Iron

      Iron is a chemical element with the symbol Fe (from Latin: ferrum) and atomic number 26. It is a metal in the first transition series. It is the most common element (by mass) forming the planet Earth as a whole, forming much of Earth's outer and inner core. It is the fourth most common element in the Earth's crust. Iron's very common presence in rocky planets like Earth is due to its abundant production as a result of fusion in high-mass stars, where the production of nickel-56 (which decays to the most common isotope of iron) is the last nuclear fusion reaction that is exothermic. This causes radioactive nickel to become the last element to be produced before collapse of a supernova leads to the explosive events that scatter this precursor radionuclide of iron abundantly into space.
       Iron is a relatively abundant element in the universe. It is found in the sun and many types of stars in considerable quantity. Iron nuclei are very stable. Iron is a vital constituent of plant and animal life, and is the key component of haemoglobin.

       The pure metal is not often encountered in commerce, but is usually alloyed with carbon or other metals. The pure metal is very reactive chemically, and rapidly corrodes, especially in moist air or at elevated temperatures. Any car owner knows this. Iron metal is a silvery, lustrous metal which has important magnetic properties.

Basic information about and classifications of iron:
   *Name: Iron
   *Symbol: Fe
   *Atomic number: 26
   *Atomic weight: 55.845 (2)
   *Standard state: solid at 298 K
   *CAS Registry ID: 7439-89-6 Group in periodic table: 8
   *Group name: (none)
   *Period in periodic table: 4
   *Block in periodic table: d-block
   *Colour: lustrous, metallic, greyish tinge
   *Classification: Metallic

History:
          Iron was discovered by Known since ancient times at no data in not known. Origin of name: from the Anglo-Saxon word "iron" or "iren" (the origin of the symbol Fe comes from the Latin word "ferrum" meaning "iron"). Possibly the word iron is derived from earlier words meaning "holy metal" because it was used to make the swords used in the Crusades..

         Iron was known in prehistoric times. Genesis says that Tubal-Cain, seven generations from Adam, was "an instructor of every artificer in brass and iron." Smelted iron artifacts have been identified from around 3000 B.C. A remarkable iron pillar, dating to about A.D. 400, remains standing today in Delhi, India. This solid pillar is wrought iron and about 7.5 m high by 40 cm in diameter. Corrosion to the pillar has been minimal despite its exposure to the weather since its erection.

         Sometime prior to the autumn of 1803, the Englishman John Dalton was able to explain the results of some of his studies by assuming that matter is composed of atoms and that all samples of any given compound consist of the same combination of these atoms. Dalton also noted that in series of compounds, the ratios of the masses of the second element that combine with a given weight of the first element can be reduced to small whole numbers (the law of multiple proportions). This was further evidence for atoms. Dalton's theory of atoms was published by Thomas Thomson in the 3rd edition of his System of Chemistry in 1807 and in a paper about strontium oxalates published in the Philosophical Transactions. Dalton published these ideas himself in the following year in the New System of Chemical Philosophy. The symbol used by Dalton for iron is shown below. [See History of Chemistry, Sir Edward Thorpe, volume 1, Watts & Co, London, 1914.]

Iron orbital properties:
   *Ground state electron configuration: [Ar].3d6.4s2
   *Shell structure: 2.8.14.2
   *Term symbol: 5D4
   *Pauling electronegativity: 1.83 (Pauling units)
   *First ionisation energy: 762.5 kJ mol-1
   *Second ionisation energy: 1561.9 kJ mol-1

Isolation:
        Isolation: it is not normally necessary to make iron in the laboratory as it is available commercially. Small amounts of pure iron can be made through the purification of crude iron with carbon monoxide. The intermediate in this process is iron pentacarbonyl, Fe(CO)5. The carbonyl decomposes on heatingto about 250°C to form pure iron powder.

                                    Fe + CO → Fe(CO)5 (250°C) → Fe + 5CO

       The Fe(CO)5 is a volatile oily complex which is easily flushed from the reaction vessel leaving the impurities behind. Other routes to small samples of pure iron include the reduction of iron oxide, Fe2O3, with hyrogen, H2.

