Category: Chemistry Notes PPT

All You Need to Know about Bohrium

Bohrium is a synthetic chemical element represented using the symbol Bh. The atomic number of this metal is 107, and its name comes from the name of Niels Bohr, a physicist from Denmark. Niels Bohr, the leader in the field of quantum physics, has gained massive popularity for explaining atomic theory and structure. His innovative and useful work on atomic structure forms the basis of atomic physics. This synthetic element is not found abundantly in nature and is considered to be very solid and strong metal. Gottfried Münzenberg and Peter Armbruster discovered the metal in 1976.

It isn’t easy to study Bohrium because it has a very short life span. Though it was discovered officially at the Institute for Heavy Ion research located in Germany in the year 1981, it was only in 2000 that a team of experts was able to come up with large amounts of this element for examining its physical and chemical properties. Longest isotopes of Bohrium are barely able to pass the 60-second mark while the heaviest ones are to decay very slowly. It is the low stability of Bohrium that makes it efficient to be used even outside the scientific research arena.

Bohrium Properties

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This image depicts the symbol of Bohrium. 

Bh element is categorised as a transition metal. Claims regarding the production of Bohrium first surfaced in 1976 in the USSR. However, a definite and verified synthesis was only accomplished in 1981 by a team of scientists at GSI, Darmstadt in Germany. It is a harmful metal owing to its radioactive nature. This synthetically produced radioactive element decays very fast by way of the emission of α-particles. Bohrium melting point and boiling point are unknown. Other properties include:

• Solid key isotopes: 272Bh

• Relative atomic weight: 270 g/mol-1

• Atomic number: 107

• Group: 7

• Period: 7

• Electron configuration: (Rn) 5f14 6d5 7s2

• Form at room temperature: Solid

• Element Classification: Metal

One crucial point to be noted about Bohrium is that it is radioactive and is produced artificially. The metal consists of approximately 10 isotopes. The isotope 270Bh is the most stable with a half-life of roughly 61 seconds. Here, it is worth noting that the atomic mass of any synthetic transuranium metal is wholly based on its longest-lived isotope in the periodic table. Atomic weights need to be considered the way they are arranged because new isotopes with longer half-lives are likely to come up. Speaking of the periodic table, Bohrium comes in the d-block category. It is a transactinide element belonging to the 7th period. Major experiments carried out in the field of chemistry have come up with confirmations of Bohrium being a heavier homolog in comparison to the rhenium element found in the same group.

Bohrium Uses

Bohrium was produced for the first time in the year 1976 by a group of scientists indulged in experiments and research at the Dubna Joint Institute for Nuclear Research in Russia. Later, Gottfried Münzenberg and Peter Armbruster, along with their team, confirmed the appearance and the use of Bohrium in the year 1981. This happened at the Darmstadt Gesellschaft für Schwerionenforschung located in Germany. The element was manufactured artificially by bombarding the bismuth-209 target with chromium-54 ions. The most stable isotope of this metal in Bohrium-270 that has a half-life of around 61 seconds. It is the alpha decay procedure through which Bohrium decays and forms dubnium-266.

Since very few atoms of this metal have been made till date, presently, there are no special or exclusive uses of Bohrium out of the field of scientific research. Also, because it rarely exists in nature, Bohrium is just used by scientific researchers with no side effects and uses of the metal known to individuals and organisations.

Bohrium Sources

The sources of Bohrium are not known till date. It is a metal that is produced artificially and is made in minimal quantities. The team of scientists at Dubna created this element by bombarding the target bismuth-204 with the heavy ions of chromium-54. You can do it by using a fast rotating cylinder covered with a fragile coating of bismuth-204. The chamber was used in the form of a target. It was barraged utilising a stream of the ions of chromium-54 ablaze obliquely. The whole procedure gave scientists the chance of getting a glimpse of the whole now metal for approximately 0.0002 seconds.

The group-13 elements present in the modern periodic table are much better known as the members of the Boron family. The members of the boron family exhibit a wide range of both physical and chemical properties. The electronic configuration of the elements of the boron family can be given by ns2 np1.

