Aluminum is a silver-white metal, very low density (less than three times as dense as water), yet relatively strong. In addition, aluminum is ductile; that is, it can be drawn into wires or pressed into sheets or foil. It is the most abundant metallic element, and the third most abundant of all elements in the Earth’s crust, making up eight percent of the crust by weight. Only silicon and oxygen are more plentiful.
Aluminum has numerous applications in the home and industry, and is a familiar metal to in residential and commercial usage.
|Previous Element: Magnesium
Next Element: Silicon
|Phase at Room Temp.||solid|
|Melting Point (K)||933.57|
|Boiling Point (K)||2740|
|Heat of Fusion (kJ/mol)||10.7|
|Heat of Vaporization (kJ/mol)||291|
|Heat of Atomization (kJ/mol)||326|
|Thermal Conductivity (J/m sec K)||237|
|Electrical Conductivity (1/mohm cm)||376.676|
|Number of Isotopes||23(1 natural)|
|Electron Affinity (kJ/mol)||42.6|
|First Ionization Energy (kJ/mol)||577.6|
|Second Ionization Energy (kJ/mol)||1816.6|
|Third Ionization Energy (kJ/mol)||2744.7|
|Atomic Volume (cm3/mol)||10|
|Ionic Radius2- (pm)||---|
|Ionic Radius1- (pm)||---|
|Atomic Radius (pm)||143|
|Ionic Radius1+ (pm)||---|
|Ionic Radius2+ (pm)||---|
|Ionic Radius3+ (pm)||67.5|
|Common Oxidation Numbers||+3|
|Other Oxid. Numbers||+1|
|In Earth's Crust (mg/kg)||8.23x104|
|In Earth's Ocean (mg/L)||2.0×10-3|
|In Human Body (%)||0.00008%|
|Regulatory / Health|
|OSHA Permissible Exposure Limit (PEL)||TWA:15mg/m3 total particulate
5mg/m3 respirable particulate
|OSHA PEL Vacated 1989||TWA:15mg/m3 total particulate
5mg/m3 respirable particulate
|NIOSH Recommended Exposure Limit||TWA:0.1ppm|
Mineral Information Institute
Jefferson Accelerator Laboratory
Aluminum is a reactive metal, and does not occur in the metallic state in nature. Therefore, it was unknown as a separate element until the 1820’s, although its existence was predicted by several scientists who had studied aluminum compounds. It was produced in metallic form independently by the Danish chemist and physicist, Hans Christian Oersted, and the German chemist, Frederich Wohler, in the mid-1820’s.
The name aluminum was derived from alumen, the Latin name for alum (an aluminum sulfate mineral). The metal was called aluminium with the -ium ending being the accepted ending for most elements at this time. This usage persists in most of the world except the United States, where the last i has been dropped from the name.
Aluminum and Bauxite
Because aluminum metal reacts with water and air to form powdery oxides and hydroxides, aluminum metal is never found in nature. Many common minerals, including feldspars, contain aluminum, but extracting the metal from most minerals is very energy-intensive, and therefore expensive.
The main ore of aluminum is bauxite, the source of over 99% of metallic aluminum. Bauxite is the name for a mixture of similar minerals that contain hydrated aluminum oxides. These minerals are gibbsite (Al(OH)3), diaspore (AlO(OH)), and boehmite (AlO(OH)). Because it is a mixture of minerals, bauxite itself is a rock, not a mineral. Bauxite is reddish-brown, white, tan, and tan-yellow. It is dull to earthy in luster and can look like clay or soil. Bauxite forms when silica in aluminum-bearing rocks (that is, rocks with a high content of the mineral feldspar) is washed away (leached). This weathering process occurs in tropical and subtropical weathering climates.
Alternative sources of aluminum might someday include kaolin clay, oil shales, the mineral anorthosite, and even coal waste. However, as long as bauxite reserves remain plentiful and production costs are low, the technologies to process these alternative sources into alumina or metallic aluminum will likely not progress beyond the experimental stage.
Australia has huge reserves of bauxite, and produces over 40% of the world’s ore. Brazil, Guinea, and Jamaica are important producers, with lesser production from about 20 other countries. The United States’ production, which was important 100 years ago, is now negligible.
Most bauxite is first processed to make alumina, or aluminum oxide, a white granular material. Sometimes, raw bauxite is shipped overseas for processing to alumina, while in other cases it is processed near the mine. Alumina is lighter than bauxite because the water has been removed, and it flows readily in processing plants, unlike bauxite which has a sticky, muddy consistency. Australia, the United States, and China are the largest producers of alumina. All the U.S. alumina being made is from imported bauxite.
Aluminum metal is refined from alumina, usually in industrialized countries having abundant supplies of cheap hydroelectric power. The refining process is the Hall-Heroult Process, named after Charles Hall of the U.S. and Paul L.T. Heroult of France, who each independently invented the process in 1866. In this process, alumina (aluminum oxide) is dissolved in molten cryolite (cryolite is an aluminum fluoride mineral, Na3AlF6). The alumina is then separated into its elements by electrolysis. Though attempts have been made to replace this process, it is to this day the only method used to isolate aluminum on a commercial scale.
The largest producers of aluminum metal are Russia, China, the United States, and Canada, countries which have abundant hydroelectric power. More than 40 other countries also produce aluminum, including Norway, Iceland, Switzerland, Tajikistan, and New Zealand, which are small but mountainous, and have many rivers to provide hydroelectric power. Other areas of the world with access to abundant and cheap electricity, such as the Middle East, are also expanding their metal production capacities.
Recycling of aluminum by melting cans and other products is an important source of metal in many developed countries.
About 85% of all the bauxite mined worldwide is used to produce alumina for refining into aluminum metal. Another 10% produces alumina which is used in chemical, abrasive, and refractory products. The remaining 5% of bauxite is used to make abrasives, refractory materials, and aluminum compounds.
The lightness, strength, and corrosion resistance of aluminum are important considerations in its application. Metallic aluminum is used in transportation, packaging such as beverage cans, building construction, electrical applications, and other products. Aluminum, the third most abundant element at the Earth’s surface, is apparently harmless to plant and animal life.
Though aluminum is very important in industry and daily-life applications, it can be replaced by other commodities if necessary. For instance, copper can replace aluminum in electrical applications. Paper, plastics and glass make good packaging alternatives. Magnesium, titanium and steel can be used in vehicles and other forms of ground and air transportation.
Unless energy costs should rise steeply, the use of aluminum in most of these applications is not likely to be seriously threatened. Worldwide sources of bauxite are large enough to supply the demand for aluminum for some time to come.
- Common Minerals and Their Uses, Mineral Information Institute.
- More than 170 Mineral Photographs, Mineral Information Institute.
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