Your search keyword '"Corby G. Anderson"' showing total 9 results

1. Advances in Mineral Processing and Hydrometallurgy: 2nd Edition

Author

Corby G. Anderson and Hao Cui

Subjects

n/a, Mining engineering. Metallurgy, TN1-997

Abstract

After a very successful initial debut, this second edition of a Special Issue of Metals has been commissioned that is specifically devoted to aspects of mineral processing and hydrometallurgy [...]

Published

2024

2. Advances in Mineral Processing and Hydrometallurgy

Author

Corby G. Anderson and Hao Cui

Subjects

n/a, Mining engineering. Metallurgy, TN1-997

Abstract

A Special Issue of Metals was commissioned that was devoted to aspects of Mineral Processing and Hydrometallurgy [...]

Published

2021

3. A Review of the Cyanidation Treatment of Copper-Gold Ores and Concentrates

Author

Diego Medina and Corby G. Anderson

Subjects

gold cyanide leaching, sulfide minerals, SART process, cyanidation, activated carbon, metal–cyanide complex, Mining engineering. Metallurgy, TN1-997

Abstract

Globally, copper, silver, and gold orebody grades have been dropping, and the mineralogy surrounding them has become more diversified and complex. The cyanidation process for gold production has remained dominant for over 130 years because of its selectivity and feasibility in the mining industry. For this reason, the industry has been adjusting its methods for the extraction of gold, by utilizing more efficient processes and technologies. Often, gold may be found in conjunction with copper and silver in ores and concentrates. Hence, the application of cyanide to these types of ores can present some difficulty, as the diversity of minerals found within these ores can cause the application of cyanidation to become more complicated. This paper outlines the practices, processes, and reagents proposed for the effective treatment of these ores. The primary purpose of this review paper is to present the hydrometallurgical processes that currently exist in the mining industry for the treatment of silver, copper, and gold ores, as well as concentrate treatments. In addition, this paper aims to present the most important challenges that the industry currently faces, so that future processes that are both more efficient and feasible may be established.

Published

2020

4. Tannins in Mineral Processing and Extractive Metallurgy

Author

Jordan Rutledge and Corby G. Anderson

Subjects

quebracho, tannin, flotation, fluorite, germanium, precipitation, Tupasol, Mining engineering. Metallurgy, TN1-997

Abstract

This study provides an up to date review of tannins, specifically quebracho, in mineral processing and metallurgical processes. Quebracho is a highly useful reagent in many flotation applications, acting as both a depressant and a dispersant. Three different types of quebracho are mentioned in this study; quebracho “S” or Tupasol ATO, quebracho “O” or Tupafin ATO, and quebracho “A” or Silvafloc. It should be noted that literature often refers simply to “quebracho” without distinguishing a specific type. Quebracho is most commonly used in industry as a method to separate fluorite from calcite, which is traditionally quite challenging as both minerals share a common ion—calcium. Other applications for quebracho in flotation with calcite minerals as the main gangue source include barite and scheelite. In sulfide systems, quebracho is a key reagent in differential flotation of copper, lead, zinc circuits. The use of quebracho in the precipitation of germanium from zinc ores and for the recovery of ultrafine gold is also detailed in this work. This analysis explores the wide range of uses and methodology of quebracho in the extractive metallurgy field and expands on previous research by Iskra and Kitchener at Imperial College entitled, “Quebracho in Mineral Processing”.

Published

2015

5. Advances in Mineral Processing and Hydrometallurgy

Author

Hao Cui and Corby G. Anderson

Subjects

Engineering, n/a, Mining engineering. Metallurgy, Hydrometallurgy, business.industry, Metallurgy, Metals and Alloys, TN1-997, General Materials Science, business, Mineral processing

Abstract

A Special Issue of Metals was commissioned that was devoted to aspects of Mineral Processing and Hydrometallurgy [...]

Published

2021

6. Recovery of Rare Earth Oxides from Flotation Concentrates of Bastnaesite Ore by Ultra-Fine Centrifugal Concentration

Author

Alex Norgren and Corby G. Anderson

Subjects

Calcite, Gravity (chemistry), Materials science, Mining engineering. Metallurgy, UF falcon concentrator, bastnaesite, Rare earth, Metallurgy, Metals and Alloys, Oxide, TN1-997, rare earth elements, chemistry.chemical_compound, chemistry, Gangue, Carbonate, General Materials Science, Ultra fine, gravity concentration, Gravity separation

Abstract

Historically, the ability to effectively separate carbonate gangue from bastnaesite via flotation has frequently proven to be challenging without sacrificing significant rare earth oxide (REO) grade or recovery. However, in light of the fact that the rare earth bearing minerals often exhibit higher specific gravities than the carbonate gangue, the possibility exists that the use of gravity separation could be used to achieve such a selective separation. This however is complicated by the fact that, in cases such as this study when the liberation size is finer than 50 microns, most traditional gravity separation methods become increasingly challenging. The aim of this study is to determine the applicability of centrifugal concentrators to beneficiate ultra-fine (UF) bastnaesite and calcite bearing flotation concentrates. By using a UF Falcon, it was possible to achieve initial gravity REO recoveries exceeding 90% while rejecting on the order of 25% to 35% of the total calcium from an assortment of rougher and cleaner flotation concentrates. Additionally, when additional stages of cleaner UF Falcon gravity separation were operated in an open circuit configuration, it was possible, from an original fine feed of 35 microns containing 50.5% REO and 5.5% Ca, to upgrade up to approximately 59% REO and 2.0% calcium. While not the goal of this study, these results also support previous limited data to suggest that UF Falcons are potentially capable of treating a wider range of materials than they were originally designed for, including feeds rich in heavy mineral content.

