Information about Lateritic Nickel Ore Deposits
Lateritic nickel ore deposits are surficial, weathered rinds formed on ultramafic rocks which contain 0.2% or more of nickel, resulting in a goethite-limonite or nontronite clay containing 0.5% to 2.5% nickel.
Lateritization of ultramafic igneous rocks (serpentinite, dunite, or peridotite containing about 02 - 0.3% nickel) often results in a considerable nickel concentration.
Limonite type laterites (or oxide type) contain 1-2% Ni bound in goethite which is highly enriched due to very strong leaching of magnesium and silica. Beneath this zone nickel silicate ore can be formed, frequently containing > 2% Ni that is incorporated in silicate minerals primarily serpentine and chrysoprase. In pockets and fissures of the serpentinite rock green garnierite can be present in minor quantities, but with high nickel contents - mostly 20-40%. It is bound in newly formed phyllosilicate minerals. All the nickel in the silicate zone is leached downwards (absolute nickel concentration) from the overlying goethite zone. Absence of this zone is due to erosion.
Saprolite type laterites are formed beneath the oxide zone, which may sometimes be removed by erosion. Saprolite nickel ores may contain green nontronitic nickel bearing clays, garnierite, chrysoprase and are generally deficient in nickel bound in goethite-limonite.
Ore deposits of this type are restricted to the oxide and saprolite profiles developed above ultramafic rocks.[2] As such they tend to be tabular, flat and areally large, covering many square kilometres of the Earth's surface. However, at any one time the area of a deposit being worked for the nickel ore is much smaller, usually only a few hectares. The typical nickel laterite mine often operates as either an open cut mine or a strip mine.
Nickel laterites are generally mined via open cut mining methods with ore extracted via some form of hydrometallurgy process, with two main process routes; high-pressure acid leach (HPAL) and for some types of limonite type nickel laterites, heap leach-SX-EW process routes are viable.
The advantages of HPAL plants are that they are not as selective toward the type of ore minerals, grades and nature of mineralisation. The disadvantage is the energy required to heat the ore material and acid, and the wear and tear hot acid causes upon plant and equipment. Higher energy costs demand higher ore grades.
Ore is ground, agglomerated, and perhaps mixed with clay-poor rock, to prevent compaction of the clay-like materials and so maintain permeability. The ore is stacked on impermeable plastic membranes and acid is percolated over the heap, generally for 3 to 4 months, at which stage 60% to 70% of the nickel-cobalt content is liberated into acid solution, which is then neutralised with limestone and a nickel-cobalt hydroxide intermediate product is generated, generally then sent to a smelter for refining.
The advantage of heap leach treatment of nickeliferous laterite ores is that the plant and mine infrastructure are much cheaper - up to 25% of the cost of a HPAL plant - and less risky from a technological point of view. However, they are somewhat limited in the types of ore which can be treated.
Dunite (IPA: /ˈduːnʌɪt, ˈdʌnʌɪt/
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Pig iron is raw iron, the immediate product of smelting iron ore with coke and limestone in a blast furnace.
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Ore Genesis
Nickeliferous laterite is formed by weathering and oxidation of ultramafic rocks which preferentially enriches the laterite (a residual regolith material) in nickel at the expense of magnesium and silica which are removed by dissolution in the environment.Lateritization of ultramafic igneous rocks (serpentinite, dunite, or peridotite containing about 02 - 0.3% nickel) often results in a considerable nickel concentration.
Types of nickel laterites
Two kinds of lateritic nickel ore have to be distinguished: goethite-limonite types and nontronitic clay types.[1]Limonite type laterites (or oxide type) contain 1-2% Ni bound in goethite which is highly enriched due to very strong leaching of magnesium and silica. Beneath this zone nickel silicate ore can be formed, frequently containing > 2% Ni that is incorporated in silicate minerals primarily serpentine and chrysoprase. In pockets and fissures of the serpentinite rock green garnierite can be present in minor quantities, but with high nickel contents - mostly 20-40%. It is bound in newly formed phyllosilicate minerals. All the nickel in the silicate zone is leached downwards (absolute nickel concentration) from the overlying goethite zone. Absence of this zone is due to erosion.
Saprolite type laterites are formed beneath the oxide zone, which may sometimes be removed by erosion. Saprolite nickel ores may contain green nontronitic nickel bearing clays, garnierite, chrysoprase and are generally deficient in nickel bound in goethite-limonite.
Ore deposits
Typical nickel laterite ore deposits are very large tonnage, low-grade deposits located close to the surface. They are typically in the range of 20 million tonnes and upwards (this being a contained resource of 20,000 tonnes of nickel at 1%) with some examples approaching a billion tonnes of material. Thus, typically, nickel laterite ore deposits contain many billions of dollars of in-situ value of contained metal.Ore deposits of this type are restricted to the oxide and saprolite profiles developed above ultramafic rocks.[2] As such they tend to be tabular, flat and areally large, covering many square kilometres of the Earth's surface. However, at any one time the area of a deposit being worked for the nickel ore is much smaller, usually only a few hectares. The typical nickel laterite mine often operates as either an open cut mine or a strip mine.
