Oxid hlinitý, známý také jako oxid hlinitý, je chemická sloučenina se vzorcem Al2O3.

Aluminium oxide (commonly referred to as “alumina”) is an aluminium compound with the formula Al2O3. It is one of several refractory aluminium oxide compounds. Naturally occurring as polymorph corundum crystals that produce gem-quality rubies and sapphires.

Bauxite is the primary source of alumina. This hard, inert material can be found in industrial ceramics as well as used as an abrasive. Reacting with acids and bases creates an aluminate solution.

What is alumina?

Aluminum oxide (Al2O3) is a chemical compound with the formula Al2O3. This white or near colorless crystalline substance occurs naturally as corundum gem quality (red for rubies and blue for sapphires) as well as in topaz, amethyst and quartz minerals. Aluminum oxide can also be produced industrially by mining bauxite – a sedimentary rock rich with aluminium minerals – then using its extracted alumina (or alum) for making aluminum metal and other applications.

Pure alumina has numerous applications, from use as an abrasive and refractory material, due to its high melting point and good electrical conductivity, to acting as an atmospheric barrier and protecting metallic aluminum against weathering due to reacting with atmospheric oxygen to form a protective passivation layer of pure alumina over its surface.

Alumina is a popular ingredient in ceramics due to its excellent thermal conductivity and low coefficient of expansion. Furthermore, alumina’s highly porous composition allows it to become even more porous through adding zirconia or silicon carbide – this makes alumina an attractive choice for use in furnace lining applications such as furnace linings.

Alumina’s main role is producing aluminum, an essential metal in transitioning towards a green economy. Aside from aluminum production, alumina is also widely used as an ingredient in ceramics production and catalyst support systems.

Due to its low melting point and excellent electrical conductivity, alumina is widely used as an insulator material. Furthermore, its properties make it valuable for use at very high temperatures found in modern high-tech furnaces.

Alumina can also be found in other industrial uses, including as an abrasive material due to its hardness and strength. Furthermore, its increased strength makes it useful in glass manufacturing to increase strength while preventing cracking; moreover, it serves as the main component in sandpaper as well as being an affordable replacement for industrial diamonds; due to its good wear resistance it’s even used as grinding and cutting tools.

What is the chemical formula of alumina?

Al2O3 is the chemical formula for alumina. This amphoteric substance combines two oxygen atoms into a tetrahedral structure that makes it resistant to both acid and bases; making alumina suitable for many industrial and commercial uses.

Engineered ceramics, or advanced or technical ceramics, use alumina as one of their key ingredients. Engineered ceramics typically involve mixing it with other materials to form composites that feature specific properties; one such alumina-zirconia composite has excellent impact strength and toughness at high temperatures – created by mixing equal proportions of both ingredients ranging between 10%-40% of each; this mixture is then quickly quenched on thin plates in order to maintain its tetragonal phase structure.

Alumina can be produced from various sources, but most alumina is obtained from an ore called bauxite through the Bayer process of extraction. This involves dissolving it into a solution of sodium hydroxide at very high temperatures to ensure all the alumina dissolves completely into solution.

Transported to aluminum plants for electrolysis into aluminum metal, any remaining alumina is known as “calcined” alumina and used to create various ceramics and refractories – spark plug insulators, integrated circuit packages, bone implants, as well as sparkplug insulators are just some examples. Sandpaper grits and grinding wheels made with this material, along with industrial furnace refractory linings made of this substance also play a vital role. In military applications alumina is also used for body armor that can withstand impacts caused by.50 caliber bullets.

Alumina can also be used in the manufacture of abrasives. A common form is produced by mixing it with silicon carbide or zirconia to increase hardness and resistance to wear; this alumina-zirconia mix abrasive has excellent properties for use in harsh environments, including those found during machining applications; its tetragonal structure withstands shocks and vibrations which would deform traditional abrasives.

What is the structure of alumina?

Alumina is one of the hardest engineered ceramic materials, renowned for its exceptional wear-resistance, thermal stability and chemical inertness. Alumina has long been used as the basis for autothermal reforming catalysts; additionally it is widely utilized in applications requiring high temperatures with minimal friction such as sliding bearings and seal rings.

Structure. Alumina can be described as a distorted close-packed hexagonal lattice composed of oxygen anions arranged as six-sided octahedra with aluminum cations attached by bonds to these oxygen anions occupying 2/3 of their faces, and Al3+ ions repelling each other leaving many empty octahedra that contribute to its high kinetic energy and thermal conductivity.

Aluminum metal production begins by extracting alumina from bauxite, found in topsoil from tropical laterites soils. Extraction and refining typically occurs using the Bayer process which involves dissolving it into caustic soda solution at 150-250degC and 20 atm of pressure, then filtering to produce red mud which is later ground into powder form for aluminum metal production.

Ground Alumina is then further refined and ground into micron-sized crystals before being calcined to produce pure aluminum oxide as feedstock for aluminum metal and technical ceramic production.

Alumina finds many uses in industry, from grinding and polishing metals, to producing fireclay and technical ceramics. Due to its abrasion resistance and durability, alumina ceramics have become essential parts of furnace liners, kiln linings, fiber insulation components and insulation products used in power generation and transmission equipment because of their low dielectric loss performance and high temperature performance.

Alumina can also be utilized in the production of glass, where transparent alumina ceramics serve as gas containers for high-pressure sodium-vapour streetlamps, while being widely employed in infrared detection windows.

What are the properties of alumina?

Aluminum oxide (alumina) is an extremely useful engineering ceramic due to its multiple beneficial properties, making it one of the more widely-used engineering ceramics. Alumina offers exceptional mechanical strength, hardness and wear resistance. Furthermore, its chemical inertness prevents corrosion in most environments while coming in various grades to suit various applications.

High-purity forms of alumina are used for various high-tech applications, including laser components, electro-optical devices, flow measurement instruments and sensors. In addition, X-ray equipment and applications where cleanliness and dimensional stability are key require them as well as other uses where cleanliness and dimension stability is key. Other grades of alumina may also be utilized industrially such as grinding wheels or sandpaper grits.

Alumina boasts remarkable electrical and thermal conductivity due to the hexagonal arrangement of its oxygen atoms, making it an excellent material for electrical insulation and heating applications. Alumina is commonly used in ceramic capacitors, spark plugs and integrated-circuit packages as well as for producing refractory linings for industrial furnaces.

Alumina stands out as an extremely durable material due to its ability to withstand high temperatures. While metals often weaken at high temperatures, alumina remains strong due to its low coefficient of thermal expansion – meaning its atoms move slowly when heated up.

Due to this property, alumina is highly resistant to corrosion in various environments, including acids, alkalis, and salt solutions at elevated temperatures. This makes alumina an ideal material choice for applications where chemicals may be present.

Most alumina is extracted from bauxite, a sedimentary rock containing large quantities of aluminium. Bauxite is mined worldwide from open-pit mines before being processed through the Bayer process (first developed for the abrasives industry in the early 20th century) to separate out aluminium from its mineral forms; activated, smelter grade and calcined grades are then produced, which are used in various industrial processes including surface electroplating, deburring and scaling; casting and mineral, glass crystal grinding applications.

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