      Nearly all iron produced commercially is used in the steel industry and made using a blast furnace. Most chemistry text books cover the blast furnace process. In essence, iron oxide, Fe2O3, is reduced with with carbon (as coke) although in the furnace the actual reducing agent is probably carbon monoxide, CO.

                                              2Fe2O3 + 3C → 4Fe + 3CO2

      This process is one of the most significant industrial processes in history and the origins of the modern process are traceable back to a small town called Coalbrookdale in Shropshire (England) around the year 1773.

Properties:
              Iron is a lustrous, ductile, malleable, silver-gray metal found in Group 8 of the periodic table. It is known to exist in four distinct crystalline forms (see allotropy). The most common is the α-form, which is stable below about 770°C, and has a body-centered cubic crystalline structure; it is often called ferrite. Iron is attracted by a magnet and is itself easily magnetized (see magnetism). It is a good conductor of heat and electricity. It displaces hydrogen from hydrochloric or dilute sulfuric acid, but becomes passive (loses its normal chemical activity) when treated with cold nitric acid.

Iron Uses:
           Iron is the most widely used of all the metals, accounting for 95% of worldwide metal production.[citation needed] Its low cost and high strength make it indispensable in engineering applications such as the construction of machinery and machine tools, automobiles, the hulls of large ships, and structural components for buildings. Since pure iron is quite soft, it is most commonly combined with alloying elements to make steel.

Commercially available iron is classified based on purity and the abundance of additives. Pig iron has 3.5–4.5% carbon and contains varying amounts of contaminants such as sulfur, silicon and phosphorus. Pig iron is not a saleable product, but rather an intermediate step in the production of cast iron and steel. The reduction of contaminants in pig iron that negatively affect material properties, such as sulfur and phosphorus, yields cast iron containing 2–4% carbon, 1–6% silicon, and small amounts of manganese. It has a melting point in the range of 1420–1470 K, which is lower than either of its two main components, and makes it the first product to be melted when carbon and iron are heated together. Its mechanical properties vary greatly and depend on the form the carbon takes in the alloy.

"White" cast irons contain their carbon in the form of cementite, or iron-carbide. This hard, brittle compound dominates the mechanical properties of white cast irons, rendering them hard, but unresistant to shock. The broken surface of a white cast iron is full of fine facets of the broken iron-carbide, a very pale, silvery, shiny material, hence the appellation.

In gray iron the carbon exists as separate, fine flakes of graphite, and also renders the material brittle due to the sharp edged flakes of graphite that produce stress concentration sites within the material. A newer variant of gray iron, referred to as ductile iron is specially treated with trace amounts of magnesium to alter the shape of graphite to spheroids, or nodules, reducing the stress concentrations and vastly increasing the toughness and strength of the material.

Wrought iron contains less than 0.25% carbon but large amounts of slag that give it a fibrous characteristic.It is a tough, malleable product, but not as fusible as pig iron. If honed to an edge, it loses it quickly. Wrought iron is characterized by the presence of fine fibers of slag entrapped within the metal. Wrought iron is more corrosion resistant than steel. It has been almost completely replaced by mild steel for traditional "wrought iron" products and blacksmithing.

Published by Ravindra.K(Mechanical Engineering)

Aluminium

Aluminium is a chemical element in the boron group with symbol Al and atomic number 13. It is silvery white, and it is not soluble in water under normal circumstances.Pure aluminium is a silvery-white metal with many desirable characteristics. It is light, nontoxic (as the metal), nonmagnetic and nonsparking. It is somewhat decorative. It is easily formed, machined, and cast. Pure aluminium is soft and lacks strength, but alloys with small amounts of copper, magnesium, silicon, manganese, and other elements have very useful properties. Aluminium is an abundant element in the earth's crust, but it is not found free in nature. The Bayer process is used to refine aluminium from bauxite, an aluminium ore.

