The influence of temperature on rare earth flotation with naphthyl hydroxamic acid

The influence of temperature on the complex process of Bayan Obo rare earth (RE) ore flotation with a collector of naphthyl hydroxamic acid (LF8#) was investigated. Industrial test data shows that the grade and recovery of RE increase with the temperature. However, the proportion of bastnaesite in t...

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Bibliographic Details
Published inJournal of rare earths Vol. 36; no. 1; pp. 99 - 107
Main Authors Li, Mei, Gao, Kai, Zhang, Dongliang, Duan, Haijun, Ma, Linlin, Huang, Lan
Format Journal Article
LanguageEnglish
Published Elsevier B.V 2018
Subjects
Adsorption
Bastnaesite
Flotation
Hydroxamic acid
Monazite
Rare earths
Hydroxamic acid
Bastnaesite
Flotation
Adsorption
Rare earths
Monazite
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Summary:The influence of temperature on the complex process of Bayan Obo rare earth (RE) ore flotation with a collector of naphthyl hydroxamic acid (LF8#) was investigated. Industrial test data shows that the grade and recovery of RE increase with the temperature. However, the proportion of bastnaesite in the bulk concentrate increases as the RE grade improves. Adsorption mechanism of LF8# on the surfaces of bastnaesite and monazite were confirmed via zeta potential, UV]Vis Spectrophotometer (UV]Vis), Fourier transform infrared (FIR), and X-ray photoelectron spectroscopy analyses (XPS). Although the results indicate that the total amount of the LF8# adsorption on the surface of bastnaesite and monazite de- creases with increasing the temperature, the amount of stable adsorbed predominance of characteristic bonds (-C(~O)N-] from LF8# uptake on bastnaesite surfaces increases significantly at high tempera- tures. This conclusion indicates that the adsorption stability increases with increasing the temperature. For monazite, the amount of characteristic elements C and N in LF8# does not increase as the temper- ature increases on the mineral surface, but the proportion of characteristic bonds increases, which shows that the adsorption stability of LF8# on the surface of monazite also increases, but it is not as significant as bastnaesite, which may be one of the reasons that the floatability of bastnaesite is better than those of monazite. Pulp dispersion results show that the temperature improve the dispersions of both the gangue and RE minerals. This improved the flotation selectivity so that it favored RE minerals. The calculated bubble size distribution confirms that higher temperatures generate smaller bubbles, thereby increasing the bubble-particle collision probability and the recovery of RE minerals.
Bibliography:11-2788/TF
BastnaesiteMonaziteFlotationHydroxamic acidAdsorptionRare earths
The influence of temperature on the complex process of Bayan Obo rare earth (RE) ore flotation with a collector of naphthyl hydroxamic acid (LF8#) was investigated. Industrial test data shows that the grade and recovery of RE increase with the temperature. However, the proportion of bastnaesite in the bulk concentrate increases as the RE grade improves. Adsorption mechanism of LF8# on the surfaces of bastnaesite and monazite were confirmed via zeta potential, UV]Vis Spectrophotometer (UV]Vis), Fourier transform infrared (FIR), and X-ray photoelectron spectroscopy analyses (XPS). Although the results indicate that the total amount of the LF8# adsorption on the surface of bastnaesite and monazite de- creases with increasing the temperature, the amount of stable adsorbed predominance of characteristic bonds (-C(~O)N-] from LF8# uptake on bastnaesite surfaces increases significantly at high tempera- tures. This conclusion indicates that the adsorption stability increases with increasing the temperature. For monazite, the amount of characteristic elements C and N in LF8# does not increase as the temper- ature increases on the mineral surface, but the proportion of characteristic bonds increases, which shows that the adsorption stability of LF8# on the surface of monazite also increases, but it is not as significant as bastnaesite, which may be one of the reasons that the floatability of bastnaesite is better than those of monazite. Pulp dispersion results show that the temperature improve the dispersions of both the gangue and RE minerals. This improved the flotation selectivity so that it favored RE minerals. The calculated bubble size distribution confirms that higher temperatures generate smaller bubbles, thereby increasing the bubble-particle collision probability and the recovery of RE minerals.
Mei Li a, b, c, * Kai Gao a, b, Dongliang Zhang a, b Haijun Duan b, c, Linlin Ma b, c, Lan Huang b, c a (School of Materials Science and Engineering, Beijing University of Chemical Technology, Beijing 100029, China b Inner Mongolia Key Laboratory of Rare Earth Hydrometallurgy and Light Rare Earth Application, Inner Mongolia University of Science and Technology, Baotou 014010, China c School of Material and Metallurgy, Inner Mongolia University of Sdence and Technology, Baotou 014010, China)
ISSN:1002-0721
2509-4963
DOI:10.1016/j.jre.2017.07.004