Kinetic study of niobium and tantalum hexameric forms and their substituted ions by capillary electrophoresis in alkaline medium

Cock, Bart De; Delaunay, Nathalie; Deblonde, Gauthier J.‐P.; Bosi, Valentina; Pasti, Luisa; Mangelings, Debby; Heyden, Yvan Vander

doi:10.1016/j.talanta.2017.07.025

Cited by 7 publications

(4 citation statements)

References 28 publications

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“…Surprisingly, a total loss of selectivity is observed when using the industrial Nb-Ta solution and both elements are extracted with identical extraction yields (within the experimental uncertainty). We previously showed by UV-vis spectrophotometry that the speciation of Nb in industrial solutions mainly consists of hexaniobate ions [45,48] x-8 (1 ≤ y ≤ 5), after a several hours or upon heating [55][56][57]. Taking these observations into account, given the high ratio Nb/Ta in the studied industrial samples, and due to the process by which they have been produced [45,51] Figure 2).…”

Section: Resultsmentioning

confidence: 77%

A fluoride-free liquid-liquid extraction process for the recovery and separation of niobium and tantalum from alkaline leach solutions

Deblonde

Bengio²,

Beltrami³

et al. 2019

Separation and Purification Technology

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The production of high purity niobium (Nb) or tantalum (Ta) compounds still relies on processes that require highly acidic conditions and concentrated HF or NH 4 F solutions. Recent progress in the chemistry of group V elements, along with the evolution of the environmental concerns, call for the development of more sustainable industrial processes for these strategic elements. In sharp contrast with the historical fluoride approach chosen by the Nb and Ta refining industry, there has been a recent surge in the literature concerning the chemistry of these elements in diluted alkaline or oxalate media. We here propose an innovative liquid-liquid extraction process that is amenable to separate Nb and Ta from alkaline feed solutions, can be operated at low acidity and that does not require any fluoridebased chemical. The developed strategy is as follows: first, Nb and Ta are co-extracted from their alkaline solution (pH 12) using a quaternary ammonium salt (Aliquat® 336) dissolved in an organic diluent; then, Nb is selectively back-extracted in a mixture of diluted nitric and Page 2/31 oxalic acids; and finally, Ta is stripped in a diluted nitric media. The process also affords purifying Nb from Ti, Fe and Na. Following an optimization at laboratory scale, the full process has been validated during continuous running tests (160 h at 1.4 L.h-1) using industrial Nb-Ta caustic solutions coming from the development of the so-called Maboumine process. The developed process works at room temperature, low acidity ([H + ] < 1 M), exhibits high recovery yields, and allows producing Nb 2 O 5 •nH 2 O with purity higher than 99.5 %. The process also yields a tantalum product (Ta 2 O 5 •nH 2 O with >20 wt% Ta) even when starting from a diluted feed (39 ppm Ta). The proposed strategy paves the way for new Nb and Ta hydrometallurgical processes operating under mild chemical environments and represents a concrete alternative to the current fluoride-intensive industrial methods. Highlights A new process for separating Nb and Ta in fluoride-free media is proposed High-purity Nb oxide (99.5 %) can be produced Nb and Ta can be recovered and separated starting from an alkaline feed solution The process works at room temperature and under mild chemical conditions

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Section: Resultsmentioning

confidence: 77%

A fluoride-free liquid-liquid extraction process for the recovery and separation of niobium and tantalum from alkaline leach solutions

Deblonde

Bengio²,

Beltrami³

et al. 2019

Separation and Purification Technology

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“…Subsequently, the SEI method was transferred in De Cock et al. to a Beckman P/ACE CE system, due to the unavailability of the Agilent system, and in a next step adapted in order to obtain a quantitative, instead of the earlier informative, separation of not only Nb 6 and Ta 6 anions, but also all their substituted Nb 6‐x Ta x with 0 < x < 6 ions. This paper deals with the interinstrumental transfer of the new SEI method that was developed with a Beckman system to an Agilent G1600 instrument in the same laboratory.…”

Section: Resultsmentioning

confidence: 99%

“…In first investigations performed by Deblonde et al [10,11], the separation of the two Nb 6 and Ta 6 anions in a basic medium, using a 45 mM LiOH/LiCH 3 COOH BGE, an application of 10 kV, a temperature of 25.0°C, and an effective capillary length of 8.5 cm was achieved on an Agilent 7100 CE system. Subsequently, the SEI method was transferred in De Cock et al [12] to a Beckman P/ACE CE system, due to the unavailability of the Agilent system, and in a next step adapted in order to obtain a quantitative, instead of the earlier informative, separation of not only Nb 6 and Ta 6 anions, but also all their substituted Nb 6-x Ta x with 0 Ͻ x Ͻ 6 ions. This paper deals with the interinstrumental transfer of the new SEI method that was developed with a Beckman system to an Agilent G1600 instrument in the same laboratory.…”

Section: Preliminary Workmentioning

confidence: 99%

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Interinstrumental transfer of a fast short‐end injection capillary electrophoresis method: Application to the separation of niobium, tantalum, and their substituted ions

et al. 2017

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The interinstrumental transfer of a short-end CE method was studied. A model separation of the hexameric forms of niobium, tantalum, and their substituted ions (Nb Ta with 0 ≤ x ≤ 6) was selected as test case. The method was first optimized on a Beckman instrument and in a second step transferred to an Agilent instrument. The transfer needed updated guidelines that tackled differences in effective capillary length, 8.5 (Agilent) versus 10 cm (Beckman), because of instrumental different capillary cartridges. Differences in effective length lead to migration time and separation efficiency inequalities, illustrated by a decrease in resolution between the substituted ions. The difference in effective length was overcome by adapting the lift offset parameter of the Agilent instrument. The lift offset default setting is 4 mm and by increasing this parameter both the inlet and outlet lifts are lowered and thus the detection window can be displaced and consequently the effective length was increased. The decrease in effective length difference and the effect on the separation efficiency was investigated and led finally to a restored separation of the substituted ions. The adaptation of the lift offset parameter during short-end injection methods was added to earlier developed guidelines to facilitate interinstrumental method transfer of CE methods.

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Alloy Materials for Biomedical Applications

Nagay

Cordeiro

Barão

2020

Alloy Materials and Their Allied Applications

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Kinetic study of niobium and tantalum hexameric forms and their substituted ions by capillary electrophoresis in alkaline medium

Cited by 7 publications

References 28 publications

A fluoride-free liquid-liquid extraction process for the recovery and separation of niobium and tantalum from alkaline leach solutions

A fluoride-free liquid-liquid extraction process for the recovery and separation of niobium and tantalum from alkaline leach solutions

Interinstrumental transfer of a fast short‐end injection capillary electrophoresis method: Application to the separation of niobium, tantalum, and their substituted ions

Alloy Materials for Biomedical Applications

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