一种从独居石精矿中提取稀土元素的新方法

Q2 Materials Science

Minerals & Metallurgical Processing Pub Date : 2017-08-01 DOI:10.19150/MMP.7618

J. Galvin, M. Safarzadeh

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引用次数: 0

摘要

背景稀土元素在现代世界的许多技术进步中发挥着重要作用。随着氢汽车、计算机硬盘驱动器和风力涡轮机等应用的发展，稀土元素在许多高技术应用中都是必需的，而且未来还会有更多的需求。独居石和巴斯坦矿是稀土元素最重要的两个来源。巴斯坦矿是一种氟碳酸盐矿物，但独居石是一种磷酸盐矿物，使其更难分解。其稳定的结构只有在极端的提取条件下才能被破坏。实现这一点的常用方法是在高温下使用氢氧化钠并延长烘焙时间。然而，用氢氧化钾代替氢氧化钠可能是一种经济上更有利的方法。目前实践中的氢氧化钠法生产的磷酸钠可以作为肥料出售（Panda等人，2014）。然而，氢氧化钾法会产生磷酸钾，这将是一种更有效、更有价值的肥料（Val’kov等人，2010）。

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A novel approach to alkali pug bake for the extraction of rare earth elements from monazite concentrate

Background Rare earth elements (REEs) play an important role in many technological advances in the modern world. With applications including hydrogen cars, computer hard drives and wind turbines, REEs are needed in numerous highly technical applications and will be needed more in the future. Monazite and bastnäsite are the two most essential sources of REEs. Bastnäsite is a fluorocarbonate mineral, but monazite is a phosphate mineral, making it much more difficult to decompose. Its stable structure can only be broken down under extreme extraction conditions. A common method to accomplish this has been through the use of sodium hydroxide at high temperatures and extended baking times. However, substituting potassium hydroxide for sodium hydroxide could potentially be a more economically favorable method. The sodium hydroxide method currently in practice produces sodium phosphate that can be sold as a fertilizer (Panda et al., 2014). However, the potassium hydroxide method would produce potassium phosphate, which would be a more effective and valuable fertilizer (Val’kov, et al., 2010).

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来源期刊

Minerals & Metallurgical Processing 工程技术-矿业与矿物加工

CiteScore

0.84

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： For over twenty-five years, M&MP has been your source for the newest thinking in the processing of minerals and metals. We cover the latest developments in a wide range of applicable disciplines, from metallurgy to computer science to environmental engineering. Our authors, experts from industry, academia and the government, present state-of-the-art research from around the globe.