Interaction of calcium dioleate collector colloids with calcite and fluorite surfaces as revealed by AFM force measurements and molecular dynamics simulation

Spherical calcium dioleate particles (∼ 10 μm in diameter) were used as AFM (atomic force microscope) probes to measure interaction forces of the collector colloid with calcite and fluorite surfaces. The attractive AFM force between the calcium dioleate sphere and the fluorite surface is strong and...

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Bibliographic Details
Published inInternational journal of mineral processing Vol. 81; no. 3; pp. 166 - 177
Main Authors Fa, Keqing, Nguyen, Anh V., Miller, Jan D.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.12.2006
Subjects
Atomic force microscopy
Calcite
Calcium dioleate
Collector colloids
Flotation collectors
Flotation reagents
Fluoride
Froth flotation
Interfacial water structure
Molecular dynamics simulation
Oleate
Atomic force microscopy
Calcium dioleate
Fluoride
Interfacial water structure
Flotation reagents
Collector colloids
Flotation collectors
Oleate
Molecular dynamics simulation
Calcite
Froth flotation
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Summary:Spherical calcium dioleate particles (∼ 10 μm in diameter) were used as AFM (atomic force microscope) probes to measure interaction forces of the collector colloid with calcite and fluorite surfaces. The attractive AFM force between the calcium dioleate sphere and the fluorite surface is strong and has a longer range than the DLVO (Derjaguin–Landau–Verwey–Overbeek) prediction. The repulsive AFM force between the calcium dioleate sphere and the fluorite surface does not agree with the DLVO prediction. Consideration of non-DLVO forces, including the attractive hydrophobic force, was necessary to explain the experimental results. The non-DLVO interactions considered were justified by the different interfacial water structures at fluorite– and calcite–water interfaces as revealed by the numerical computation experiments using molecular dynamics simulation. The density of interfacial water at the fluorite surface is low and the fluorite surface is not strongly wetted by water molecules. In contrast to the water at the fluorite surface, water molecules at the calcite surface form tightly packed monolayer structures and the calcite surface is extensively hydrated by water molecules. The interfacial water structure agrees with the AFM force measurements and the flotation recovery data. The strong attraction between the calcium dioleate colloid and the fluorite surface, and the moderately wetted fluorite surface by water molecules explain the better flotation response of fluorite with the oleate collector colloid.
ISSN:0301-7516
1879-3525
DOI:10.1016/j.minpro.2006.08.006