Leaching (metallurgy)

Last updated

Leaching is a process widely used in extractive metallurgy where ore is treated with chemicals to convert the valuable metals within the ore, into soluble salts while the impurity remains insoluble. These can then be washed out and processed to give the pure metal; the materials left over are commonly known as tailings. Compared to pyrometallurgy, leaching is easier to perform, requires less energy and is potentially less harmful as no gaseous pollution occurs. Drawbacks of leaching include its lower efficiency and the often significant quantities of waste effluent and tailings produced, which are usually either highly acidic or alkali as well as toxic (e.g. bauxite tailings).

Contents

There are four types of leaching:

  1. Cyanide leaching (e.g. gold ore)
  2. Ammonia leaching (e.g. crushed ore)
  3. Alkali leaching (e.g. bauxite ore)
  4. Acid leaching (e.g. sulfide ore) [1] [2]


Leaching is also notable in the extraction of rare earth elements, which consists of lanthanides, yttrium and scandium. [2]

Chemistry

Leaching is done in long pressure vessels which are cylindrical (horizontal or vertical) or of horizontal tube form known as autoclaves. A good example of the autoclave leach process can also be found in the metallurgy of zinc. It is best described by the following chemical reaction:

2 ZnS + O2 + 2 H2SO4 → 2 ZnSO4 + 2 H2O + 2 S

This reaction proceeds at temperatures above the boiling point of water, thus creating a vapour pressure inside the vessel. Oxygen is injected under pressure, making the total pressure in the autoclave more than 0.6 MPa and temperature at 473-523 K .

The leaching of precious metals such as gold can be carried out with cyanide or ozone under mild conditions. [1]

Historical Uses

Origins

Jabir Ibn Hayyan, Arab alchemist and creator of "aqua regia." Jabir ibn Hayyan, Sayr mulhimah min al-Sharq wa-al-Gharb.png
Jabir Ibn Hayyan, Arab alchemist and creator of "aqua regia."

Heap leaching dates back to the second century BC in China, where iron was combined with copper sulfate. [3] By the time of the Northern Song Dynasty, a copper alloy was able to be recovered by leaching. [3]

Leaching can also be traced back to alchemy. [4] Early examples of leaching performed by alchemists resembled mixing iron with copper sulfate, yielding a layer of metallic copper. [4] In the 8th century, Jabir Ibn Hayyan, an Arab alchemist, discovered a substance he coined "aqua regia". [4] Aqua regia, a combination of hydrochloric acid and nitric acid, was found to be effective in dissolving gold, which was previously thought to be insoluble. [4]

Pre-World War II

In the 16th century, heap leaching became commonly used to extract copper and saltpeter from organic matter. [4] Primarily used in Germany and Spain, pyrite would be brought to the surface and left out in the open. [4] [3] The pyrite would be set outside for months at a time, where rain and air exposure would lead to chemical weathering. [4] A solution containing copper sulfide would be collected in a basin, then precipitated in a process called cementation, resulting in metallic copper. [4] Heap leaching, in this natural chemical-free form, was further developed to obtain different, more economically viable, types of ore. This was done by incorporating chemical lixiviation, which applies more chemical manipulation and technique to heap leaching. [5]

From 1767-1867, the production of potash in Quebec became an important industry to supply France's glass and soap manufacturers. [4] Potash was most frequently made from the ash remains of wood-burning stoves and fireplaces, which were agitated with water and filtered. [4] Once evaporated, the remains would be potash. 400 tons of hardwood would be required to burn to yield one ton of potash. [4]

In 1858 Adolf Von Patera, a metallurgist in Austria, utilized lixiviation separate soluble and insoluble compounds from silver in an aqueous solution. [6] [7] Von Patera's process, though successful, did not generate much use due partly to the price of hyposulphite. [8] Additionally, with Patera's process, if the sodium hyposulphite failed to dissolve perfectly, silver would often be caught in the extra solution and not properly extracted. [8]

The technique of Patera's lixiviation was further developed by American E.H Russell around 1884, creating the "Russell Process". [9] [8] Prior leaching processes often could not concentrate ores with too much base metal, something thing the Russel Process was able to solve thus making it more lucrative. [8]

In 1887, when the cyanidation process was patented in England, it began to phase out the existing Russell Process. [5] Cyanidation was much more efficient and had a recovery rate of up to 90%. [5]

Leading up to World War I, many new ideas for leaching processes were experimented. [4] This included using ammonia solutions for copper sulfides, and nitric acid for leaching sulfide ores. [4] Most of these ideas were phased out into obscurity due to the high cost of the leaching agents required. [4]

Modern Leaching

Heap leaching process diagram, specifically for uranium. Heap Leach Recovery Process (35992338083).jpg
Heap leaching process diagram, specifically for uranium.