Basic information about and classifications of aluminium:
   *Name: Aluminium
   *Symbol: Al
   *Atomic number: 13
   *Atomic weight: 26.9815386 (8)
   *Standard state: solid at 298 K
   *CAS Registry ID: 7429-90-5 Group in periodic table: 13
   *Group name: (none)
   *Period in periodic table: 3
   *Block in periodic table: p-block
   *Colour: silvery
   *Classification: Metallic

History & Production:
               From Latin alumen, meaning bitter salt. It derives its name from alum, KAl(SO4)2.12H2O, where the ancient Greek and Roman used it in medicine as an astringent and as a mordant in dyeing. In 1807, H. Davy, who was not able to isolate the metal, proposed the name alumium and later changed to aluminum.It was then modified again to the name aluminium. The impure metal was first isolated by H.C. Oersted using the reaction of dilute potassium amalgam on aluminium(III) chloride, in 1825. Nowadays, it can be obtained by electrolysis of alumina (Al2O3) dissolved in cryolite. The former can be obtained from bauxite mineral via the Bayer process, while cryolite has been largely synthesized since the natural mineral is rather rare. Aluminium is used for kitchen utensils, and a variety industrial and building materials. When alloyed with small amount of other metals such as magnesium, copper, manganese etc, it is used for construction of aircrafts and rockets. It is also used in coating applications in telescope mirrors, packages, etc.


Biological Role:
             Aluminium has no known biological role. It can be accumulated in the body from daily intake, and at one time was suggested as a potential causative factor in Alzheimer’s disease (senile dementia), although some studies have disproved this theory. Only a small amount of what we take in with our food is absorbed by our bodies. Foods with above average amounts of aluminium are tea, processed cheese, lentils and sponge cakes (where it comes from the rising agent). Cooking in aluminium pans does not greatly increase the amount in our diet except when cooking acid foods such as rhubarb. Some indigestion tablets are pure aluminium hydroxide.


Natural Abudance:
                 Aluminium is not found uncombined in nature, but is the most abundant metal in the Earth’s crust (8.1%) in the form of minerals such as bauxite and cryolite. Most commercially produced aluminium is obtained by the Bayer process of refining bauxite. In this process the bauxite is refined to pure aluminium oxide, which is mixed with cryolite and then electrolytically reduced to pure aluminium. A lot of energy is needed to extract it from its ores: however, this is worthwhile because it does not rust and is fairly easy to recycle.


Aluminium Properties:
              After iron, aluminium is now the second most widely used metal in the world. This is because aluminium has a unique combination of attractive properties. Low weight, high strength, superior malleability, easy machining, excellent corrosion resistance and good thermal and electrical conductivity are amongst aluminium’s most important properties. Aluminium is also very easy to recycle.

Weight:Aluminium is light with a density one third that of steel, 2.700 kg/m3.

Strength:Aluminium alloys commonly have tensile strengths of between 70 and 700 MPa. The range for alloys used in extrusion is 150 – 300 MPa. Unlike most steel grades, aluminium does not become brittle at low temperatures. Instead, its strength increases. At high temperatures, aluminium’s strength decreases. At temperatures continuously above 100°C, strength is affected to the extent that the weakening must be taken into account.

Linear expansion:Compared with other metals, aluminium has a relatively large coefficient of linear expansion. This has to be taken into account in some designs.

Machining:Aluminium is easily worked using most machining methods – milling, drilling, cutting, punching, bending, etc. Furthermore, the energy input during machining is low.

Formability:Aluminium’s superior malleability is essential for extrusion. With the metal either hot or cold, this property is also exploited in the rolling of strips and foils, as well as in bending and other forming operations.

Conductivity:Aluminium is an excellent conductor of heat and electricity. An aluminium conductor weighs approximately half as much as a copper conductor having the same conductivity.

Joining:Features facilitating easy jointing are often incorporated into profile design. Fusion welding, Friction Stir Welding, bonding and taping are also used for joining.

Reflectivity:Aluminium is a good reflector of both visible light and radiated heat.

Screening EMC:Tight aluminium boxes can effectively exclude or screen off electromagnetic radiation. The better the conductivity of a material, the better the shielding qualities.

Corrosion resistance:
        Aluminium reacts with the oxygen in the air to form an extremely thin layer of oxide. Though it is only             some hundredths of a (my)m thick (1 (my)m is one thousandth of a millimetre), this layer is dense and             provides excellent corrosion protection. The layer is self-repairing if damaged.