The members of this family include Boron (B), Gallium(Ga), Aluminium (Al), Thallium (Tl), Indium (In) and including a radioactive synthetic element, Nihonium (Nh), which was formerly known as ununtrium.

Properties of Boron Family

The chemical and physical properties of the boron family members are found to follow a specific trend. Also, the properties of boron vary from the other members of the group because of the absence of the d orbital and its smaller size. These deviations in the boron properties lead to the classification of boron’s anomalous properties.

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Trends in Properties of Members of the Boron Family

Let us look at the trends in properties of the boron family members listed as follows:

• The boron family members react with halogens to produce bromides, iodides, and tri-chlorides. All these halides are covalent in nature and hydrolyzed in water.

• The compounds of these elements, such as octahedral [M(H2O)6]3+ (where M denotes a member of the boron family) and tetrahedral [M(OH)4]–, exists in an aqueous medium.

• These trihalides are strong Lewis acids due to the deficiency of electrons.

• The metallic character of the boron increases down the group while we move from boron to thallium.

• First, the electronegativity of the elements decreases down the group from B to Al and, after that, increases marginally due to the discrepancies existing in the atomic size of the elements.

Anomalous Properties of Boron

Because of the unavailability of d-electrons and their smaller size, boron is found to exhibit properties that are in contrast to the other elements associated with the boron family. These properties are referred to as anomalous properties of boron. A few of these anomalous properties can be listed as follows:

• Except for boron, the compounds of the elements of the boron family such as octahedral [M(H2O)6]3+ (where M denotes the member of boron family), and tetrahedral [M(OH)4]– exists in an aqueous medium.

• Due to the absence of d orbitals, the maximum covalency of boron is 4.

• While the rest of the family are post-transition metals, boron is given as a metalloid.

• Hydroxides and boron oxides are of an acidic nature, while, on the other hand, the other elements in the boron family form hydroxides and oxides of an amphoteric nature.

Characteristics of Boron Family

The boron group is notable for its trends in the electron configuration and a few of its characteristics of the elements. Boron varies from the other group members in its refractivity, reluctance, and hardness to participate in metallic bonding. One of the examples of a trend in reactivity is given as the tendency of boron to form reactive compounds with hydrogen.

While located in the p-block, the party is notorious for the octet violation rule of boron and (to a lesser extent) aluminium by its members. These elements can place only six electrons (in 3 molecular orbitals) onto the valence shell. All the members of this group are characterized as trivalent.

Chemical Reactivity

Hydrides

Most of the elements found in the boron group show increasing reactivity as the elements get heavier in the atomic mass and higher in the atomic number. Boron, which is the first element in the group, is normally unreactive with several elements except at high temperatures, though it is capable of producing several compounds with hydrogen, at times called boranes. The simplest borane is either B₂H₆ or diborane. B₁₀H₁₄ is another example.

Oxides

All the boron-group elements are much known to produce a trivalent oxide, involving two atoms of the element, which is covalently bonded with three oxygen atoms. These elements exhibit an increasing pH trend (from acidic to basic).

Toxicity

All the elements in the boron group can be said to be toxic, given a high enough dose. A few of them are only toxic to animals, some only to plants, and a few to both.

An example of boron toxicity: It has been noticed to harm barley in concentrations exceeding 20 mm. The boron toxicity symptoms are numerous in plants. As per the research, they include decreased shoot and root growth, reduced cell division, inhibition of photosynthesis, decreased production of leaf chlorophyll, reduced proton extrusion from roots, lowering of stomata conductance, and the deposition of suborgin and lignin.

Aluminium does not give a prominent toxicity hazard in smaller quantities, but it is slightly toxic in very large doses. Gallium is not considered to be toxic, although it may contain some minor effects. Indium is not toxic and can be handled with approximately similar precautions as gallium, but a few of its compounds are slightly to moderately toxic.

There is hardly any industry in the world that is not dependent on chemical compounds, and alcohol is the leader of the lot. There are many types of alcohol present in the world and thus there are various uses of this chemical substance. It is used for heating, cooling, production, cleaning, mixing, and many other industries. The development in this segment of science is going on at such a rapid rate that we are seeing more and more alcohol-based products coming up in the market which is being used for manufacturing.  The most popular alcohol in terms of industrial usage is butyl alcohol. 

