Molecular Engineering and Controlled Nano-assembly for Complex Sulfide Flotation in High Salinity Water

高盐度水中复杂硫化物浮选的分子工程和受控纳米组装

• 批准号: RGPIN-2015-05422
• 负责人: Liu, Qingxia
• 金额: $ 2.55万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=685633
• 关键词: Molecular; Engineering; Controlled; Nano; assembly

The depletion of high-grade mineral ore resources has driven Canada's mining and mineral processing industry to explore new technologies to process lower grade ores. The effective recovery of valuable minerals from low-grade ore requires intensive fine grinding for mineral liberation and a new technology for fine particle flotation. With increasingly stringent environment regulations for zero discharge, recycled water is used for mineral processing and oil sands extraction. As a result, salinity or total dissolved solids (TDS) in the recycled water has increased significantly. These elevated ionic concentrations, as well as the precipitation of metal hydroxides at high pH, retard the collector's reaction with mineral surfaces and lower the selectivity. These problems limit the effectiveness of recycled high-salinity water or seawater in mineral processing. ******This discovery program is aimed at developing a breakthrough technology for fine particle flotation in high salinity and seawater. Our approach is to achieve fundamental understanding of the underlying science of the critical physiochemical properties of fine mineral particles and air bubbles in high salinity and seawater. Through controlled nano-assembly, a topography of collector molecules on the surface of fine mineral particles will be designed for selective flotation in high salinity and seawater. The effects of solution chemistry on collector adsorption, air bubble coalescence, and water structure at the air-water interface will be studied in high salinity water. We will elucidate the relationship of molecular structure and topography on mineral surfaces to flotation recovery and selectivity. The interaction forces between bubbles and mineral surfaces in high salinity water will be studied by atomic force microscopy (AFM). This fundamental knowledge lays the foundation for further development of revolutionary fine particle flotation technologies so that our limited mineral resources can be used responsibly with minimum environmental footprint. Scientifically, we anticipate breakthroughs in understanding the nature of molecular nano-assembly structure and interaction forces.

高品位矿石资源的枯竭促使加拿大采矿和选矿行业探索加工低品位矿石的新技术。从低品位矿石中有效回收有价值的矿物需要进行精磨以释放矿物，并需要采用细颗粒浮选新技术。随着零排放环境法规日益严格，再生水被用于选矿和油砂开采。结果，循环水中的盐度或总溶解固体（TDS）显着增加。这些升高的离子浓度以及高pH值下金属氢氧化物的沉淀会延迟捕收剂与矿物表面的反应并降低选择性。这些问题限制了矿物加工中回收高盐水或海水的有效性。 ******该发现计划旨在开发高盐度海水中细颗粒浮选的突破性技术。我们的方法是对高盐度和海水中细矿物颗粒和气泡的关键理化性质的基础科学有基本的了解。通过受控的纳米组装，细矿物颗粒表面的捕收剂分子的形貌将被设计用于在高盐度和海水中选择性浮选。将在高盐度水中研究溶液化学对捕收剂吸附、气泡聚结和空气-水界面处的水结构的影响。我们将阐明矿物表面的分子结构和形貌与浮选回收率和选择性的关系。将通过原子力显微镜（AFM）研究高盐度水中气泡和矿物表面之间的相互作用力。这些基础知识为进一步开发革命性的细颗粒浮选技术奠定了基础，以便我们能够以最小的环境足迹负责任地使用有限的矿产资源。从科学角度来看，我们预计在理解分子纳米组装结构和相互作用力的本质方面将取得突破。