       Anodising increases the thickness of the oxide layer and thus improves the strength of the natural c                orrosion protection. Where aluminium is used outdoors, thicknesses of between 15 and 25 ¥ìm                      (depending on wear and risk of corrosion) are common.

      Aluminium is extremely durable in neutral and slightly acid environments.
      In environments characterised by high acidity or high basicity, corrosion is rapid.

      Further details are given in Corrosion Resistance.

Non-magnetic material:Aluminium is a non-magnetic (actually paramagnetic) material. To avoid interference of magnetic fields aluminium is often used in magnet X-ray devices.

Zero toxicity:After oxygen and silicon, aluminium is the most common element in the Earth’s crust. Aluminium compounds also occur naturally in our food.


Applications:
   *Low density and strength make aluminium ideal forconstruction of aircraft, lightweight vehicles, and
     ladders.An alloy of aluminium called duralumin is often usedinstead of pure aluminium because of its              improved properties.
   *Easy shaping and corrosion resistance make aluminiuma good material for drink cans and roofing                  materials.
   *Corrosion resistance and low density leads to its use for greenhouses and window frames.
   *Good conduction of heat leads to its use for boilers, cookers and cookware.
   *Good conduction of electricity leads to its use for overhead power cables hung from pylons(low density         gives it an advantage over copper).
   *High reflectivity makes aluminium ideal for mirrors, reflectors and heat resistant clothing for fire fighting.

                                                               Published by Ravindra.K(Mechanical Engineering)

Titanium

Titanium is a chemical element with the symbol Ti and atomic number 22 with the Group of 4.Titanium is a lustrous, white metal when pure. Titanium minerals are quite common. The metal has a low density, good strength, is easily fabricated, and has excellent corrosion resistance. The metal burns in air and is the only element that burns in nitrogen. It is marvellous in fireworks.
Titanium is resistant to dilute sulphuric and hydrochloric acid, most organic acids, damp chlorine gas, and chloride solutions. Titanium metal is considered to be physiologically inert.
Titanium is present in meteorites and in the sun. Some lunar rocks contain high concentrations of the dioxide, TiO2. Titanium oxide bands are prominent in the spectra of M-type stars.

Basic information about and classifications of titanium.
   *Name: Titanium
   *Symbol: Ti
   *Atomic number: 22
   *Atomic weight: 47.867 (1)
   *Standard state: solid at 298 K
   *CAS Registry ID: 7440-32-6 Group in periodic table: 4
   *Group name: (none)
   *Period in periodic table: 4
   *Block in periodic table: d-block
   *Colour: silvery metallic
   *Classification: Metallic

   Titanium is fairly hard (although not as hard as some grades of heat-treated steel), non-magnetic and a poor conductor of heat and electricity. Machining requires precautions, as the material will soften and gall if sharp tools and proper cooling methods are not used. Like those made from steel, titanium structures have a fatigue limit which guarantees longevity in some applications. Titanium alloys have lower specific stiffnesses than in many other structural materials such as aluminium alloys and carbon fiber.

   The metal is a dimorphic allotrope whose hexagonal alpha form changes into a body-centered cubic (lattice) β form at 882 °C (1,620 °F).The specific heat of the alpha form increases dramatically as it is heated to this transition temperature but then falls and remains fairly constant for the β form regardless of temperature.Similar to zirconium and hafnium, an additional omega phase exists, which is thermodynamically stable at high pressures, but is metastable at ambient pressures. This phase is usually hexagonal (ideal) or trigonal (distorted) and can be viewed as being due to a soft longitudinal acoustic phonon of the β phase causing collapse of (111) planes of atoms.

       Titanium was discovered by William Gregor at 1791 in England. Origin of name: named after the "Titans", (the sons of the Earth goddess in Greek mythology).
Titanium was discovered by the Reverend William Gregor in 1791, who was interested in minerals. He recognized the presence of a new element, now known as titanium, in menachanite, a mineral named after Menaccan in Cornwall (England). Several years later, the element was rediscovered in the ore rutile by a German chemist, Klaproth.

