mineral resources
TRANSCRIPT
Sumberdaya Mineral (Minerals Resources)
Dr. Arifudin Idrus
Gadjah Mada University - INDONESIA
GEORESOURCES
Introduction: Natural Resources And Human History (1)
Over one hundred sixty thousand years ago, our ancestors probably began to use flint, chert, and obsidian to make tools.
Metals were first used more than 20,000 years ago. Copper and gold were the earliest metals used. By 6000 years ago, our ancestors extracted copper
by smelting. Before another thousand years had passed, they had
discovered how to smelt lead, tin, zinc, silver, and other metals.
Introduction: Natural Resources And Human History (2)
The technique of mixing metals to make alloys came next.
– Bronze was composed of copper and tin.– Pewter was composed of tin, lead, and copper.
The smelting of iron came much later—about 3300 years ago.
The first people to use oil instead of wood for fuel were the Babylonians, about 4500 years ago.
The first people to mine and use coal were the Chinese, about 3100 years ago.
Mineral Resources (1)
Mineral deposits are any volume of rock containing an enrichment of one or more minerals.
Mineral resources have three distinctive characteristics: Occurrences of usable minerals are limited in
abundance and localized at places within the Earth’s crust.
The quantity of a given mineral available in any one country is rarely known with accuracy.
Deposits of minerals are depleted by mining and eventually exhausted.
Figure 21.1
Enrichment factors
Mineral Resources (2)
Ore is an aggregate of minerals from which one or more minerals can be extracted profitably.
“Ore” is an economic term, whereas “mineral deposit” is a geologic term.
The economic challenges of ore are to find it, mine it, and refine it as cheaply as possible.
The lowest-grade ores ever mined—about 0.5 percent copper—were worked only at a time of high metal prices.
Mineral Resources (3)
In 2002, lowest grade of of mineable copper ore is closer to 1 percent. Over production of copper around the world,
combined with economic recession, has resulted in the closing of many mines, particularly those exploiting the lowest grades of ores.
Mineral Resources (4)
Sphalerite, galena, and chalcopyrite are ore minerals from which zinc, lead, and copper respectively can be extracted.
Ore minerals rarely occur alone. They are mixed with other nonvaluable minerals,
collectively termed gangue.– Gangue may include quartz, feldspar, mica, calcite, or
dolomite.
Origin Of Mineral Deposits (1)
All ores are mineral deposits because each of them is a local enrichment of one or more minerals or mineraloids.
Not all minerals deposits are ores. In order for a deposit to form, processes must bring
about a localized enrichment of one or more minerals.
Origin Of Mineral Deposits (2)
Minerals become concentrated in five ways: 1. Concentration by hot, aqueous solutions flowing
through fractures and pore spaces in crustal rock to form hydrothermal mineral deposits.
2. Concentration by magmatic processes within a body of igneous rock to form magmatic mineral deposits.
Origin Of Mineral Deposits (3)
3. Concentration by precipitation from lake water or sea water to form sedimentary mineral deposits.
4. Concentration by flowing surface water in streams or along the shore, to form placers.
5. Concentration by weathering processes to form residual mineral deposits.
Hydrothermal Mineral Deposits (1)
Some solutions originate when water dissolved in magma is released as the magma rises and cools.
Other solutions are formed from rainwater or seawater that circulates deep in the crust.
Mineral deposits formed from midocean ridge volcanism are called volcanogenic massive sulfide deposits.
Figure 21.3
Hydrothermal Mineral Deposits (2)
The pyroxene-rich rocks of the oceanic crust yield solutions charged with copper and zinc. As a result, volcanogenic massive sulfide deposits are
rich in copper and zinc. In black smokers, the rising hydrothermal fluid
appears black due to fine particles of iron sulfide and other minerals precipitated from solution as the plume is cooled by contact with cold seawater. The chimney-like structure is composed of pyrite,
chalcopyrite, and other ore minerals deposited by hydrothermal solution.
Hydrothermal Mineral Deposits (3)
When a hydrothermal solution moves slowly upward, as with groundwater percolating through an aquifer, the solution cools very slowly.
If dissolved minerals were precipitated from such a slow-moving solution, they would be spread over a large volume of rock and would not be sufficiently concentrated to form an ore.
Hydrothermal Mineral Deposits (4)
When a solution flows rapidly, as in an open fracture, or through a mass of shattered rocks, or through a layer of porous tephra where flow is less restricted, cooling can be sudden and can occur over short distances. Rapid precipitation and a concentrated mineral deposit
are the result. Veins formed when hydrothermal solutions deposit
minerals in open fractures. Many such veins are found in regions of volcanic
activity.