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Types of Butyl Alcohol 

Tba- Tert Butyl Alcohol 

Tba alcohol is one of the simplest types of alcohol. It falls under the umbrella of butyl alcohol isomers. It is among the four major types in butyl. This colourless liquid is used as a solvent and cleaner. It is also used as a base for compounds like methanol, ethanol, and tert butyl hydroxide.

Secondary Butyl Alcohol

Known as sec-butyl, this is another alcohol isomer in this category. It is derived from the two isomers of butane. This compound has got several uses as well. It works on the lines of tert alcohol and has got similar characteristics.  

Isobutyl 

This is the third type of normal butyl alcohol. It is a colourless liquid and gives out a strong ester smell. It has got a lot of industrial uses which are explained below. 

Tertiary Butyl Alcohol

It is the last isomer in this category. This compound is used as solvents and denaturing agents. It is made using isobutylene, which is, in turn, developed using isobutyl.  

Industrial Usage of Butyl Alcohol

Butyl alcohol is used as a biofuel due to its advantages over traditional bioethanol. It is also being tested for completing the processes of fermentation and separation in a waste management refinery. 

Scientists are exploring the benefits of butyl alcohol in terms of it being used as the fuel of the future. The idea is to develop this fuel as an algae-based energy source. It will be replenishable and will have less carbon emission as compared to other fuels. It is being seen as a direct substitute for gasoline as well. Tba Tert Butyl alcohol is being used as a substitute for gasoline in some automobiles for its inherent qualities of low water solubility. 

Tert butyl cyclohexanol is used by manufacturers while making air fresheners and fragrance products. Apart from that this category of Butyl alcohol is also used to make food additives, colour paints, and washing products.  It is also used as an inert ingredient in making pesticides. 

Scientists and manufacturers are coming up with new usage of this alcohol every day. With the advancement of research and experiments, this category of alcohol is going to gain more importance in the commercial manufacturing segment. 

Pricing of Butyl Alcohol

The Asia Pacific region faced a heavy shortage of this category of butyl alcohol in the last quarter of 2020. The industry faced a heavy crunch of this chemical due to the ban on the import and export for the pandemic. The tert butyl alcohol price took a bit of hike in the last segment of the year and it was rated 90 Rs/ltr. 

Europe faced a crunch of this chemical in the Oct-Nov 2020 period. However, they did not face a hike in the prices of this chemical because they had enough storage plus they have an enormous capacity of producing this category of alcohol. 

The USA had a steady market for this category of alcohol. They did not face any crunch even in the year 2020. The USA has the biggest reserves for this as well as they have a good production capacity as well. 

The world is still going to face a shortage of Butyl alcohol, especially in the Asia-pacific region. The second wave of COVID-19 has hit several countries and the restrictions are coming back. The production is going to take a toll again and the industries have not stored it in good amounts as well. This region has been completely dependent on the import of para-tertiary butyl cyclohexanol and tba tertiary butyl alcohol. 

Did You Know? 

The biggest use of alcohol is for intoxicating beverages. Beers, whiskeys, and other types of beverages are made using the alcoholic compound known as ethanol. There are around 30 variants of this compound and they have uses that cannot ever be limited to a particular number. New uses of this chemical compound are being discovered every other day. The alcoholic beverage industry is the biggest consumer of this compound. Apart from that, many scientific processes can never be completed without the help of this compound. 

Calcium oxide has been known since ancient times. The Roman writer Cato the Elder (234 – 149 BC) mentioned one method of making the compound in 184 BC. By the early fifteenth century, many Europeans were using calcium oxide (generally referred to as lime) in the construction of buildings. The Scottish chemist Joseph Black (1728–1799) performed some of the earliest scientific studies of calcium oxide. He found that when the compound is exposed to air, it combines with carbon dioxide to produce calcium carbonate.

Calcium oxide is a chemical compound that has colourless, odourless properties and was used since the early times. The formula for calcium oxide is CaO. It is an amorphous substance that is in a crystalline or powdery solid form. Calcium oxide is also called quick lime, caustic lime or burnt lime. In its pure form, calcium oxide is white or off grey in colour. On the other hand, it is yellow or brownish in colour in the presence of impurities, such as iron, magnesia, silica or alumina.  Calcium oxide also exists in the colours reds and muted browns. 

