The production of rare earth elements group via tributyl phosphate extraction and precipitation stripping using oxalic acid

The present work describes the extraction of lanthanide (rare earth elements, REE) from low grade bauxite using acid leaching method. The aim of this study is to obtain the best condition for extraction of lanthanides from low grade bauxite. The effect of different parameters such as temperatures and concentration of oxalic acid in leaching process were investigated. The content of La, Ce and Y elements were determined using ICP-OES. The experimental result shows that the efficiencies of lanthanide leaching are the temperature-dependent. Increasing leaching temperature from 45°C to 85°C did not improve recoveries of lanthanides. The most optimum condition was found at oxalic acid leaching of 1 mol/L, leaching temperature at 40°C, and time for 2 hours. The obtained results show that the lanthanides can be leached using oxalic axid. This finding may lead to more effective and economical method to separate lanthanides from low grade bauxite.

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ChemInform Abstract: CRAIG DISTRIBUTION OF RARE EARTH ELEMENTS IN THE SYSTEM TRIBUTYL PHOSPHATE-NITRIC ACID SYSTEM. 10. PREPARATION OF YTTRIUM OXIDE IN THE PURE STATE

Chemischer Informationsdienst ◽

10.1002/chin.198243034 ◽

1982 ◽

Vol 13 (43) ◽

Author(s):

K. ROSSMANITH

Keyword(s):

Rare Earth ◽

Nitric Acid ◽

Rare Earth Elements ◽

Yttrium Oxide ◽

Pure State ◽

Tributyl Phosphate ◽

Acid System

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Solvent Extraction of Rare Earth Elements from a Nitric Acid Leach Solution of Apatite by Mixtures of Tributyl Phosphate and Di-(2-ethylhexyl) Phosphoric Acid

Metallurgical and Materials Transactions B ◽

10.1007/s11663-017-1086-6 ◽

2017 ◽

Vol 48 (6) ◽

pp. 3380-3387 ◽

Cited By ~ 6

Author(s):

Ali Ferdowsi ◽

Hossein Yoozbashizadeh

Keyword(s):

Rare Earth ◽

Nitric Acid ◽

Solvent Extraction ◽

Phosphoric Acid ◽

Rare Earth Elements ◽

Tributyl Phosphate ◽

Leach Solution ◽

Acid Leach

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Optimal Monazite Concentration Processes for the Extraction of Uranium and Thorium Fuel Material

Energies ◽

10.3390/en13184601 ◽

2020 ◽

Vol 13 (18) ◽

pp. 4601

Author(s):

Olga Fedorova ◽

Elizaveta Vershinina ◽

Svetlana Krasitskaya ◽

Ivan Tananaev ◽

Boris Myasoedov ◽

...

Keyword(s):

Rare Earth ◽

Nitric Acid ◽

Rare Earth Elements ◽

Tributyl Phosphate ◽

Solid Phase ◽

Optimal Conditions ◽

Acid Dissolution ◽

Fuel Material ◽

Monazite Concentrate

The optimal conditions for the nitric acid dissolution of precipitates of hydroxides and hydrated oxides of rare-earth elements, uranium, and thorium obtained after autoclave alkaline opening of samples of monazite concentrate have been determined. The distribution of radioactive impurities between the solid phase and the solution in the processes of alkaline opening, dephosphorization, and acid dissolution of the pulp was studied. Two options are proposed for the extraction of uranium and thorium in the presence of rare earth elements, followed by separation of the components using tributyl phosphate of various contents in the carbon diluent.

