Titanium

Notable characteristics

Titanium is well known for its excellent corrosion resistance (almost as resistant as platinum), being able to withstand attack by acids, moist chlorine gas, and by common salt solutions. Pure titanium is not solubility | soluble in water but is soluble in concentrated acids. A metal|metallic chemical element|element, it is also well-known for its high strength-to-weight ratio. It is a light, strong metal with low density (60% as dense as steel) that, when pure, is quite ductility | ductile (especially in an oxygen-free environment), easy to work, lustrous, and metallic-white in colour. The relatively high melting point of this element makes it useful as a refractory metal. Titanium is as strong as steel, but 43% lighter; it is 60% heavier than aluminium, but twice as strong; however these numbers can vary a little because of the use of different alloys. These properties make titanium very resistant to the usual kinds of metal fatigue. This metal forms a passive but protective oxide coating (leading to corrosion-resistance) when exposed to elevated temperatures in air but at room temperatures it resists tarnish | tarnishing. The metal, which burns when heated in air 610 °C or higher (forming titanium dioxide) is also one of the only elements that burn in pure nitrogen gas (it burns at 800 °C and forms titanium nitride). Titanium is resistant to dilute sulfuric acid|sulfuric and hydrochloric acid, along with chlorine gas, chloride solutions, and most organic acids. It is paramagnetic (weakly attracted to magnets) and has a very low electrical conductivity|electrical and thermal conductivity. Experiments have shown that natural titanium becomes very radioactive after it is bombarded with deuterons, emitting mainly positrons and hard gamma rays. The metal is a dimorphic allotropy|allotrope with the hexagonal alpha form changing into the cubic beta form very slowly at around 880 Celsius|°C. When it is red hot the metal combines with oxygen, and when it reaches 550 °C it combines with chlorine. It also reacts with the other halogens and absorbs hydrogen.

Applications

Approximately 95% of titanium is consumed in the form of titanium dioxide (Tioxygen|O₂), an intensely white permanent pigment with good covering power in paints, paper, toothpaste, and plastics. Paints made with titanium dioxide are excellent reflectors of infrared radiation and are therefore used extensively by astronomers and in exterior paints. It is also used in cement, in gemstones, and as a strengthening filler in paper. Because of its very high tensile strength (even at high temperatures), light weight, extraordinary corrosion resistance, and ability to withstand extreme temperatures, titanium alloys are principally used in aircraft, armour plating, navy | naval ships, spacecraft and missiles. It is used in steel alloys to reduce grain size and as a deoxidiser but in stainless steel it is employed to reduce carbon content. Titanium is often alloyed with aluminium (to refine grain size), vanadium, copper (to harden), iron, manganese, molybdenum and with other metals. Welded Titanium pipe is used in the chemical industry for its corrosion resistance and is seeing growing use in petroleum drilling especially offshore for its strength, light weight and corrosion resistance. Its vanadium alloy is used to make the outer skin of aircraft, to make fire walls, landing gear, and hydraulic tubing. Titanium Metals Corporation's Annual Report of 2004 estimates titanium content of modern airliners to be 58, 43, and 18 metric tons for the Boeing 777, 747 and 737 respectively. While for the Airbus, 24, 17 and 12 metric tons of titanium are used for the A340, A330 and A320 respectively. Generally, newer models use more and widebodies use the most. For the newest models, the 787 might use 91 metric tons and the A380 77 metric tons. The engines account for 10-11 tons of those totals. Use of titanium in consumer products such as golf club (equipment)|golf clubs, bicycles, laboratory equipment, wedding bands, and laptop computers is becoming more common. Other uses:

Due to excellent resistance to sea water, it is used to make propeller shafts and rigging and in the heat exchangers of desalination plants and in heater-chillers for salt water aquariums.

Owing to its high stiffness it is favoured in place of steel in high performance model sailplane wing join rods.

It is used to produce relatively soft artificial gemstones.

Titanium tetrachloride (Tichlorine|Cl₄), a colourless liquid, is used to iridescence|iridise glass and because it fumes strongly in moist air it is also used to make smoke screens and in skywriting.

In addition to being a very important pigment, titanium dioxide is also used in sunscreens due to its ability to protect skin by itself.

Because it is considered to be physiologically inert, the metal is used in joint replacement implants such as hip ball and sockets and to make medical equipment and in pipe/tank lining in food processing.

Its inertness and ability to be attractively coloured makes it a popular metal for use in body piercing.

Titanium has the unusual ability to osseointegration|osseointegrate, enabling use in dental implants. This ability is also exploited by some orthopedic implants.

