Editing Chalcopyrite (section)

=== Pyrometallurgical processes ===
The most important method for copper extraction from chalcopyrite is pyrometallurgy. Pyrometallurgy is commonly used for large scale, copper rich operations with high-grade ores.<ref>{{Citation |last=Nassaralla |first=C. L. |title=Pyrometallurgy |date=2001-01-01 |url=https://www.sciencedirect.com/science/article/pii/B0080431526014297 |encyclopedia=Encyclopedia of Materials: Science and Technology |pages=7938–7941 |editor-last=Buschow |editor-first=K. H. Jürgen |access-date=2023-03-23 |place=Oxford |publisher=Elsevier |language=en |doi=10.1016/b0-08-043152-6/01429-7 |bibcode=2001emst.book.7938N |isbn=978-0-08-043152-9 |editor2-last=Cahn |editor2-first=Robert W. |editor3-last=Flemings |editor3-first=Merton C. |editor4-last=Ilschner |editor4-first=Bernhard}}</ref> This is because Cu-Fe-S ores, such as chalcopyrite, are difficult to dissolve in aqueous solutions.<ref name="Schlesinger-2011">{{Cite book |url=https://www.worldcat.org/oclc/742299078 |title=Extractive Metallurgy of Copper |date=2011 |publisher=Elsevier |first1=Mark E. |last1=Schlesinger |isbn=978-0-08-096789-9 |location=Amsterdam |pages=281–317 |oclc=742299078}}</ref> The extraction process using this method undergoes four stages:

# Isolating desired elements from ore using '''froth flotation''' to create a concentration
# Creating a high-Cu sulfide '''matte by smelting''' the concentration
# '''Oxidizing/converting''' the sulfide matte, resulting in an impure molten copper
# '''Refining by fire and electrowinning''' techniques to increase purity of resultant copper<ref name="Schlesinger-2011" />

Chalcopyrite ore is not directly smelted. This is because the ore is primarily composed of non-economically valuable material, or waste rock, with low concentrations of copper. The abundance of waste material results in a lot of hydrocarbon fuel being required to heat and melt the ore. Alternatively, copper is isolated from the ore first using a technique called '''[[froth flotation]]'''. Essentially, [[Reagent|reagents]] are used to make the copper water-repellent, thus the Cu is able to concentrate in a flotation cell by floating on air bubbles. In contrast to the 0.5–2% copper in chalcopyrite ore, froth flotation results in a [[concentrate]] containing about 30% copper.<ref name="Schlesinger-2011" />

The concentrate then undergoes a process called '''matte smelting'''. Matte smelting [[Redox|oxidizes]] the sulfur and iron<ref name="Chamveha-2008">{{Cite journal |last1=Chamveha |first1=Pimporn |last2=Chaichana |first2=Kattiyapon |last3=Chuachuensuk |first3=Anon |last4=Authayanun |first4=Suthida |last5=Arpornwichanop |first5=Amornchai |date=2008-10-09 |title=Performance Analysis of a Smelting Reactor for Copper Production Process |url=http://dx.doi.org/10.1021/ie800618a |journal=Industrial & Engineering Chemistry Research |volume=48 |issue=3 |pages=1120–1125 |doi=10.1021/ie800618a |issn=0888-5885}}</ref> by melting the flotation concentrate  in a 1250{{nbsp}}°C furnace to create a new concentrate (matte) with about 45–75% copper.<ref name="Schlesinger-2011" /> This process is typically done in flash furnaces. To reduce the amount of copper in the [[slag]] material, the slag is kept molten with an addition of SiO<sub>2</sub> flux<ref name="Chamveha-2008" /> to promote immiscibility between concentration and slag. In terms of byproducts, matte smelting copper can produce SO<sub>2</sub> gas which is harmful to the environment, thus it is captured in the form of [[sulfuric acid]]. Example reactions are as follows:<ref name="Schlesinger-2011" />

# 2CuFeS<sub>2 (s)</sub> +3.25O<sub>2(g)</sub> → Cu<sub>2</sub>S-0.5FeS<sub>(l)</sub> + 1.5FeO<sub>(s)</sub> + 2.5SO<sub>2(g)</sub>
# 2FeO<sub>(s)</sub> + SiO<sub>2(s)</sub> → Fe<sub>2</sub>SiO<sub>4(l)</sub><ref name="Schlesinger-2011" />

'''[[Converting (metallurgy)|Converting]]''' involves oxidizing the matte once more to further remove sulfur and iron; however, the product is 99% molten copper.<ref name="Schlesinger-2011" /> Converting occurs in two stages: the slag forming stage and the copper forming stage. In the slag forming stage, iron and sulfur are reduced to concentrations of less than 1% and 0.02%, respectively. The concentrate from matte smelting is poured into a converter that is then rotated, supplying the slag with oxygen through [[tuyere]]s. The reaction is as follows:

2FeS<sub>(l)</sub>+3O<sub>2(g)</sub>+SiO<sub>2(s)</sub> -> Fe<sub>2</sub>SiO<sub>4(l)</sub> + 2SO<sub>2(g)</sub> + heat

In the copper forming stage, the matte produced from the slag stage undergoes charging (inputting the matte in the converter), blowing (blasting more oxygen), and skimming (retrieving impure molten copper known as blister copper).<ref name="Schlesinger-2011" /> The reaction is as follows:

Cu<sub>2</sub>S<sub>(l)</sub> + O<sub>2(g)</sub> -> 2Cu<sub>(l)</sub> + SO<sub>2(g)</sub> + heat<ref name="Schlesinger-2011" />

Finally, the blister copper undergoes refinement through fire, [[Electrowinning|electrorefining]] or both. In this stage, copper is refined to a high-purity [[cathode]].<ref name="Schlesinger-2011" />