Extraction
Nickel laterites are a very important type of nickel ore deposit. They are growing to become the most important source of nickel metal for world demand, and are second for now to sulphide nickel ore deposits.Nickel laterites are generally mined via open cut mining methods with ore extracted via some form of hydrometallurgy process, with two main process routes; high-pressure acid leach (HPAL) and for some types of limonite type nickel laterites, heap leach-SX-EW process routes are viable.
HPAL Processing
High Pressure Acid Leach processing is required for nickel laterite ores with a predominantly nontronitic character where nickel is bound within clay or secondary silicate substrates in the ores. The nickel (+/- cobalt) metal is liberated from such minerals only at low pH and high temperatures, generally in excess of 250 degrees celsius.The advantages of HPAL plants are that they are not as selective toward the type of ore minerals, grades and nature of mineralisation. The disadvantage is the energy required to heat the ore material and acid, and the wear and tear hot acid causes upon plant and equipment. Higher energy costs demand higher ore grades.
Heap (Atmospheric) Leach
Heap leach treatment of nickel laterites is primarily possible only for clay-poor oxide-rich ore types where clay contents are low enough to allow percolation of acid through the heap. Generally, this route of production is much cheaper - up to half the cost of production - due to the lack of need to heat and pressurise the ore and acid.Ore is ground, agglomerated, and perhaps mixed with clay-poor rock, to prevent compaction of the clay-like materials and so maintain permeability. The ore is stacked on impermeable plastic membranes and acid is percolated over the heap, generally for 3 to 4 months, at which stage 60% to 70% of the nickel-cobalt content is liberated into acid solution, which is then neutralised with limestone and a nickel-cobalt hydroxide intermediate product is generated, generally then sent to a smelter for refining.
The advantage of heap leach treatment of nickeliferous laterite ores is that the plant and mine infrastructure are much cheaper - up to 25% of the cost of a HPAL plant - and less risky from a technological point of view. However, they are somewhat limited in the types of ore which can be treated.
Pig iron oxide ores
A recent development in the extraction of nickel laterite ores is a partcular grade of tropical deposits, typified by examples at Acoje in the Philippines, developed on ophiolite sequence ultramafics. This ore is so rich in limonite (generally grading 47% to 59% iron, 0.8 to 1.5% nickel and trace cobalt) that it is essentially similar to low-grade iron ore. As such, certain steel smelters in China have developed a process for blending nickel limonite ore with conventional iron ore to produce stainless steel feed products. This pig iron process short-circuits the typical costly hydrometallurgical route for producing nickel, which is then used in stainless steel anyway.See also
References
1. ^ Schellmann, W. (1983): Geochemical principles of lateritic nickel ore formation. Proceedings of the 2. International Seminar on Lateritisation Processes, Sao Paulo, 119-135
2. ^ Golightly, J.P. (1981): Nickeliferous Laterite Deposits. Economic Geology 75, 710-735
2. ^ Golightly, J.P. (1981): Nickeliferous Laterite Deposits. Economic Geology 75, 710-735
Goethite, named after the German polymath Johann Wolfgang von Goethe, is an iron bearing oxide mineral found in soil and other low temperature environments. Goethite has been well known since prehistoric times for its use as a pigment.
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Limonite is an ore consisting in a mixture of hydrated iron(III) oxide-hydroxide of varying composition. The generic formula is frequently written as FeO(OH)·nH2
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Nontronite is the iron(III) rich member of the smectite group of clay minerals. Nontronites typically have a chemical composition consisting of more than ~30% Fe2O3 and less than ~12% Al2O3 (ignited basis).
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Ultramafic (or ultrabasic) rocks are igneous and meta-igneous rocks with very low silica content (less than 45%), generally >18% MgO, high FeO, low potassium, and are composed of usually greater than 90% mafic minerals (dark colored, high magnesium and iron content).
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Laterite is a surface formation in hot and wet tropical areas which is enriched in iron and aluminium and develops by intensive and long lasting weathering of the underlying parent rock.
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Serpentinite is a rock comprised of one or more serpentine minerals. Minerals in this group are formed by serpentinization, a hydration and metamorphic transformation of ultramafic rock from the Earth's mantle.
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Not to be confused with Dunnite.
Dunite (IPA: /ˈduːnʌɪt, ˈdʌnʌɪt/
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Peridotite is a dense, coarse-grained igneous rock, consisting mostly of the minerals olivine and pyroxene. Peridotite is ultramafic and ultrabasic, as the rock contains less than 45% silica.
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Garnierite is the name for a green nickel ore which is found in pockets and fissures of weathered ultramafic rocks (serpentinite, dunite, peridotite). The name was given by Jules Garnier who first discovered it 1864 in New Caledonia.