Titanium alloys are also used in glasses|spectacle frames. This results in a rather expensive, but highly durable and long lasting frame. Both traditional alloys and shape memory alloys find use in this application. Titanium has occasionally been used in construction: the 150-foot (45 m) memorial to Yuri Gagarin, the first man to travel in space, in Moscow, is made of titanium for the metal's attractive colour and association with rocketry. The Guggenheim Museum Bilbao and the Cerritos, California|Cerritos Library were the first buildings, respectively, in Europe and North America to be sheathed in titanium panels.

History

Titanium (Latin ''titan (mythology)|Titans'', Earth or the first sons of Gaia (mythology)|Gaia) was discovery of the chemical elements|discovered in England by Reverend William Gregor in 1791. He recognised the presence of a new element in ilmenite, and named it ''menachite''. At around the same time, Franz Joseph Muller also produced a similar substance, but could not identify it. The element was independently rediscovered several years later by Germany|German chemist Martin Heinrich Klaproth in rutile ore. Klaproth confirmed it as a new element and in 1795 he named it for the Latin word for Earth (also the name for the Titans of Greek mythology). The metal has always been difficult to extract from its various ores. Pure metallic titanium (99.9%) was first prepared in 1910 by Matthew A. Hunter by heating Tichlorine|Cl₄ with sodium in a steel bomb at 700–800 °C in the Hunter process. Titanium metal was not used outside the laboratory until 1946 when William Justin Kroll proved that titanium could be commercially produced by reducing titanium tetrachloride with magnesium in the Kroll process which is the method still used today. In 1950s|1950–1960s|1960s the Soviet Union attempted to corner the world titanium market as a tactic in the Cold War to prevent the American military from utilising it. In spite of these efforts, the U.S obtained large quantities of titanium when a European company set up a front for the U.S. foreign intelligence agencies to purchase it.

Occurrence and production

Titanium metal is not found unbound to other elements in nature but the element is the ninth most abundant element in the Earth's crust (0.63% by mass) and is present in most igneous rocks and in sedimentary rock|sediments derived from them (as well as in living things and natural bodies of water). It is widely distributed and occurs primarily in the minerals anatase, brookite, ilmenite, perovskite, rutile, titanite (sphene), as well in many iron ores. Of these minerals, only ilmenite and rutile have significant economic importance, yet even they are difficult to find in high concentrations. Because it chemical reaction | reacts easily with oxygen and carbon at high temperatures it is difficult to prepare pure titanium metal, crystals, or powder. Significant titanium ore deposits are in Australia, Scandinavia, North America and Malaysia. ''Chiffres de 2003, en milliers de tonnes de dioxide de titane'' ''Source ; L'état du monde 2005, annuaire économique géopolique mondial'' This metal is found in meteorites and has been detected in the sun and in Stellar classification|M-type stars. Rock (geology)|Rocks brought back from the moon during the Apollo 17 mission are composed of 12.1% TiO₂. Titanium is also found in coal ash, plants, and even the human body. Because the metal reacts with air at high temperatures it can not be produced by reduction of its dioxide. Titanium metal is therefore produced commercially by the Kroll process; a complex, and expensive batch production|batch process developed in 1946 by William Justin Kroll. In the Kroll process, the oxide is first converted to chloride through carbochlorination, whereby chlorine gas is passed over red-hot rutile or ilmenite in the presence of carbon to make Titanium tetrachloride|TiCl₄. This is condensed and purified by fractional distillation and then reduction (chemistry)|reduced with 800 °C molten magnesium in an argon atmosphere. A newer process called the FFC Cambridge Process may displace this older process. This method uses the feedstock titanium dioxide powder (which is a refined form of rutile) to make the end product which is either a powder or sponge. If mixed oxide powders are used, the product is an alloy at a much lower cost than the conventional multi-step melting process. It is hoped that the FFC Cambridge Process will render titanium a less rare and expensive material for the aerospace industry and the luxury goods market, and will be seen in many products currently manufactured using aluminium and specialist grades of steel. Titanium may be purified to ultra high purity in small quantities by the van Arkel deBoer process by reacting with iodine and decomposing the formed vapors over a hot filament to pure metal. Titanium oxide is produced commercially by grinding its mineral ore and mixing it with potassium carbonate and aqueous hydrofluoric acid. This yields potassium fluorotitanate (potassium|K₂Tifluorine|F₆) which is extracted with hot water and decomposed with ammonia, producing a ammoniacal hydrated oxide. This in turn is ignited in a platinum vessel, which creates pure titanium dioxide. Common titanium alloys are made by reduction (chemistry)|reduction. For example; cuprotitanium (rutile with copper added is reduced), ferrocarbon titanium (ilmenite reduced with coke (fuel)|coke in an electric furnace), and manganotitanium (rutile with manganese or manganese oxides are reduced).