The main primary elements which constitute calcium oxide are calcium and oxygen.It is prepared by heating calcium carbonate (e.g. limestone) in a distinct lime kiln to about 500°C to 600°C, decomposing it into the oxide and carbon dioxide.This process of obtaining burnt lime is called calcification. It starts with decomposing the natural components at high temperatures while maintaining they do not reach the melting point. This process is done by heating them at temperatures ranging from 1070 degrees Celsius to 1270 degrees celsius. 

CaCO₃ → CaO + CO₂

Calcium oxide is used in industries that make porcelain and glass. It is also used for purifying sugar, in preparing bleaching powder, calcium carbide, and calcium cyanamide. Its other uses are in water softeners, mortars, and cement. 

Calcium oxide (CaO), is generally known as quicklime or burnt lime, it is a commonly used chemical compound. It is solid at room temperature. The broadly used word lime means calcium-containing inorganic materials, in which oxides and hydroxides of calcium, magnesium, aluminium, silicon, and iron are present. By contrast, quicklime precisely applies to the single chemical compound calcium oxide. But commercial lime frequently contains impurities. 

Calcium oxide is also widely used in medicines and pesticides. Due to alkali being available in affordable amounts, calcium oxide is one of the essential ingredients in making caustic soda. It is also used in the manufacturing of steel, paper, and cement. 

The second most vital use of calcium oxide is in pollution control devices. Smoke that ejects from any industry’s smokestack contains high amounts of sulfur and nitrogen. When sulfur and nitrogen are combined with water, it morphs into new substances, such as nitric acid and sulphuric acid. 

To prevent such harmful chemical compositions from getting in contact with nature, machines called scrubbers are installed. These devices have large compounds of calcium oxide which help in neutralising the high amounts of sulphuric acid and nitric acid.  

Benefits Of Calcium In The Human Body

Calcium is mainly needed for building strong bones and maintaining good oral health. 99% of calcium is found in bones and teeth. It is essential for the growth, development, and maintenance of the body. Calcium also helps in maintaining the activity of the blood and ensuring its smooth flow in the whole body. 

The presence of adequate calcium in the body results in lower blood pressure, high amounts of energy and promotes effective rejuvenation of the skin and bones. It also helps in muscle contraction and improves cholesterol functioning. 

Interesting Facts about Calcium Oxide

• Calcium oxide is frequently used to “lime” lake waters that have been acidified by acid rain; it reacts with them and neutralizes acids in the lake. It is also formed when nitric and sulphuric acid in acid rain is carried to earth by rain, sleet, snow, and other methods of precipitation.

• When calcium oxide is heated near its melting point, it gives off a bright white light. In the years before electricity was discovered for lighting, particularly during the second half of the 19th century it was used as a limelight source, heated lime was used to create the bright lights required to illuminate stage productions.

• Because it was thought to increase the speed in the decomposition of soft tissue, quicklime has historically been used in the funeral of diseased animals and humans. For instance, the bodies of plague victims in London in 1666 were instructed to be buried in quicklime. 

Health Risk

Contact with calcium oxide can cause injury to the skin, nose, eyes, and respiratory system. People who use the product in their line of work or at home for (garden purposes) for example, people who are working must be extremely cautious not to breathe in, swallow, or otherwise come into contact with the chemical. If such contact occurs, it should be washed off completely with water and asked for medical assistance.

Conclusion

This is all about calcium oxide and its properties. Learn how it is used in daily lives and modern industries. Understand its properties and benefits well to increase your conceptual knowledge about this oxide. 

Carbon black is a substance that is an intense black substance, which belongs to the carbon family. The carbon black structure is of a high surface-area-to-volume ratio, making it light and durable. It is obtained through the unfinished combustion process of heavy petroleums like coal tar, ethylene cracking tar, etc. 

In the form of carbon black pigment, i.e., being insoluble in water, carbon black can be used in almost all industries. We shall discuss it in detail in the subsequent sections, along with other topics like carbon black uses, properties, and structure.

What is Carbon Black?

