Название | Application of Nanotechnology in Mining Processes |
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Автор произведения | Группа авторов |
Жанр | Отраслевые издания |
Серия | |
Издательство | Отраслевые издания |
Год выпуска | 0 |
isbn | 9781119865346 |
Keywords: Acid rock drainage, dendrimers, magnetic iron oxides nanoparticle, potentially toxic elements, rare earth element
1.1 Introduction
The global human population has risen considerably since the industrial revolution and currently stands at above 7.7 billion worldwide, beyond the carrying capacity of the earth [1]. The rapid population growth is imposing tremendous challenges such as the easy spread of disease outbreaks, food scarcity, shortage of infrastructures, and insufficient communication networks, which require resources and technological advancement to ameliorate these predicaments. All resources required for this technological advancement come from mother earth and can be obtained only through two means; if they cannot be harvested (from farming), they should be mined. The mining industry plays a vital role in supplying these key resources but lacks the potential to obtain mineral resources without compromising environmental integrity [2]. Nevertheless, mining cannot be easily halted due to the growing need for mineral resources to support technological advancement required to artificially sustain the ever-increasing human population, which is beyond the earth’s carrying capacity. The mineral resources, including metals, are essential components in the advancement of several technologies, like the production of medications and vaccines, fertilizers for agricultural application to ensure food security, and the manufacture of building materials for construction of mega-infrastructures to improve road networks. They are also used as vital components to manufacture computers and cell phones for better communication networks. In addition, mining is a vital economic activity for many nations, bringing in much-needed foreign exchange earnings and employment [3]. Despite the benefits mentioned above, the legacy of mining activities includes major environmental pollution and heaps or piles of municipal solid waste (MSW) from mining [4]. For example, most valuable minerals like gold (Au), copper (Cu), sulfur (S), zinc (Zn), silver (Ag) or lead (Pb) occurs in sulfidic ore bodies (Table 1.1) with more than one type of mineralization [5]. Once these valuable metals have been extracted from their sulfidic ores, vast volumes of mine water and leftover mining solid wastes and tailings are generated, which contain most of the sulfide mineral, like pyrite. The exposure of the pyrite-containing waste to oxygen and water leads to an acid-generating material, producing acid mine drainage (AMD). The discharge of AMD is attributed to most of the contamination being transported from mining sites to the receiving environments, affecting environmental water quality [6–8] (Figure 1.1). Due to its well-known and publicized ecological impacts, many countries have adopted stringent regulations, such as Section 402 of the Clean Water Act of the Republic of South Africa, enabling mining operators to treat mine water discharging AMD [9–11].
On the one hand, treatment of AMD as required by environmental legislation has serious financial implications for the mining operators, but on the other hand, generation of AMD in former mining sites occurs long after active mining when the responsible mining companies no longer exist. Thus, treatment and remediation of AMD are an economic and financial burden to the mining company if the operation is still active, and to the community and their governments in closed or abandoned mines. Mine water discharging AMD is known to contain a consortium of dissolved elements, including precious metals and rare-earth elements (REE) [12]. Thus, AMD can be a valuable resource, especially of REE and precious metals that can generate more income and compensate for the treatment and remediation expenses of mine water and contaminated mining sites [13]. Furthermore, AMD can be regarded as an initial and natural process of hydrometallurgy of REE. However, extraction of REE from AMD is a big challenge due to the need for highly selective extraction methods, targeting only REE and leaving other metal ions dissolved in AMD to produce the required purity. Thus, recovery of REE from AMD is usually more expensive, resulting in AMD not being attractive as a source of REE. Nevertheless, using polymeric nanomaterials as hydrometallurgical extraction agents is promising to be a cost-effective and efficient method of extracting REE from AMD. One of the agent groups with high potential is Poly(amidoamine) (PAMAM) dendrimers. Consequently, this chapter discusses the application of PAMAM dendrimers as an extraction agent of REE, evaluating their performance potential and the development of methods in which they are applied.
Table 1.1 Different types of sulfide-bearing ore bodies, % content in ore body, uses, world deposit and origin [14, 15].
Sulfide ore bodies and formula | Minerals present in the ore body with % content | Application of the major elements in the ore body | Regions of major deposit of ore bodies in the world | Origin of occurrence |
Arsenopyrite (FeAsS) | Arsenopyrite is the major source of arsenic, with 46% Arsenic, 34.3% Iron, and 19.7% Sulfur in the ore body. It should be noted that the arsenic content is made up of minor gold deposits. | Used in the manufacture of herbicide, alloys, wood preservative, medicine, insecticide, and rat poison. | China, Morocco, Namibia, Russia, Belgium, Iran, and Japan | Hydrothermal veins, pegmatite, contact metamorphism, and metasomatism |
Bornite (Cu5FeS4) | Source of rich-grade copper metal. The ore body contains 63.3% Copper (Cu), 11.1% Iron (Fe), and 25.6% Sulfur (S) | Major applications are in electrical wires, cables, plumbing, currency, utensils, machinery, alloys, architecture, nutritional supplements, and agricultural fungicides | United States, England, Austria, Zimbabwe, Morocco, Dzhezkazgan, and Kazakhstan | In the zone of secondary supergene enrichment, source of rich copper metal |
Chalcopyrite (CuFeS2) | Chalcopyrite is the principal source of copper metal and accounts for approximately 70% of the copper deposits in the world. The ore body content is made up of 34.5% Copper (Cu), 30.5% Iron (Fe), and 35.0% Sulphur (S) | Major applications of copper metal are in electrical wires, cables, plumbing, currency, utensils, machinery, alloys, architecture, nutritional supplements, agricultural fungicides, and space exploration capsules | Chile, China, Peru, United States, DRC, Australia, Russia, Zambia, Canada, and Mexico | Large, massive, irregular veins, disseminated and porphyry deposit at granitic/dioritic intrusive and SEDEX type |
Cinnabar (HgS) | The ore body is a primary source of mercury. It contains 86.2% Mercury (Hg) and 13.8% Sulfur (S). | Used in the manufacturing of industrial chemicals and in electronics, thermometers, medicine, cosmetics, pigments, and fluorescent lamps. Environmentally sensitive due to health and safety regulations | China, Mexico, Kyrgyzstan, Peru, and Tajikistan | Vein-filling by recent volcanic activity and acid-alkaline hot spring |
Galena (PbS) | Galena is the primary source of lead metal and one of the sources of sulfur. It contains 86.6% Lead (Pb) and 13.4% Sulfur (S). | Used as a key ingredient for paint production, used in plumbing materials, bullets, automobile batteries, alloys, sheets, radiation shields, electrodes, ceramic glazes, stained glass, and cosmetics |
China,
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