The pure elemental metal was not made until 1910 by Matthew A. Hunter, who heated TiCl4 together with sodium in a steel bomb at 700-800°C.

Compounds:
The +4 oxidation state dominates 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.

Star sapphires and rubies get their asterism from the titanium dioxide impurities 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 fabrics.

Titanium nitride (TiN), having a hardness equivalent to sapphire and carborundum (9.0 on the Mohs Scale), is often used to coat cutting tools, such as drill bits.It also finds use as a gold-colored decorative finish, and as a barrier metal in semiconductor fabrication.

Titanium tetrachloride (titanium(IV) chloride, TiCl4) is a colorless liquid which is used as an intermediate in the manufacture of titanium dioxide 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).

Isolation:

      Isolation: titanium is readily available from commercial sources so preparation in the laboratory is not normally required. In industry, reduction of ores with carbon is not a useful option as intractable carbides are produced. The Kroll method is used on large scales and involves the action of chlorine and carbon upon ilmenite (TiFeO3) or rutile (TiO2). The resultant titanium tetrachloride, TiCl4, is separated from the iron trichloride, FeCl3, by fractional distillation. Finally TiCl4 is reduced to metallic titanium by reduction with magnesium, Mg. Air is excluded so as to prevent contamination of the product with oxygen or nitrogen.

                         2TiFeO3 + 7Cl2 + 6C (900°C) → 2TiCl4 + 2FeCl3 + 6CO
                           
                                         TiCl4 + 2Mg (1100°C) → 2MgCl2 + Ti

Excess magensium and magneium dichloride is removed from the product bytreatment with water and hydrochloric acid to leave a titanium "sponge". This can be melted under a helium or argon atmosphere to allow casting as bars.

Titanium Orbital Properties:

Ground state Electron Configuration:  [Ar].3d2.4s2
Shell structure: 2.8.10.2
Term symbol: 3F2
Pauling electronegativity: 1.54 (Pauling units)
First ionisation energy: 658.8 kJ mol-1
Second ionisation energy: 1309.8 kJ mol-1

Production & Frabrication:

                The processing of titanium metal occurs in 4 major steps:reduction of titanium ore into "sponge", a porous form; melting of sponge, or sponge plus a master alloy to form an ingot; primary fabrication, where an ingot is converted into general mill products such as billet, bar, plate, sheet, strip, and tube; and secondary fabrication of finished shapes from mill products.

Because the metal reacts with oxygen at high temperatures it cannot be produced by reduction of its dioxide.Titanium metal is therefore produced commercially by the Kroll process, a complex and expensive batch process. (The relatively high market value of titanium is mainly due to its processing, which sacrifices another expensive metal, magnesium.) 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 TiCl4. This is condensed and purified by fractional distillation and then reduced with 800 °C molten magnesium in an argon atmosphere.

A more recently developed method, the FFC Cambridge process,may eventually replace the Kroll process. This method uses titanium dioxide powder (which is a refined form of rutile) as feedstock to make the end product which is either a powder or sponge. If mixed oxide powders are used, the product is an alloy manufactured at a much lower cost than the conventional multi-step melting process. The FFC Cambridge process may render titanium a less rare and expensive material for the aerospace industry and the luxury goods market, and could be seen in many products currently manufactured using aluminium and specialist grades of steel.

Common titanium alloys are made by reduction. For example, cuprotitanium (rutile with copper added is reduced), ferrocarbon titanium (ilmenite reduced with coke in an electric furnace), and manganotitanium (rutile with manganese or manganese oxides) are reduced.

                  2 FeTiO3 + 7 Cl2 + 6 C → 2 TiCl4 + 2 FeCl3 + 6 CO (900 °C)
                                 TiCl4 + 2 Mg → 2 MgCl2 + Ti (1100 °C)

About 50 grades of titanium and titanium alloys are designated and currently used, although only a couple of dozen are readily available commercially.The ASTM International recognizes 31 Grades of titanium metal and alloys, of which Grades 1 through 4 are commercially pure (unalloyed). These four are distinguished by their varying degrees of tensile strength, as a function of oxygen content, with Grade 1 being the most ductile (lowest tensile strength with an oxygen content of 0.18%), and Grade 4 the least (highest tensile strength with an oxygen content of 0.40%).The remaining grades are alloys, each designed for specific purposes, be it ductility, strength, hardness, electrical resistivity, creep resistance, resistance to corrosion from specific media, or a combination thereof.