In the 1940s, as a result of the Manhattan Project, the United States government needed ready access to uranium. [4] Many different techniques in leaching were quickly employed at a large scale. [4] Both synthetic resins and organic solvents were used early on to extract uranium. [4] Ultimately, the use of organic solvents was less tedious compared to ion exchange through synthetic resins, and further production of uranium and other rare earth metals moved towards solvent extraction. [4] In the 1950s, pressure hydrometallurgy was developed for the leaching of multiple different metals, such as sulfide concentrates and laterites. [4] Particularly at the Mines Branch in Ottawa (now known as CANMET), it was demonstrated that pyrrhotite-penthandite concentrate could be treated in autoclaves, with the resulting nickel in a solution while iron oxide and sulfur remain in the residue. [4] This process was later used in other nickel recovery operations across the globe. [4]

In the 1960s, heap and in situ leaching became widely practiced, particularly for copper. [4] In situ leaching was later used for the extraction of uranium as well. [4]

Pressure leaching was further refined in the 1970s and 80s. [4]

See also

Related Research Articles

Bioleaching is the extraction or liberation of metals from their ores through the use of living organisms. Bioleaching is one of several applications within biohydrometallurgy and several methods are used to treat ores or concentrates containing copper, zinc, lead, arsenic, antimony, nickel, molybdenum, gold, silver, and cobalt.

Extractive metallurgy is a branch of metallurgical engineering wherein process and methods of extraction of metals from their natural mineral deposits are studied. The field is a materials science, covering all aspects of the types of ore, washing, concentration, separation, chemical processes and extraction of pure metal and their alloying to suit various applications, sometimes for direct use as a finished product, but more often in a form that requires further working to achieve the given properties to suit the applications.

<span class="mw-page-title-main">Chalcopyrite</span> Copper iron sulfide mineral

Chalcopyrite ( KAL-kə-PY-ryte, -⁠koh-) is a copper iron sulfide mineral and the most abundant copper ore mineral. It has the chemical formula CuFeS2 and crystallizes in the tetragonal system. It has a brassy to golden yellow color and a hardness of 3.5 to 4 on the Mohs scale. Its streak is diagnostic as green-tinged black.

<span class="mw-page-title-main">Malachite</span> Mineral variety of copper carbonate

Malachite is a copper carbonate hydroxide mineral, with the formula Cu2CO3(OH)2. This opaque, green-banded mineral crystallizes in the monoclinic crystal system, and most often forms botryoidal, fibrous, or stalagmitic masses, in fractures and deep, underground spaces, where the water table and hydrothermal fluids provide the means for chemical precipitation. Individual crystals are rare, but occur as slender to acicular prisms. Pseudomorphs after more tabular or blocky azurite crystals also occur.

Gold cyanidation is a hydrometallurgical technique for extracting gold from low-grade ore by converting the gold to a water-soluble coordination complex. It is the most commonly used leaching process for gold extraction. Cyanidation is also widely used in the extraction of silver, usually after froth flotation.

<span class="mw-page-title-main">Copper extraction</span> Process of extracting copper from the ground

Copper extraction refers to the methods used to obtain copper from its ores. The conversion of copper ores consists of a series of physical, chemical and electrochemical processes. Methods have evolved and vary with country depending on the ore source, local environmental regulations, and other factors.

Hydrometallurgy is a technique within the field of extractive metallurgy, the obtaining of metals from their ores. Hydrometallurgy involve the use of aqueous solutions for the recovery of metals from ores, concentrates, and recycled or residual materials. Processing techniques that complement hydrometallurgy are pyrometallurgy, vapour metallurgy, and molten salt electrometallurgy. Hydrometallurgy is typically divided into three general areas:

<span class="mw-page-title-main">Gold extraction</span> Process of extracting gold from ore

Gold extraction is the extraction of gold from dilute ores using a combination of chemical processes. Gold mining produces about 3600 tons annually, and another 300 tons is produced from recycling.

<span class="mw-page-title-main">Electrowinning</span> Electrolytic extraction process

Electrowinning, also called electroextraction, is the electrodeposition of metals from their ores that have been put in solution via a process commonly referred to as leaching. Electrorefining uses a similar process to remove impurities from a metal. Both processes use electroplating on a large scale and are important techniques for the economical and straightforward purification of non-ferrous metals. The resulting metals are said to be electrowon.

<span class="mw-page-title-main">Heap leaching</span> Industrial mining process used to extract precious metals from ore

Heap leaching is an industrial mining process used to extract precious metals, copper, uranium, and other compounds from ore using a series of chemical reactions that absorb specific minerals and re-separate them after their division from other earth materials. Similar to in situ mining, heap leach mining differs in that it places ore on a liner, then adds the chemicals via drip systems to the ore, whereas in situ mining lacks these liners and pulls pregnant solution up to obtain the minerals. Heap leaching is widely used in modern large-scale mining operations as it produces the desired concentrates at a lower cost compared to conventional processing methods such as flotation, agitation, and vat leaching.