Carbon black is a form of amorphous carbon which exists in various types, such as thermal black, furnace black, lamp black, and acetylene black. In its purest form, it exists in a very fine powder state. It exists in a paracrystalline form of carbon, i.e., it doesn’t have a lustre like that of a crystal and has varied disordered ordering of atoms. Let us see the structure in a little more detail.

Carbon Black Structure

Carbon black has a paracrystalline construction. A paracrystalline structure has a liquid crystal-like ordering, i.e., short-range and medium range. However, there exists no long-range ordering. Thus, the material is neither fully amorphous nor fully crystalline. The disordered ordering, i.e., the location of atoms in the lattice, is helpful in understanding polymers. 

Properties of Carbon Black

The properties of this amorphous carbon vary within types of carbon black.  In general, carbon blacks have the following properties:

• They exist in powder form and are odourless.

• They have a high melting and high boiling point.

• Specific gravity varies between 1.8 to 2.18

• It is insoluble in water and is hence called hydrophobic.

• It is highly combustible when it comes in contact with oxidizers like nitrates, chlorates, etc. It can form explosive mixtures in the air.

• Carbon black conductivity varies with the manufacturing process. When made under perfect conditions, it can offer high electric conductivity. 

• Particle Size: A smaller particle size ensures an intense black colour. However, the dispersion rate becomes less.

• Structure Size: An increase in structure size increases the conductivity of the carbon type. The blackness of the material degrades, and the dispersibility increases. 

Carbon Black Manufacturing Process

Carbon black is a product of burning petroleum products in an insufficient supply of air. The process is often called thermal decomposition and is used in hydrocarbons in industrial manufacturing. 

Nowadays, the Furnace Black Process is the most commonly employed procedure in the industry. In this process, the raw material petroleum oil or coal oil is partially combusted in a high heat supply via a furnace. The conditions are highly controlled to ensure quality.

Another manufacturing process is the channel process which uses partial charring of natural gas in a channel H-shaped steel.

The types of method and material used in the manufacturing process determine the properties and applicability of the carbon black obtained. 

Carbon Black Uses

• It is used in the food and packaging industry.

• Carbon Black absorbs the UV radiations. Hence it is mixed in polypropylene to prevent degradation.

• The high carbon black conductivity allows it to provide electrical conductivity to polymers.

• It is used in radar-absorbent materials to facilitate RF radiation-absorbing.

• Laser printers, toners, inks, paints also use different types of carbon black.

• They are also employed in the electronic industry. 

•  It is used as a filler in adhesives, films, plastics, and paints.

• Carbon black obtained from vegetables is used for food colouring.

• Some of the most common uses of carbon black are present in the automobile industry. The carbon black pigment is used here on tires. It acts as a reinforcer that helps to control the heat of the tire. This gives it durability and sustainability.

Fun Fact

Carbon black structure reflects little to no light, and hence it is black. Historically, it was procured after charring organic substances like bones, wood, etc. The product obtained was named after the material it was produced from. For instance, ivory black was created by combustion bones or ivory, while vine black was obtained via charing grape vines and stems. The uses of carbon black thus obtained included painting. 

Carbides are inorganic or organic chemical compounds that include carbon in an anionic form. The various elements that form carbides are; calcium, boron, silicon, and aluminium. Let us discuss the carborundum meaning, Silicon carbide (SiC), also referred to as carborundum, is a silicon-carbon semiconductor. 

 

Moissanite, an exceptionally rare mineral, is found in nature. Since 1893, synthetic SiC powder has been mass-produced as an abrasive. Sintering can bind silicon carbide grains together to form very hard ceramics, which are commonly used in applications requiring high endurance, such as car brakes, car clutches, and bulletproof vest ceramic plates. About 1907, silicon carbide was first used in electronic applications such as light-emitting diodes (LEDs) and detectors in early radios. 

 

SiC is a semiconductor material that is used in semiconductor electronics devices that work at high temperatures, high voltages, or both. The Lely method can be used to grow large single crystals of silicon carbide, which can then be cut into synthetic moissanite gems.