The grades covered by ASTM and other alloys are also produced to meet Aerospace and Military specifications (SAE-AMS, MIL-T), ISO standards, and country-specific specifications, as well as proprietary end-user specifications for aerospace, military, medical, and industrial applications.

In terms of fabrication, all welding of titanium must be done in an inert atmosphere of argon or helium in order to shield it from contamination with atmospheric gases such as oxygen, nitrogen, or hydrogen. Contamination will cause a variety of conditions, such as embrittlement, which will reduce the integrity of the assembly welds and lead to joint failure. Commercially pure flat product (sheet, plate) can be formed readily, but processing must take into account the fact that the metal has a "memory" and tends to spring back. This is especially true of certain high-strength alloys.Titanium cannot be soldered without first pre-plating it in a metal that is solderable.The metal can be machined using the same equipment and via the same processes as stainless steel.

Titanium Properties:

           The atomic weight of titanium is 47.88. Titanium is lightweight, strong, corrosion resistant and abundant in nature. Titanium and its alloys possess tensile strengths from 30,000 psi to 200,000 psi (210-1380 MPa), which are equivalent to the strengths found in most of alloy steels.

Titanium is a low-density element (approximately 60% of the density of iron) that can be strengthened by alloying and deformation processing. Titanium is nonmagnetic and has good heat-transfer properties. Its coefficient of thermal expansion is somewhat lower than that of steels and less than half that of aluminum.

One of titanium’s useful properties is a high melting point of 3135°F (1725°C). This melting point is approximately 400°F above the melting point of steel and approximately 2000°F above that of aluminum.

Titanium can be passivated, and thereby exhibit a high degree of immunity to attack by most mineral acids and chlorides. Titanium is nontoxic and generally biologically compatible with human tissues and bones. The excellent corrosion resistance and biocompatibility coupled with strength make titanium and its alloys useful in chemical and petrochemical applications, marine environments, and biomaterial applications.

Titanium is not a good conductor of electricity. If the conductivity of copper is considered to be 100%, titanium would have a conductivity of 3.1%. From this it follows that titanium would not be used where good conductivity is a prime factor. For comparison, stainless steel has a conductivity of 3.5% and aluminum has a conductivity of 30%.

Electrical resistance is the opposition a material presents to the flow of electrons. Since titanium is a poor conductor, it follows that it is a fair resistor.


Applications:
  *Titanium alloys are used in aircraft (including helicopters), armor plating, naval ships, spacecraft and               missiles. Titanium alloys do not fatigue easily, are strong and are resistant to corrosion so they are perfect       for use in the above items.
  *Most titanium is converted to titanium oxide. This is the white pigment found in toothpaste, paint, paper         and some plastics. Cement and gemstones also contain titanium oxide. Fishing rods and golf clubs are also     made stronger through the use of titanium oxide.
  *Heat exchangers in desalination plants (which turn sea water into drinking water) are made from titanium        as it is resistant to corrosion in sea water.
  *Body piercings are generally made out of titanium. Titanium is perfect for this as it is easily colored and is       inert (will not react with other things).
  *Surgical instruments, wheelchairs and crutches are all made out of titanium for high strength and low               weight!
  *Dental implants are made with titanium. People with titanium dental implants can still go in an MRI                  machine!
  *Hip balls and joint replacements are made out of titanium and they can stay in place for around 20 years.
  *Many firearms (guns) are made from titanium as it is strong and lightweight.
  *The body of a laptop is often made from titanium.
  *Titanium is occasionally used in buildings.
Football helmet grills, tennis rackets, cricket helmets and bicycle frames are all made from titanium.



                                                                 Published by Ravindra.K(Mechanical Engineering)