Compounds

The +4 oxidation state dominates in titanium chemistry, but compounds in the +3 oxidation state are also common. Because of this high oxidation state, many titanium compounds have a high degree of covalent bonding. Although titanium metal is relatively uncommon, due to the cost of extraction, titanium dioxide (also called titanium(IV), titanium white, or even titania) is cheap, nontoxic, readily available in bulk, and very widely used as a white pigment in paint, vitreous enamel|enamel, lacquer, plastic and construction cement. TiO₂ powder is chemically inert, resists fading in sunlight, and is very opaque: this allows it to impart a pure and brilliant white colour to the brown or gray chemicals that form the majority of household plastics. In nature, this compound is found in the minerals anatase, brookite, and rutile. Paint made with titanium dioxide does well in severe temperatures, is somewhat self-cleaning, and stands up to marine environments. Pure titanium dioxide has a very high refractive index|index of refraction and an optical dispersion higher than diamond. Star sapphires and ruby|rubies get their asterism from the titanium dioxide present in them. Titanates are compounds made with titanium dioxide. Barium titanate has piezoelectric properties, thus making it possible to use it as a transducer in the interconversion of sound and electricity. Esters of titanium are formed by the reaction of alcohols and titanium tetrachloride and are used to waterproof Cloth|fabrics. Titanium nitride is often used to coat cutting tools, such as drill bits. It also finds use as a gold-coloured decorative finish, and as a Copper-based chips#Barrier metal|barrier metal in semiconductor fabrication. Titanium tetrachloride|Titanium(IV) chloride (titanium tetrachloride, TiCl₄, sometimes called "Tickle") is a colourless, weakly acidic liquid which is used as an intermediate in the manufacture of titanium(IV) oxide for paint. It is widely used in organic chemistry as a Lewis acid, for example in the Mukaiyama aldol condensation. Titanium also forms a lower chloride, titanium(III) chloride (TiCl₃), which is used as a reducing agent. Titanocene dichloride is an important catalyst for carbon-carbon bond formation. Titanium isopropoxide is used for Sharpless epoxidation. Other compounds include; Titanium bromide (used in metallurgy, superalloys, and high-temperature electrical wiring and coatings) and titanium carbide (found in high-temperature cutting tools and coatings).

Isotopes

Naturally occurring titanium is composed of 5 stable isotopes; Ti-46, Ti-47, Ti-48, Ti-49 and Ti-50 with Ti-48 being the most abundant (73.8% natural abundance). Eleven radioisotopes have been characterized with the most stable being Ti-44 with a half-life of 63 years, Ti-45 with a half-life of 184.8 minutes, Ti-51 with a half-life of 5.76 minutes, and Ti-52 with a half-life of 1.7 minutes. All of the remaining radioactive isotopes have half-lifes that are less than 33 seconds and the majority of these have half-lifes that are less than half a second. The isotopes of titanium range in atomic weight from 39.99 atomic mass unit|amu (Ti-40) to 57.966 amu (Ti-58). The primary decay mode before the most abundant stable isotope, Ti-48, is electron capture and the primary mode after is beta emission. The primary decay products before Ti-48 are element 21 (scandium) isotopes and the primary products after are element 23 (vanadium) isotopes.

Precautions

When in a metallic powdered form, titanium metal poses a significant fire hazard and, when heated in air, an explosion hazard. Water and carbon dioxide-based methods to extinguish fires are ineffective on burning titanium; sand, dirt, or special foams must be used instead. Salts of titanium are often considered to be relatively harmless but chlorine compounds, such as TiCl₃ and TiCl₄, should be considered corrosive. Titanium also has a tendency to bio-accumulate in tissues that contain silica but it does not play any known biological role in humans.

References

http://periodic.lanl.gov/elements/22.html

''Guide to the Elements – Revised Edition'', Albert Stwertka, (Oxford University Press; 1998) ISBN 0-19-508083-1

''The History and Use of Our Earth's Chemical Elements: A Reference Guide'', Robert E. Krebs (Greenwood Press: Westport, CT, 1998) ISBN 0-313-30123-9

"titanium" Encyclopædia Britannica from Encyclopædia Britannica Premium Service.http://www.britannica.com/eb/article?tocId=7296

"titanium" ''The Columbia Electronic Encyclopedia, 6th ed'' http://www.infoplease.com/ce6/sci/A0848871.html

"titanium," Microsoft Encarta Online Encyclopedia 2005 http://encarta.msn.com/encyclopedia_761569280/Titanium.html

http://minerals.usgs.gov/minerals/pubs/commodity/titanium/

'''''Nature''''', Vol 407, 21 Sept 2000

External links

http://www.webelements.com/webelements/elements/text/Ti/index.html(also used as a reference)

http://www.msm.cam.ac.uk/phase-trans/2003/titanium.movies/titanium.html

http://www.indexmundi.com/en/commodities/minerals/titanium/titanium_table15.html