Published

2021

7. Ultra-Fine Centrifugal Concentration of Bastnaesite Ore

Author

Corby G. Anderson and Alex Norgren

Subjects

Calcite, Gravity (chemistry), Mining engineering. Metallurgy, Materials science, bastnaesite, Rare earth, TN1-997, Metals and Alloys, Oxide, Mineralogy, rare earth elements, UF Falcon concentrator, chemistry.chemical_compound, chemistry, Gangue, Carbonate, General Materials Science, gravity concentration, Ultra fine, Gravity separation

Abstract

Historically, the ability to effectively separate carbonate gangue from bastnaesite via flotation has frequently proven to be challenging without sacrificing significant rare earth oxide (REO) grade or recovery. However, in light of the fact that the rare earth bearing minerals often exhibit higher specific gravities than the carbonate gangue, the possibility exists that the use of gravity separation could be used to achieve such a selective separation. This however is complicated by the fact that, in cases such as this study when the liberation size is finer than 50 µm, most traditional gravity separation methods become increasingly challenging. The purposes of this study is to determine the applicability of gravity concentrators to beneficiate bastnaesite from deleterious calcite bearing flotation feed material. Via the use of a UF Falcon, it was possible to achieve rougher gravity REO recoveries approaching the upper 80% range while rejecting on the order of 30% of the total calcium. In terms of purely REO recovery, this represents a significant improvement over results obtained via a traditional Falcon in previously reported studies.

Published

2021

8. Hydrometallurgical Leaching of Copper Flash Furnace Electrostatic Precipitator Dust for the Separation of Copper from Bismuth and Arsenic

Author

Corby G. Anderson, Shijie Wang, Michael Caplan, and Joseph Trouba

Subjects

lcsh:TN1-997, inorganic chemicals, Materials science, copper bearing dusts, 0211 other engineering and technologies, chemistry.chemical_element, 02 engineering and technology, digestive system, 030226 pharmacology & pharmacy, Bismuth, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Sulfurous acid, General Materials Science, lcsh:Mining engineering. Metallurgy, Arsenic, 021102 mining & metallurgy, copper processing, Metallurgy, Metals and Alloys, copper leaching, Sulfuric acid, bacterial infections and mycoses, equipment and supplies, Copper, digestive system diseases, chemistry, Sodium hydroxide, Leaching (metallurgy), Electrowinning

Abstract

Flash furnace electrostatic precipitator dust (FF-ESP dust) is a recycle stream in some primary copper production facilities. This dust contains high amounts of copper. In some cases, the FF-ESP dust contains elevated levels of bismuth and arsenic, both of which cause problems during the electrorefining stages of copper production. Because of this, methods for separation of copper from bismuth and arsenic in FF-ESP dust are necessary. Hydrometallurgical leaching using a number of lixiviants, including sulfuric acid, sulfurous acid, sodium hydroxide, and water, were explored. Pourbaix diagrams of copper, bismuth, and arsenic were used to determine sets of conditions which would thermodynamically separate copper from bismuth and arsenic. The data indicate that water provides the best overall separation between copper and both bismuth and arsenic. Sodium hydroxide provided a separation between copper and arsenic. Sulfurous acid provided a separation between copper and bismuth. Sulfuric acid did not provide any separations between copper and bismuth or copper and arsenic.

Published

2021

9. Hydrometallurgical Recovery of Rare Earth Elements from NdFeB Permanent Magnet Scrap: A Review

Author

Shuo Liu, Foquan Gu, Tao Jiang, Su Zijian, Yuanbo Zhang, and Corby G. Anderson

Subjects

lcsh:TN1-997, Secondary resource, Metallurgy, Rare earth, 0211 other engineering and technologies, Metals and Alloys, rare earth elements, Scrap, 02 engineering and technology, 021001 nanoscience & nanotechnology, hydrometallurgical, recovery, Neodymium magnet, Magnet, Environmental science, General Materials Science, NdFeB permanent magnet, Leaching (metallurgy), 0210 nano-technology, Solvent extraction, lcsh:Mining engineering. Metallurgy, Economic potential, 021102 mining & metallurgy

Abstract

NdFeB permanent magnet scrap is regarded as an important secondary resource which contains rare earth elements (REEs) such as Nd, Pr and Dy. Recovering these valuable REEs from the NdFeB permanent magnet scrap not only increases economic potential, but it also helps to reduce problems relating to disposal and the environment. Hydrometallurgical routes are considered to be the primary choice for recovering the REEs because of higher REEs recovery and its application to all types of magnet compositions. In this paper, the authors firstly reviewed the chemical and physical properties of NdFeB permanent magnet scrap, and then carried out an in-depth discussion on a variety of hydrometallurgical processes for recovering REEs from the NdFeB permanent magnet scrap. The methods mainly included selective leaching or complete leaching processes followed by precipitation, solvent extraction or ionic liquids extraction processes. Particular attention is devoted to the specific technical challenge that emerges in the hydrometallurgical recovery of REEs from NdFeB permanent magnet scrap and to the corresponding potential measures for improving REEs recovery by promoting the processing efficiency. This summarized review will be useful for researchers who are developing processes for recovering REEs from NdFeB permanent magnet scrap.

Published

2020