Carborundum Structure

 

There are about 250 different crystalline types of silicon carbide. Silicon carbide in a glassy amorphous shape is formed by pyrolysis of preceramic polymers in an inert atmosphere. Polytypes are a wide family of related crystalline structures that define SiC polymorphism. They are two-dimensional variants of the same chemical compound that vary in the third dimension. As a result, they can be thought of as layers stacked in a specific order.

 

The most popular polymorph is alpha silicon carbide (SiC), which is produced at temperatures above 1700 °C and has a hexagonal crystal structure. At temperatures below 1700 °C, the beta modification (SiC) with a zinc blende crystal structure (similar to diamond) is formed. The beta form has had few commercial applications until recently, but due to its higher surface area than the alpha form, it is now gaining popularity as a support for heterogeneous catalysts.

Carborundum Formula

Carborundum formula (Silicon carbide chemical formula) is SiC. Its molar mass is 40.10 g/mol and its molecular formula is CSi. It’s a simple compound with a triple bond connecting the carbon atom to the silicon atom, leaving all atoms with a positive and negative charge. However, rather than being ionic, the bonding between them is primarily covalent. Solid silicon carbide comes in a variety of crystalline shapes, the most common of which is the hexagonal crystal structure.

Properties of Carborundum

• SiC is colourless in its purest form. Iron impurities give the industrial product a brown to black hue. 

• The crystals’ rainbow-like lustre is caused by the thin-film intrusion of a silicon dioxide passivation layer that forms on the surface.

• Silicon carbide is useful for bearings and furnace parts because of its high sublimation temperature (approximately 2700 °C). At any known temperature, silicon carbide does not melt.

• Chemically, it is also very inert. 

• Its high thermal conductivity, high electric field breakdown resistance, and high maximum current density make it more promising than silicon for high-powered devices, and there is currently a lot of interest in its use as a semiconductor material in electronics. 

• SiC also has a very low coefficient of thermal expansion and no phase transitions that trigger thermal expansion discontinuities.
  

Silicon Carbide as a Semiconductor Material

Silicon carbide is a semiconductor that can be doped with nitrogen or phosphorus to make it n-type and beryllium, boron, aluminium, or gallium to make it p-type. Strong doping with boron, aluminium, or nitrogen has been used to achieve metallic conductivity.

 

At the same temperature of 1.5 K, superconductivity was observed in 3C-SiC:Al, 3C-SiC:B, and 6H-SiC:B. However, there is a significant difference in magnetic field activity between aluminium and boron doping: SiC:Al, like Si:B, is a type-II compound. SiC:B, on the other hand, is a type-I compound. It was discovered that Si sites are more critical for superconductivity in SiC than carbon sites. In SiC, boron replaces carbon, while Al replaces Si sites. As a result, Al and B “see” different worlds, which may explain why SiC has different properties.

Occurrence of Carborundum in Nature

Moissanite is only present in trace amounts in some forms of meteorites, as well as corundum deposits and kimberlite. Almost all-silicon carbide sold in the world is synthetic, like moissanite jewellery. Dr. Ferdinand Henri Moissan discovered natural moissanite as a small portion of the Canyon Diablo meteorite in Arizona in 1893, and the substance was named after him in 1905. Moissan’s discovery of naturally occurring SiC was initially questioned due to the possibility that his sample had been tainted by silicon carbide saw blades that were already on the market at the time.

 

Silicon carbide is extremely popular in space, despite its rarity on Earth. It’s a common type of stardust found in the vicinity of carbon-rich stars, and examples have been discovered in pristine conditions in primitive (unaltered) meteorites. The beta-polymorph of silicon carbide is almost exclusively present in space and in meteorites. The isotopic ratios of carbon and silicon in SiC grains found in the Murchison meteorite, a carbonaceous chondrite meteorite, showed anomalous isotopic ratios, suggesting that these grains originated beyond the solar system.

Production of Carborundum

Moissanite is a rare mineral, and most silicon carbide is synthetic. Silicon carbide is used as an abrasive, a semiconductor, and a gem-quality diamond simulant. Combining silica sand and carbon in an Acheson graphite electric resistance furnace at a high temperature, between 1,600 °C (2,910 °F) and 2,500 °C (4,530 °F), is the easiest way to make silicon carbide. By heating in the excess carbon from the organic material, fine SiO₂ particles in plant material (e.g. rice husks) can be converted to SiC. By heating with graphite at 1,500 °C (2,730 °F), silica fume, a byproduct of making silicon metal and ferrosilicon alloys, can be converted to SiC.