Figure 21.5
Hydrothermal Mineral Deposits (5)
The famous gold deposits at Cripple Creek, Colorado, were formed in fractures associated with a small caldera.
The huge tin and silver deposits in Bolivia are in fractures that are localized in and around stratovolcanoes.
Many famous ore bodies are associated with intrusive igneous rocks. Tin in Cornwall, England, Copper at Butte, Montana, Bingham, Utah, and Bisbee,
Arizona.
Figure 21B1
Figure 21B2
Magmatic Mineral Deposits (1)
The processes of partial melting and fractional crystallization are two ways of separating some minerals from other.
The processes involved are entirely magmatic, and so such deposits are referred to as magmatic mineral deposits.
Magmatic Mineral Deposits (2)
Pegmatites formed by fractional crystallization of granitic magma commonly contain rich concentrations of such elements as: Lithium. Beryllium. Cesium. Niobium.
Magmatic Mineral Deposits (3)
Much of the world’s lithium is mined from pegmatites such as those at King’s Mountain, North Carolina, and Bikita in Zimbabwe.
The great Tanco pegmatite in Manitoba, Canada, produces much of the world’s cesium, and pegmatites in many countries yield beryl, one of the main ore minerals of beryllium.
Magmatic Mineral Deposits (4)
Crystal settling, another process of fractional crystallization, is especially important in low-viscosity basaltic magma.
One of the first minerals to form is chromite, the main ore mineral of chromium.
The dense chromite crystals settle to the bottom of the magma, producing almost pure layers of chromite. The world’s principal deposits of chromite are in the
Bushveld igneous complex in South Africa and the Great Dike of Zimbabwe.
Sedimentary Mineral Deposits
The term sedimentary mineral deposits is applied to any local concentration of minerals formed through processes of sedimentation.
One form of sedimentation is the precipitation of substances carried in solution.
There are three types of sedimentary mineral deposits: Evaporite deposits. Iron deposits. Stratabound deposits.
Evaporite Deposits (1)
Evaporite deposits are formed by evaporation of lake water or seawater.
The layers of salts precipitate as a consequence of evaporation. Salts that precipitate from lake water of suitable
composition include sodium carbonate (Na2CO3), sodium sulfate (Na2SO4), and borax (Na2B4O7.1OH2O).
Evaporite Deposits (2)
Huge evaporite deposits of sodium carbonate were laid down in the Green River basin of Wyoming during the Eocene Epoch. Oil shales were also deposited in the basin.
Borax and other boron-containing minerals are mined from evaporite lake deposits in Death Valley and Searled and Borax Lakes, all in California; and in Argentina, Bolivia, Turkey, and China.
Evaporite Deposits (3)
Much more common and important than lake water evaporites are the marine evaporites formed by evaporation of seawater.
The most important salts that precipitate from seawater are: Gypsum (CaSO4.2H2O). Halite (NaCl). Carnallite (KCl.MgCl2.6H2O).
Evaporite Deposits (4)
Low-grade metamorphism of marine evaporite deposits causes another important mineral, sylvite (KCl), to form from carnallite.
Marine evaporite deposits are widespread. In North America, for example, strata of marine
evaporites underlie as much as 30 percent of the land area.
Evaporite Deposits (5)
Marine evaporites produce: Most of the salt that we use. The gypsum used for plaster. The potassium used in plants fertilizers.
Figure 21.6
Iron Deposits (1)
Sedimentary deposits of iron minerals are widespread, but the amount of iron in average seawater is so small that such deposits cannot have formed from seawater that is the same as today’s seawater.
Iron Deposits (2)
All sedimentary iron deposits are tiny by comparison with the class of deposits characterized by the Lake Superior-type iron deposits.
These remarkable deposits, mined principally in Michigan and Minnesota, were long the mainstay of the U.S. steel industry. They are declining in importance today because
imported ore is replacing them. They are of early Proterozoic age (about 2 billion
years or older).
Iron Deposits (3)
They are found in sedimentary basins on every craton (Labrador, Venezuela, Brazil, Russia, India, South Africa, and Australia).
They appear to be the product of chemical precipitation. They are interbedded layers of chert and several different
kinds of iron minerals. The cause of precipitation remains uncertain.
Iron Deposits (4)
Many experts suspect these evaporites formed from seawater of a different composition than today’s seawater.
The grade of the deposits ranges from 15 to 30 percent Fe by weight.
