At present, most tailings are dewatered by static settling in tailings dams. The environmental impact of these large settlings ponds is very dramatic, not to mention the space requirements and the potential risk of dam failure. This method of disposal also results in the loss of process water due to evaporation. This can be significant in areas where the supply of fresh water is limited.The high centrifugal force in a decanter centrifuge drastically increases dewatering efficiency, as centrifugal separation happens at up to 29,430 m/s² (3,000 × gravitational acceleration or g).Depending on the material, more than 90% of the process water can be recovered using centrifuge technology. It can be reused in the mineral processing operation and will increase the water efficiency of the whole mining community. This paper presents the results of actual projects in Brazil and Peru.
Thioethers are highly prevalent functional groups in organic compounds of natural and synthetic origin but remain remarkably underexplored as starting materials in desulfurative transformations. As such, new synthetic methods are highly desirable to unlock the potential of the compound class. In this vein, electrochemistry is an ideal tool to enable new reactivity and selectivity under mild conditions. Herein, we demonstrate the efficient use of aryl alkyl thioethers as alkyl radical precursors in electroreductive transformations, along with mechanistic details. The transformations proceed with complete selectivity for C(sp3)−S bond cleavage, orthogonal to that of established transition metal‐catalyzed two‐electron routes. We showcase a hydrodesulfurization protocol with broad functional group tolerance, the first example of desulfurative C(sp3)−C(sp3) bond formation in Giese‐type cross‐coupling and the first protocol for electrocarboxylation of synthetic relevance with thioethers as starting materials. Finally, the compound class is shown to outcompete their well‐established sulfone analogues as alkyl radical precursors, demonstrating their synthetic potential for future desulfurative transformations in a one‐electron manifold.
Thioethers are highly prevalent functional groups in organic compounds of natural and synthetic origin but remain remarkably underexplored as starting materials in desulfurative transformations. As such, new synthetic methods are highly desirable to unlock the potential of the compound class. In this vein, electrochemistry is an ideal tool to enable new reactivity and selectivity under mild conditions. Herein, we demonstrate the efficient use of aryl alkyl thioethers as alkyl radical precursors in electroreductive transformations, along with mechanistic details. The transformations proceed with complete selectivity for C(sp3)−S bond cleavage, orthogonal to that of established transition metal‐catalyzed two‐electron routes. We showcase a hydrodesulfurization protocol with broad functional group tolerance, the first example of desulfurative C(sp3)−C(sp3) bond formation in Giese‐type cross‐coupling and the first protocol for electrocarboxylation of synthetic relevance with thioethers as starting materials. Finally, the compound class is shown to outcompete their well‐established sulfone analogues as alkyl radical precursors, demonstrating their synthetic potential for future desulfurative transformations in a one‐electron manifold.
Herein, the use of aryl alkyl thioethers as precursors for C-centered alkyl radicals is demonstrated for desulfurative C-H and C-C bond formation under electroreductive conditions. The transformations occur with complete selectivity for C(sp3)-S bond cleavage, orthogonal to that of transition metal-catalyzed two-electron routes. Experimental and theoretical studies provide mechanistic insights that serve as a steppingstone for future use of thioethers as efficient radical precursors that can outcompete their established sulfone analogues.
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