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Concentration and Separation of Heavy Rare-Earth Metals at Stripping Stage

Metals ◽

10.3390/met9121317 ◽

2019 ◽

Vol 9 (12) ◽

pp. 1317

Author(s):

Olga Cheremisina ◽

Vasiliy Sergeev ◽

Alexander Fedorov ◽

Daria Alferova

Keyword(s):

Rare Earth ◽

Oxalic Acid ◽

Organic Phase ◽

Tributyl Phosphate ◽

Rare Earth Metals ◽

Earth Metal ◽

Acid Solutions ◽

Extractant Concentration ◽

Heavy Rare Earth ◽

Separation Factors

The separation and concentration processes of heavy rare-earth metals—yttrium, ytterbium, erbium, and dysprosium—during stripping from the organic phase based on di-2-ethylhexylphosphoric acid (D2EHPA, or DEHPA) solutions were investigated in this work. Optimal conditions providing high separation factors of rare-earth metals (REM) and their extraction degree to the aqueous phase were determined. The usage of sulfuric acid solutions with a concentration of 2–6 mol/L, depending on the type of extracted rare-earth element, was proposed as a stripping agent for rare-earth metals (REM), and the usage of oxalic acid solution was proposed as an iron stripping solution from the organic phase. To increase the REM stripping efficiency, the antagonistic effect of tributyl phosphate in the di-2-ethylhexylphosphoric acid-kerosene-tributyl phosphate system was considered. The possibility of increasing the capacity of the organic solvent by cleaning the organic phase from iron ions using oxalic acid solutions was revealed. The influence of temperature, aqueous and organic phase ratio, stirring rate, and re-extractant concentration on the distribution and separation factors of adjacent heavy rare-earth-metal (HREM) pairs during the re-extraction process were determined. A schematic diagram of the laboratory-tested separation process of heavy rare-earth metals into individual components with the obtaining of yttrium and ytterbium concentrates containing more than 99% of the target components was proposed.

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From the Eclipse of Aldebaranium and Cassiopeium to the Priority Conflict Between Celtium and Hafnium

The Lost Elements ◽

10.1093/oso/9780199383344.003.0014 ◽

2014 ◽

Author(s):

Marco Fontani ◽

Mariagrazia Costa ◽

Mary Virginia Orna

Keyword(s):

Rare Earth ◽

Oxalic Acid ◽

Rare Earth Elements ◽

Ore Deposits ◽

Dilute Solutions ◽

Simple Body ◽

Intermediate Fraction ◽

The Town ◽

The Rare Earth

In 1794, Finnish scientist Johan Gadolin discovered the first of the rare earth elements in some ore deposits at Ytterby, Sweden. He called the oxide of the new element that he had isolated ytterbia and ytterbite the ore from which he had extracted it. Three years later, Anders Gustaf Ekeberg verified Gadolin’s discoveries and proposed the name of yttria (or yttric earths) for the oxide and gadolinite for the ore. For many years, chemists, among them L. N. Vauquelin, J. J. Berzelius, and M. H. Klaproth, wrestled with the problem that perhaps Gadolin’s yttrium was not a simple body but in reality contained other elements. In 1842, the Swedish chemist C. G. Mosander described how, by means of the fractional precipitations of the oxalates from dilute solutions of oxalic acid and by treatment of the hydroxides with dilute ammoniacal solutions, he seemed to have succeeded in extracting three new elements. The first was yttrium, the most basic; the second was erbium, the least basic; and the intermediate fraction he called terbium. The names terbium, erbium, and ytterbium derive from the name of the town, Ytterby. The names that Mosander gave to the three elements derived from the sequence in which they were separated: the name yttrium was not changed out of respect for Gadolin. The first element that he extracted, Mosander called terbium, and the following one he called erbium. He removed a letter from the word terbium because he had isolated it later. In the following years, it was discovered that both erbium and terbium were not single elements but mixtures of elements yet unknown. A practice developed that we might call an entente cordiale: when a discoverer split a presumed element into its constituents, one element retained the name already given by its preceding discoverer. This usage was respected by everyone, including Urbain, who, in 1907, presented his discoveries with the names neo-ytterbium and lutecium. Only Auer von Welsbach, a renowned Austrian chemist, did not respect this tacit “gentlemen’s agreement” and called the elements with atomic numbers 70 and 71 aldebaranium and cassiopeium.

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