Iron Deposits (5)
Two additional processes can form iron ore: First, leaching of silica during weathering can lead to
secondary enrichment and can produce ores containing as much as 66 percent Fe.
The second way a Lake Superior-type iron can become an ore is through metamorphism.
– First, grain sizes increase so that separating ore minerals from the gangue becomes easier and cheaper.
– Second, new mineral assemblages form, and iron silicate and iron carbonate minerals originally present can be replaced by magnetite or hematite, both of which are desirable ore minerals.
Figure 21.7
Iron Deposits (5)
Ore grade is not increase by metamorphism, The changes in grain size and mineralogy transform the
sedimentary rock into an ore. Iron ores formed as a result of metamorphism are
called taconites, and they are now the main kind of ore mined in Lake Superior region.
Stratabound Deposits (1)
Some of the world’s most important ores of lead, zinc, and copper occur in sedimentary rock;
The ore minerals—galena, sphalerite, chalcopyrite, and pyrite—occur in such regular, fine layers that they look like sediments.
The sulfide mineral layers are enclosed by and parallel to the sedimentary strata in which they occur. For this reason, they are called stratabound mineral
deposits.
Figure 21.8
Stratabound Deposits (2)
Most stratabound deposits are diagenetic in origin. Stratabound deposits form when a hydrothermal
solution invades and reacts with a muddy sediment. The famous copper deposits of Zambia, in central Africa,
are stratabound deposits. The world’s largest and richest lead and zinc deposits are
also stratabound:– Broken Hill, Australia.– Mount Isa in Australia.– Kimberley in British Columbia.
Placers (1)
A mineral with a high specific gravity will become concentrated by flowing water.
Deposits of minerals having high specific gravities are placers.
Most placers are found in stream gravels that are geologically young.
Figure 21.9
Figure 21.10
Placers (2)
The most important minerals concentrated in placers are gold, platinum, cassiterite (SnO2), and diamond.
More than half of the gold recovered throughout all of human history has come from placers.
Placers (3)
The South African fossil placers are a series of gold-bearing conglomerates. They were laid down 2.7 billion years ago as gravels in the
shallow marginal waters of a marine basin. Associated with the gold are grains of pyrite and uranium
minerals. Nothing like the deposits in the Witwatersrand basin has been
discovered anywhere else. – Mining the Witwatersrand basin has reached a depth of 3600 m
(11,800 ft).– The deposits are running out of ore.
Residual Mineral Deposits (1)
Chemical weathering leads to mineral concentration through the removal of soluble materials and the concentration of a less soluble residue.
A common example of a deposit formed through residual concentration is bauxite.
Residual Mineral Deposits (2)
Bauxites are: The source of the world’s aluminum. Concentrated in the tropics because that is where
lateritic weathering occurs. Found in present-day temperate conditions, such as
France, China, Hungary, and Arkansas, where the climate was tropical when the bauxites formed.
Not found in glacial regions.– Glaciers scrape off the soft surface materials.
Residual Mineral Deposits (3)
More than 90 percent of all known bauxite deposits formed during the last 60 million years,
All of the very large bauxite deposits formed less than 25 million years ago.
Residual Mineral Deposits (4)
Many of the world’s manganese deposits have been formed by secondary enrichment of low-grade primary deposits, particularly in tropical regions. Secondary enrichment zones are produced by deposition of soluble minerals near the groundwater table, leached from mineral deposits present near the surface.
One of the largest nickel deposits ever found, in New Caledonia, was formed by secondary enrichment.
Residual Mineral Deposits (5)
Secondary enrichment has led to large deposits in the arid southwestern United States and desert regions of northern Chile of: Pyrite (FeS2). Chalcopyrite (CuFeS2). Chalcocite (CuS2).
Useful Mineral Substances (1)
Excluding substances used for energy, there are two broad groups of useful minerals: Metallic minerals, from which metals such as iron,
copper, and gold can be recovered. Nonmetallic minerals, such as salts, gypsum, and clay.
Useful Mineral Substances (2)
Geochemically abundant metals include: Iron. Aluminum. Manganese. Magnesium. Titanium.
Useful Mineral Substances (3)
Geochemically scarce metals represent less than 0.1 percent by weight of the crust. They are present exclusively as a result of atomic
substitution. Atoms of the scarce metals (such as nickel,
cobalt, and copper) can readily substitute for more common atoms (such as magnesium and calcium).
Useful Mineral Substances (4)
Most ore minerals of the scarce metals are sulfides. A few, such as the ore minerals of tin and tungsten,
are oxides; Most scarce metal deposits form as
hydrothermal or magmatic mineral deposits.
Figure 21.20