XPS study of sulfide minerals surface oxidation under high-voltage nanosecond pulses

XPS study of sulfide minerals surface oxidation under high-voltage nanosecond pulses

•The powerful toll (HPEMP) for the directed modification of the mineral surface properties is presented.•The application the HPEMP allows to regulate directionally the floatability of most important sulfides.•Due to the surface properties modification the floatability of studied sulfides improved dy...

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Bibliographic Details
Published in:Minerals engineering Vol. 143; p. 105939
Main Authors: Chanturiya, Valentine A., Bunin, I.Zh, Ryazantseva, Maria
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-11-2019
Subjects:
Energy spectroscopy for chemical analysis (ESCA)
Irradiation effects
Oxidation
Semiconductors
Surface properties
Surfaces
Surfaces
Surface properties
Irradiation effects
Oxidation
Energy spectroscopy for chemical analysis (ESCA)
Semiconductors
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Summary:•The powerful toll (HPEMP) for the directed modification of the mineral surface properties is presented.•The application the HPEMP allows to regulate directionally the floatability of most important sulfides.•Due to the surface properties modification the floatability of studied sulfides improved dy 12-15%.•The detailed study of the surface alterations under the impact of HPEMP.•The process of the surface transformation occurring by stages. Surface modification of natural metal sulfides (pyrite, arsenopyrite, chalcopyrite, sphalerite, galena, and molybdenite) treated by high-power electromagnetic pulses (HPEMPtreatment) has been studied by X-ray photoelectron spectroscopy as a function of HPEMP treatment duration. Two principal common steps and some differences in the surface evolution process were identified. The initial surface modification step was observed at low treatment doses (up to N ~ 103 pulses). Formation or accumulation in the surface layer of metal-deficient sulfide phase, oxides and hydroxides, elemental/polysulfide sulfur and/or metastable sulfur (thiosulfate, sulfite) was observed at this step. The second step (N ≥ 3·103 pulses) is characterized by thermal loss of elemental sulfur. Differences in the modification process, it was found that the chemical transformations of sulfur in the surface layer of pyrite, arsenopyrite, chalcopyrite include accumulation/formation of S0 (Sn2−) at the first transformation stage (up to N ~ 103 pulses) followed by its removal. In the case of sphalerite and galena, the surface sulfur transformation had a different pattern. It included formation/accumulation at the first stage of metastable sulfur species (thiosulfate, sulfite) converted at an increase treatment duration to the initial state (sulfide or disulfide).
ISSN:0892-6875
1872-9444
DOI:10.1016/j.mineng.2019.105939