 

The purity of the substance produced in the Acheson furnace varies depending on how far it is from the graphite resistor heat source. The purest crystals are colourless, pale yellow, and green, and they are located nearest to the resistor. At a greater distance from the resistor, the colour changes to blue and black, and the darker crystals are less pure. The electrical conductivity of SiC is affected by impurities such as nitrogen and aluminium.

Uses of Carborundum

Abrasive and Cutting Tools

Silicon carbide, a common abrasive in modern lapidary due to its toughness and low cost, is a popular abrasive in the arts. It is used in abrasive machining processes such as grinding, honing, water-jet cutting, and sandblasting because of its hardness. Sandpapers and skateboard grip tape are made from silicon carbide particles laminated to paper.

 

In 1982, a composite of aluminium oxide and silicon carbide whiskers was discovered to be extremely solid. It took just three years to transform this lab-created composite into a commercial product. The first commercially available cutting tools made from this alumina and silicon carbide whisker-reinforced composite hit the market in 1985.

In Making Structural Material

Silicon carbide was investigated in many high-temperature gas turbine research programmes in Europe, Japan, and the United States during the 1980s and 1990s. The parts were designed to be used in place of nickel superalloy turbine blades or nozzle vanes. However, none of these ventures resulted in a commercially viable product, owing to its low impact resistance and fracture toughness.

 

Silicon carbide, like other hard ceramics (such as alumina and boron carbide), is used in composite armour (such as Chobham armour) and in bulletproof vest ceramic plates. Pinnacle Armour used silicon carbide discs in their Dragon Skin armour. The phenomenon of abnormal grain development, or AGG, can help improve the fracture toughness of SiC armour. Similar to whisker reinforcement, the growth of abnormally long silicon carbide grains can help to impart a toughening effect by crack-wake bridging. Silicon nitride has been shown to have similar AGG-toughening effects (Si3N4).

 

In high-temperature kilns, such as those used for firing ceramics, glass fusing, or glass casting, silicon carbide is used as a support and shelving material. Traditional alumina kiln shelves are significantly heavier and less sturdy than SiC kiln shelves.

 

In December 2015, it was reported that infusing silicon carbide nanoparticles into molten magnesium could create a new strong and plastic alloy suitable for use in aeronautics, aerospace, automobiles, and microelectronics.

In Making Automobiles Parts

High-performance “ceramic” brake discs are made of silicon-infiltrated carbon-carbon composite, which can withstand extreme temperatures. The silicon in the carbon-carbon composite reacts with the graphite to form carbon-fibre-reinforced silicon carbide (C/SiC). Some road-going sports cars, supercars, and other luxury cars, such as the Porsche Carrera GT, Bugatti Veyron, Chevrolet Corvette ZR1, McLaren P1, Bentley, Ferrari, Lamborghini, and other specific high-performance Audi cars, use these brake discs. Sintered silicon carbide is also used in diesel particulate filters. Friction, emissions, and harmonics are all reduced by using it as an oil additive.

Electronic Elements

SiC’s voltage-dependent resistance was discovered early on, and columns of SiC pellets were connected between high-voltage power lines and the earth. The SiC column will conduct when a lightning strike to the line increases the line voltage enough, allowing the strike current to flow harmlessly to the earth rather than to the power line. The SiC columns showed considerable conductivity at standard power-line operating voltages, necessitating their placement in series with a spark gap. As lightning increases the voltage of the power line conductor, the spark gap is ionised and made conductive, essentially connecting the SiC column to the power conductor and the ground. Spark gaps in lightning arresters are unreliable, failing to strike an arc when needed or failing to switch off afterwards, the latter due to material failure or contamination by dust or salt in the latter case. The use of SiC columns in lightning arresters was originally intended to reduce the need for a spark gap. Gapped SiC arresters were sold under the GE and Westinghouse brands, among others, for lightning safety. No-gap varistors that use zinc oxide pellet columns have essentially replaced the gapped SiC arrester.

