The activation mechanism of lead ions in the flotation of ilmenite using sodium oleate as a collector

•Oleate predominantly interacts with iron on the ilmenite surface via chemisorption.•Ilmenite flotability can be enhanced due to the adsorption of Pb(OH)+/Pb2+ species.•Oleate adsorption behavior onto ilmenite surface is evaluated via adsorption test.•Ilmenite-oleate system is delineated through det...

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Published inMinerals engineering Vol. 111; pp. 100 - 107
Main Authors Chen, Pan, Zhai, Jihua, Sun, Wei, Hu, Yuehua, Yin, Zhigang
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.09.2017
Subjects
Flotation
Ilmenite
Lead activation
Surface modification
Surface modification
Flotation
Lead activation
Ilmenite
Online AccessGet full text
ISSN0892-6875
1872-9444
DOI10.1016/j.mineng.2017.06.009

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Abstract •Oleate predominantly interacts with iron on the ilmenite surface via chemisorption.•Ilmenite flotability can be enhanced due to the adsorption of Pb(OH)+/Pb2+ species.•Oleate adsorption behavior onto ilmenite surface is evaluated via adsorption test.•Ilmenite-oleate system is delineated through detailed solution chemistry analysis.•Lead ions can change the chemical environment and compositions of ilmenite surface. The flotation behaviors of ilmenite untreated or treated with lead ions using sodium oleate as a collector were studied. The results of micro-flotation experiments reveal that ilmenite shows good floatability at pH 6–8. Compared with the flotation recovery of ilmenite untreated with lead ions, ilmenite floatability can be enhanced, and the resulting increase in recovery can surpass 30% after the addition of lead ions. The results of zeta potential tests show that the isoelectric point of ilmenite can change from 5.2 (untreated) to 7.8 (treated), which is beneficial for the interaction between ilmenite and the collector and increases its floatability. Adsorption measurements show that the adsorption amounts of ilmenite treated with lead ions are higher than those of untreated ilmenite. XPS tests show that after activation with lead ions, the relative contents of iron and titanium on the ilmenite surface, which play leading roles in ilmenite flotation, increase by 5.9% and 4.6%, respectively. At the same time, changes in binding energy are more visible after ilmenite is pretreated with lead ions and subsequently treated with sodium oleate. Within the optimal flotation pH range, oleate species (RCOO−, (RCOO)22-, (RCOO)2H−) can mainly react with iron on the ilmenite surface through chemical adsorption in addition to electrostatic effects.
AbstractList •Oleate predominantly interacts with iron on the ilmenite surface via chemisorption.•Ilmenite flotability can be enhanced due to the adsorption of Pb(OH)+/Pb2+ species.•Oleate adsorption behavior onto ilmenite surface is evaluated via adsorption test.•Ilmenite-oleate system is delineated through detailed solution chemistry analysis.•Lead ions can change the chemical environment and compositions of ilmenite surface. The flotation behaviors of ilmenite untreated or treated with lead ions using sodium oleate as a collector were studied. The results of micro-flotation experiments reveal that ilmenite shows good floatability at pH 6–8. Compared with the flotation recovery of ilmenite untreated with lead ions, ilmenite floatability can be enhanced, and the resulting increase in recovery can surpass 30% after the addition of lead ions. The results of zeta potential tests show that the isoelectric point of ilmenite can change from 5.2 (untreated) to 7.8 (treated), which is beneficial for the interaction between ilmenite and the collector and increases its floatability. Adsorption measurements show that the adsorption amounts of ilmenite treated with lead ions are higher than those of untreated ilmenite. XPS tests show that after activation with lead ions, the relative contents of iron and titanium on the ilmenite surface, which play leading roles in ilmenite flotation, increase by 5.9% and 4.6%, respectively. At the same time, changes in binding energy are more visible after ilmenite is pretreated with lead ions and subsequently treated with sodium oleate. Within the optimal flotation pH range, oleate species (RCOO−, (RCOO)22-, (RCOO)2H−) can mainly react with iron on the ilmenite surface through chemical adsorption in addition to electrostatic effects.
Author Sun, Wei
Chen, Pan
Yin, Zhigang
Zhai, Jihua
Hu, Yuehua
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Keywords Surface modification
Flotation
Lead activation
Ilmenite
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Snippet •Oleate predominantly interacts with iron on the ilmenite surface via chemisorption.•Ilmenite flotability can be enhanced due to the adsorption of Pb(OH)+/Pb2+...
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SubjectTerms Flotation
Ilmenite
Lead activation
Surface modification
Title The activation mechanism of lead ions in the flotation of ilmenite using sodium oleate as a collector
URI https://dx.doi.org/10.1016/j.mineng.2017.06.009
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