Abstract
Most hydrophobic clay minerals, such as clinochlore, are known to cause problems in the recovery of cassiterite. In this study, a new reagent scheme, i.e., sodium oleate (NaOL) as a collector and Al (III) ions as a depressant, for reverse flotation separation of cassiterite and clinochlore was investigated. The flotation performance and interaction mechanism were studied by microflotation tests, adsorption tests, contact angle measurements, and X-ray photoelectron spectroscopy (XPS) analysis. Results of single mineral flotation experiments showed that NaOL had a different flotation performance on cassiterite and clinochlore, and the addition of Al (III) ions could selectively inhibit the floatability of cassiterite. Reverse flotation tests performed on mixed minerals indicated that the separation of cassiterite and clinochlore could be achieved in the presence of NaOL and Al (III) ions. Adsorption experiments demonstrated that Al (III) ions hindered the adsorption of NaOL on cassiterite surfaces but exerted little influence on the adsorption of NaOL on clinochlore surfaces. Results of contact angle measurements indicated that Al (III) ions could impede the hydrophobization process of cassiterite in NaOL solution. XPS results showed that aluminum species were adsorbed onto the cassiterite surfaces through the interaction with O sites.
Highlights
Tin and its compounds can be applied in many industries, such as soldering, plating, alloy, chemistry, and metallurgy [1]
The global tin resources with industrial utilization value are mainly derived from cassiterite (SnO2 ), some of which contain a significant amount of slime due to overmining [2]
Previous studies [1,3] have indicated that clinochlore is one of the clay minerals encountered in complex tin oxide ores
Summary
Tin and its compounds can be applied in many industries, such as soldering, plating, alloy, chemistry, and metallurgy [1]. The global tin resources with industrial utilization value are mainly derived from cassiterite (SnO2 ), some of which contain a significant amount of slime (clay mineral) due to overmining [2]. Previous studies [1,3] have indicated that clinochlore is one of the clay minerals encountered in complex tin oxide ores. Cassiterite should be separated from the clay minerals to improve its purity [1,4,5]. With the depletion of cassiterite deposits and decrease of its grade, cassiterite necessitates fine grinding to liberate valuable minerals from low-grade refractory ores. The inherent brittle nature of cassiterite leads to the generation of ultra-fine particles
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