LEDs

In 1907, silicon carbide was used to discover the phenomenon of electroluminescence, and the first commercial LEDs were made of SiC. In the 1970s, the Soviet Union produced yellow 3C-SiC LEDs, and in the 1980s, the world produced blue 6H-SiC LEDs.

 

When a different material, gallium nitride, showed 10–100 times brighter emission, LED development was quickly halted. This efficiency disparity is attributable to SiC’s unfavourable indirect bandgap, while GaN’s direct bandgap favours light emission. SiC, on the other hand, remains a significant LED component because it is a common substrate for growing GaN devices and also serves as a heat spreader in high-power LEDs.

In the Production of Graphene

Silicon carbide can be used to make graphene because of its chemical properties, which encourage graphene to develop epitaxially on the surface of SiC nanostructures. When it comes to manufacturing graphene, silicon is mainly used as a substrate on which the graphene is grown.

 

However, there are many methods for growing graphene on silicon carbide that can be used. A SiC chip is heated under vaccum with graphite in the confinement controlled sublimation (CCS) growth process. The vacuum is then gradually released in order to regulate the growth of graphene. The graphene layers generated by this method are of the highest quality. However, other methods have been documented to produce the same result.

 

Another method for producing graphene is to thermally decompose SiC in a vacuum at a high temperature. However, this process produces graphene layers with smaller grains inside the layers. As a result, attempts have been made to increase graphene consistency and yield. Ex-situ graphitization of silicon terminated SiC in an argon atmosphere is one of these techniques. This method has been shown to produce graphene layers with larger domain sizes than those obtained by other methods. This new method of producing higher-quality graphene could be very useful in a variety of technical applications.

 

When it comes to understanding how and when to use these graphene production methods, the majority of them primarily produce or grow graphene on SiC in a growth-friendly environment. Because of the thermal properties of SiC, it is most commonly used at higher temperatures (such as 1300° C). 

 

However, such procedures have been performed and studied that could theoretically lead to graphene manufacturing methods that use lower temperatures. This new method of graphene growth has been observed to generate graphene in a temperature setting of about 750 degrees Celsius. This approach combines various techniques such as chemical vapour deposition (CVD) and surface segregation. In terms of the substrate, the technique would include coating a SiC substrate with thin transition metal films. After rapid heat treatment, the carbon atoms at the surface interface of the transition metal film become more abundant, yielding graphene. And it was discovered that this process resulted in graphene layers that were more consistent around the substrate surface.

Jewels of Carborundum

After the mineral name, silicon carbide is called “synthetic moissanite” or simply “moissanite” as a gemstone used in jewellery. Moissanite is similar to diamond in many ways: it is transparent and hard (9–9.5 on the Mohs scale, versus 10 for diamond), and it has a refractive index of 2.65–2.69. (compared to 2.42 for diamond). Moissanite is a little tougher than cubic zirconia. Moissanite, unlike diamond, can be highly birefringent. As a result, moissanite jewels are cut along the crystal’s optic axis to reduce birefringent effects. It is lighter than diamond and much more heat resistant. As a result, the stone has a higher lustre, sharper facets, and is more durable. 

 

Since moissanite is unaffected by temperatures up to 1,800 °C (3,270 °F), loose moissanite stones, like diamonds, can be inserted directly into wax ring moulds for lost wax casting. Moissanite has gained popularity as a diamond replacement, and it is possible that it would be mistaken for diamond because its thermal conductivity is the closest to diamond of any substitute. While several thermal diamond-testing instruments can’t tell the difference between moissanite and diamond, the gem is distinguished by its birefringence and a faint green or yellow fluorescence under ultraviolet light. Moissanite also has curved, string-like inclusions, which diamonds do not have.

Did You Know?

• Silicon carbide gets its hardness and strength from tetrahedral silicon and carbon structures kept together by tight covalent bonds in its crystal lattice.

• On the other hand, silicon carbide fibres have been linked to lung fibrosis, lung cancer, and probably mesothelioma. Fibrous silicon carbide can cause cancer in humans.

• Another name of synthetic moissanite is carborundum stone.
  

Conclusion:

This article contains everything one needs to know about Carborundum. Students can study from this to prepare for exams.