From Nickel Ore to Ni Nanoparticles in the Extraction Process: Properties and Application

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Uspekhi Fiziki Metallov-Progress in Physics of Metals Pub Date : 2023-03-01 DOI:10.15407/ufm.24.01.173

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Abstract

Laterite nickel ore is a mineral rock, which contains iron–nickel oxide compounds. One processing technology proposed to treat the ore is the Caron process. In general, the Caron process combines pyrometallurgical and hydrometallurgical stages. In the pyrometallurgical step, the ore mixed with reductant is heated up to 1800 °C in a rotary kiln-electric furnace to transform iron–nickel oxide into iron–nickel alloy. In the hydrometallurgical stage, nickel has to be dissolved selectively using ammonia solution (alkaline). The further process is aimed to separate and purify the nickel in ammonia solution using solvent extraction and precipitation. The disadvantages of the pyrometallurgical stage in the Caron process include high-energy consumption, low economic value, and technical problems such as partially melted material, which hinders the further process. While in the hydrometallurgical stage, the extensive use of ammonia causes an environmental impact. Selective reduction is proposed to solve problems in the pyrometallurgical stage. Selective reduction is a process favouring the formation of iron oxide to obtain high nickel content in an intermediate product with less energy consumption. An additive is added to the ore to reduce selectively the nickel and decrease the reaction temperature. To solve the environmental impact of ammonia, a novel and safer chemical is proposed as a substitute — the monosodium glutamate (MSG). Selective reduction combined with alkaline leaching using MSG is proposed as an alternative to the Caron method. Precipitation is employed further to purify the nickel that results in nickel nanoparticles with 90–95 wt.% purity.

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从镍矿石到镍纳米颗粒的萃取过程:性质及应用

红土镍矿是一种矿物岩石，含有铁镍氧化物化合物。提出的一种处理矿石的工艺是碳法。一般来说，Caron工艺结合了火法冶金和湿法冶金两个阶段。在火法冶炼步骤中，混合还原剂的矿石在回转窑电炉中加热到1800 ℃，使铁镍氧化物转化为铁镍合金。在湿法冶金阶段，镍必须选择性地用氨溶液(碱性)溶解。进一步的工艺是采用溶剂萃取和沉淀法分离纯化氨溶液中的镍。Caron工艺中火法冶金阶段的缺点是能耗高，经济价值低，并且存在材料部分熔化等技术问题，阻碍了进一步的工艺。而在湿法冶金阶段，氨的大量使用会对环境造成影响。提出了选择性还原法解决火法冶炼阶段存在的问题。选择性还原是一种有利于形成氧化铁的过程，在中间产物中以较少的能量消耗获得高镍含量。在矿石中加入添加剂，选择性地还原镍，降低反应温度。为了解决氨对环境的影响，人们提出了一种新的、更安全的化学品——味精(MSG)作为氨的替代品。提出了用味精选择性还原联合碱浸法替代Caron法。采用沉淀法进一步提纯镍，得到纯度为90-95 wt.%的纳米镍颗粒。

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来源期刊

Uspekhi Fiziki Metallov-Progress in Physics of Metals Multiple-

CiteScore

3.10

自引率

18.80%

发文量

审稿时长

13 weeks

期刊介绍： The review journal Uspehi Fiziki Metallov (abbreviated key-title: Usp. Fiz. Met.) was founded in 2000. In 2018, the journal officially obtained parallel title Progress in Physics of Metals (abbreviated title — Prog. Phys. Met.). The journal publishes articles (that has not been published nowhere earlier and are not being considered for publication elsewhere) comprising reviews of experimental and theoretical results in physics and technology of metals, alloys, compounds, and materials that possess metallic properties; reviews on monographs, information about conferences, seminars; data on the history of metal physics; advertising of new technologies, materials and devices. Scope of the Journal: Electronic Structure, Electrical, Magnetic and Optical Properties; Interactions of Radiation and Particles with Solids and Liquids; Structure and Properties of Amorphous Solids and Liquids; Defects and Dynamics of Crystal Structure; Mechanical, Thermal and Kinetic Properties; Phase Equilibria and Transformations; Interphase Boundaries, Metal Surfaces and Films; Structure and Properties of Nanoscale and Mesoscopic Materials; Treatment of Metallic Materials and Its Effects on Microstructure and Properties.