the metal from its goethitic host. Even though the transformation Of pure goethite to hematite is known to occur via intermediate hydroxylated phases, the effect of other metals such as Ni substituting for Fe in goethites oil this thermal transformation to hematite is unknown. The purpose Of this Study was to fill this gap, with the hope that the results Will lead to more energy-efficient extraction methods and/or a better understanding of Fe geochemistry in thermally activated soils. X-ray diffraction, transmission electron microscopy with EDS, and thermal analysis were used to investigate mineralogical changes in nickeliferous goethites from five oxide-type lateritic nickel ore deposits that had been subjected to shock heating at temperatures in the range 220-800 degrees C. Acicular, nano-sized goethite was the main constituent of the samples with minor to trace amounts of quartz, talc, kaolinite, chromite, maghemite, and Mn oxides. Goethite was partially dehydroxylated to OH-hematite at 340-400 degrees C and had completely altered to well ordered hematite at 800 degrees C. The OH-hematite was characterized by broad XRD peaks for reflections associated with the Fe sublattice. The goethite Unit-cell a and b lengths remained almost constant with increasing preheating temperature up to 300 degrees C, while the size of the c axis dimension contracted. The neoformed hematite crystals were larger than the precursor goethite crystals due to development, by sintering and surface diffusion, of regularly ordered hematite domains. The increase (1.5-2.6 fold) in surface area with increasing heating temperature (tip to 340-400 degrees C) reflected the development of slit-shaped micropores (similar to 300 degrees C), which further developed into elliptically shaped micropores (similar to 400 degrees C) in OH-hematite. With increased heating temperature, well ordered hematite formed with only a few micropores remaining. Such results may contribute to the development of more efficient procedures for extracting Ni from lateritic nickel ores, as the rate of dissolution of goethite in acid in 'heap and pressure' leach facilities will be enhanced by the increases in surface area and microporosity. The results may also provide valuable information oil the probable effects of natural heating oil pedogenic Fe oxides.