<span class="mw-page-title-main">Ore genesis</span> How the various types of mineral deposits form within the Earths crust

Various theories of ore genesis explain how the various types of mineral deposits form within Earth's crust. Ore-genesis theories vary depending on the mineral or commodity examined.

Biohydrometallurgy is a technique in the world of metallurgy that utilizes biological agents (bacteria) to recover and treat metals such as copper. Modern biohydrometallurgy advances started with the bioleaching of copper more efficiently in the 1950's

<span class="mw-page-title-main">In situ leach</span>

In-situ leaching (ISL), also called in-situ recovery (ISR) or solution mining, is a mining process used to recover minerals such as copper and uranium through boreholes drilled into a deposit, in situ. In situ leach works by artificially dissolving minerals occurring naturally in a solid state. For recovery of material occurring naturally in solution, see: Brine mining.

Dr. Frank Arthur Forward (1902–1972) was a Canadian metallurgist and inventor. In 1947, he discovered a method for the extraction of nickel and cobalt.

<span class="mw-page-title-main">Leaching (chemistry)</span> Extraction of some soluble substances from a solid material into a liquid

Leaching is the process of a solute becoming detached or extracted from its carrier substance by way of a solvent.

<span class="mw-page-title-main">Outline of mining</span> Overview of and topical guide to mining

The following outline is provided as an overview of and topical guide to mining:

<span class="mw-page-title-main">Cobalt extraction</span>

Cobalt extraction refers to the techniques used to extract cobalt from its ores and other compound ores. Several methods exist for the separation of cobalt from copper and nickel. They depend on the concentration of cobalt and the exact composition of the ore used.

Pressure oxidation is a process for extracting gold from refractory ore.

Mineral processing and extraction of metals are very energy-intensive processes, which are not exempted of producing large volumes of solid residues and wastewater, which also require energy to be further treated and disposed. Moreover, as the demand for metals increases, the metallurgical industry must rely on sources of materials with lower metal contents both from a primary and/or secondary raw materials. Consequently, mining activities and waste recycling must evolve towards the development of more selective, efficient and environmentally friendly mineral and metal processing routes.

References

  1. 1 2 J. Viñals; E. Juan; M. Ruiz; E. Ferrando; M. Cruells; A. Roca; J. Casado (February 2006). "Leaching of gold and palladium with aqueous ozone in dilute chloride media". Hydrometallurgy. 81 (2): 142–151. Bibcode:2006HydMe..81..142V. doi:10.1016/j.hydromet.2005.12.004.
  2. 1 2 Borges de Lima, Ismar; Filho, Walter Leal (2016), "Highlights on Rare Earths", Rare Earths Industry, Elsevier, pp. 395–424, doi:10.1016/b978-0-12-802328-0.00026-7, ISBN   978-0-12-802328-0 , retrieved 2024-03-01
  3. 1 2 3 Bin, Yu; Kuangdi, Xu (2022), "Leaching Mining Method", in Xu, Kuangdi (ed.), The ECPH Encyclopedia of Mining and Metallurgy, Singapore: Springer Nature, pp. 1–3, doi:10.1007/978-981-19-0740-1_703-1, ISBN   978-981-19-0740-1 , retrieved 2024-03-08
  4. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Habashi, Fathi (2005-09-01). "A short history of hydrometallurgy". Hydrometallurgy. Teaching and Learning Hydrometallurgical Science and Engineering-Part I. 79 (1): 15–22. Bibcode:2005HydMe..79...15H. doi:10.1016/j.hydromet.2004.01.008. ISSN   0304-386X.
  5. 1 2 3 McQueen, Robery. "Mining "Invisible" Gold: Heap Leaching and Nevada's Contribution to Twentieth- Century Gold Mining" (PDF). 2021 Mining History Journal via Mining History Association.
  6. McQueen, Robery. "Mining "Invisible" Gold: Heap Leaching and Nevada's Contribution to Twentieth- Century Gold Mining" (PDF). 2021 Mining History Journal via Mining History Association.
  7. Eissler, Manuel (1891). The metallurgy of silver; a practical treatise on the amalgamation, roasting, and lixiviation of silver ores including the assaying, melting, and refining of silver bullion. unknown library. London, C. Lockwood and son.
  8. 1 2 3 4 Tyrrell, Frank (1893-01-01). "Russell's lixiviation process for silver ores". Professional Degree Theses.
  9. "Collection: Letters Regarding the Russell Process | Special Collections ArchivesSpace | University of Arizona Libraries". archives.library.arizona.edu. Retrieved 2024-03-22.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.