Extraction of Rare Earth Elements from Phospho-Gypsum: Concentrate Digestion, Leaching, and Purification

Rare earth-bearing gypsum tailings from the fertilizer industry are a potential source for an economically viable and sustainable production of rare earth elements. Large quantities are generated inter alia in Catalão, Brazil, as a by-product in a fertilizer production plant. Hitherto, the gypsum has been used as soil conditioner in agriculture or was dumped. The cooperative project, “Catalão Monazite: Economical exploitation of rare earth elements from monazite-bearing secondary raw materials,” intends to extract rare earth elements from these gypsum tailings. In this paper, a chemical process route to obtain a mixed rare earth carbonate from a monazite concentrate, was investigated. The results of the digestion, leaching, and precipitation experiments are presented and discussed herein. This includes reagent choice, process parameter optimization through experimental design, mineralogical characterization of the feed material and residues, purification of the leach solution, and precipitation of the rare earth as carbonates. The results showed that a rare earth extraction of about 90% without the mobilization of key impurities is possible during a sulfuric acid digestion with two heating stages and subsequent leaching with water. In the following purification step, the remaining impurities were precipitated with ammonium solution and the rare earth elements were successfully recovered as carbonates with a mixture of ammonium solution and ammonium bicarbonate.

Download Full-text

The Market For The "Not-So-Rare" Rare Earth Elements

Journal of International Energy Policy (JIEP) ◽

10.19030/jiep.v1i1.7013 ◽

2012 ◽

Vol 1 (1) ◽

pp. 11-18 ◽

Cited By ~ 5

Author(s):

Joseph A. Giacalone

Keyword(s):

Rare Earth ◽

Rare Earth Elements ◽

Raw Materials ◽

Rare Earth Metals ◽

High Technology ◽

Consumer Products ◽

Separation Processes ◽

Technology Products ◽

Development Costs ◽

The Rare Earth

This paper examines the market for the Rare earth elements. These are comprised of 17 elements of the periodic table which include 15 elements from the group known as lanthanides and two additional elements known as scandium and yttrium. The metals are often found combined together in ores and must be separated into its individual elements. The fact is that rare earth metals are not rare in terms of the quantity present in the earths crust. However, the metals are less concentrated than other more common metals and the extraction and separation processes necessitate high research and development costs and large capital outlays.The various applications of rare earth elements can be broadly classified into four major categories, namely: High Technology Consumer Products, Environmentally Friendly Products, Industrial and Medical Devices, and National Defense Systems. The demand for such high technology products is rapidly increasing causing a simultaneous upsurge in the demand for rare earth metals as well.On the supply side, China dominates the production rare earth elements, mining approximately 97% of total world production. Consequently, most countries must rely on imports of these REEs to facilitate production of the various systems and products that are dependent on the rare earth metals as raw materials. This near-monopoly imposes several supply-chain risks on the importing nations which are exploring ways to mitigate the potential economic harm associated with these risks.

Download Full-text

Complex processing of titanium-rare metal raw material

E3S Web of Conferences ◽

10.1051/e3sconf/20185603019 ◽

2018 ◽

Vol 56 ◽

pp. 03019

Author(s):

Mikhail Medkov ◽

Galina Krysenko ◽

Dantiy Epov ◽

Pavel Sitnik ◽

Valentin Avramenko

Keyword(s):

Rare Earth ◽

Rare Earth Elements ◽

Raw Materials ◽

Rare Metal ◽

Raw Material ◽

Insoluble Residue ◽

Ammonium Hydrodifluoride ◽

Fluoroammonium Salts ◽

Main Components ◽

The Rare Earth

The paper is devoted to investigation of the complex processing of titanium-rare metal raw materials with ammonium hydrodifluoride. It is stated that fluorination of the main components of the mineral raw materials with ammonium hydrodifluoride proceeds with formation of complex ammonium fluorometallates and simple fluorides. It is showed that in the process of aqueous leaching of the fluorinated mineral raw material niobium and tantalum completely pass into solution together with titanium, iron, and silicon fluoroammonium salts while all the rare-earth elements stay in the insoluble residue as complex fluorosodium salts together with CaF2. The method of separation of the fluoroammonium salts with obtaining marketable products and isolation of the rare-earth elements from the insoluble residue is offered.

Download Full-text