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Open-pit mining, also known as opencast mining, refers to a method of extracting rock or minerals from the earth by their removal from an open pit or borrow.
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Hydrometallurgy is part of the field of extractive metallurgy involving the use of aqueous chemistry for the recovery of metals from ores, concentrates, and recycled or residual materials.
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Solvent extraction/electrowinning (SX/EW) is a two-stage process that first extracts and upgrades copper ions from low-grade leach solutions into a concentrated electrolyte, and then deposits pure copper onto cathodes using an electrolytic procedure.
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Limestone is a sedimentary rock composed largely of the mineral calcite (calcium carbonate: CaCO3). Limestone often contains variable amounts of silica in the form of chert or flint, as well as varying amounts of clay, silt and sand as disseminations, nodules, or layers
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smelting, is a form of extractive metallurgy. The main use of smelting is to produce a metal from its ore. This includes iron extraction (for the production of steel) from iron ore, and copper extraction and other base metals from their ores.
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Ophiolite is a section of the Earth's oceanic crust and the underlying upper mantle that has been uplifted or emplaced to be exposed within continental crustal rocks. Ophio is Greek for "snake", lite means "stone".
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Limonite is an ore consisting in a mixture of hydrated iron(III) oxide-hydroxide of varying composition. The generic formula is frequently written as FeO(OH)·nH2
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3, 4, 6
(amphoteric oxide)
Electronegativity 1.83 (Pauling scale)
Ionization energies
(more) 1st: 762.5 kJmol−1
2nd: 1561.9 kJmol−1
3rd: 2957 kJmol−1
Atomic radius 140 pm
Atomic radius (calc.
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(amphoteric oxide)
Electronegativity 1.83 (Pauling scale)
Ionization energies
(more) 1st: 762.5 kJmol−1
2nd: 1561.9 kJmol−1
3rd: 2957 kJmol−1
Atomic radius 140 pm
Atomic radius (calc.
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2, 3
(mildly basic oxide)
Electronegativity 1.91 (Pauling scale)
Ionization energies
(more) 1st: 737.1 kJmol−1
2nd: 1753.0 kJmol−1
3rd: 3395 kJmol−1
Atomic radius 135 pm
Atomic radius (calc.
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(mildly basic oxide)
Electronegativity 1.91 (Pauling scale)
Ionization energies
(more) 1st: 737.1 kJmol−1
2nd: 1753.0 kJmol−1
3rd: 3395 kJmol−1
Atomic radius 135 pm
Atomic radius (calc.
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2, 3
(amphoteric oxide)
Electronegativity 1.88 (Pauling scale)
Ionization energies
(more) 1st: 760.4 kJmol−1
2nd: 1648 kJmol−1
3rd: 3232 kJmol−1
Atomic radius 135 pm
Atomic radius (calc.
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(amphoteric oxide)
Electronegativity 1.88 (Pauling scale)
Ionization energies
(more) 1st: 760.4 kJmol−1
2nd: 1648 kJmol−1
3rd: 3232 kJmol−1
Atomic radius 135 pm
Atomic radius (calc.
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Iron ores are rocks and minerals from which metallic iron can be economically extracted. The ores are usually rich in iron oxides and vary in colour from dark grey to rusty red.
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This page contains Chinese text.
Without proper rendering support, you may see question marks, boxes, or other symbols instead of Chinese characters.
China (Traditional Chinese: Without proper rendering support, you may see question marks, boxes, or other symbols instead of Chinese characters.
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stainless steel is defined as an iron-carbon alloy with a minimum of 10.5% chromium content.[1] The name originates from the fact that stainless steel does not stain, corrode or rust as easily as ordinary steel (note: it "stains less", but is not actually "stainless").
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- For the DC Comics superhero Pig Iron, see Peter Porkchops. For the band see Pig Irön.
Pig iron is raw iron, the immediate product of smelting iron ore with coke and limestone in a blast furnace.
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The various theories of ore genesis explain how the various types of mineral deposits form within the Earth's crust. Ore genesis theories are very dependent on the mineral or commodity.
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Laterite is a surface formation in hot and wet tropical areas which is enriched in iron and aluminium and develops by intensive and long lasting weathering of the underlying parent rock.
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Open-pit mining, also known as opencast mining, refers to a method of extracting rock or minerals from the earth by their removal from an open pit or borrow.
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2, 3
(mildly basic oxide)
Electronegativity 1.91 (Pauling scale)
Ionization energies
(more) 1st: 737.1 kJmol−1
2nd: 1753.0 kJmol−1
3rd: 3395 kJmol−1
Atomic radius 135 pm
Atomic radius (calc.
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(mildly basic oxide)
Electronegativity 1.91 (Pauling scale)
Ionization energies
(more) 1st: 737.1 kJmol−1
2nd: 1753.0 kJmol−1
3rd: 3395 kJmol−1
Atomic radius 135 pm
Atomic radius (calc.
..... Click the link for more information.
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