氧化铝玻璃

Alumina glass is an extremely chemical and thermal resistant glass material with high strength, low electric conductivity levels and extreme hardness (9 Mohs scale). Alumina is often found as part of the composition of advanced ceramic products like night vision devices or heat-seeking missile nose cones.

It’s made from aluminum oxide

Alumina is an extremely hard material, second only to diamond in terms of hardness. Due to its durability, alumina makes for an excellent ingredient in glass-making and ceramic production, particularly technical or advanced ceramics designed for harsh environments and needing superior pressure resistance as well as wear resistance. Alumina can also be combined with other materials to produce different types of glass and ceramic products.

Scientists have been conducting studies to increase the durability of aluminum oxide. They have tried mixing it with metal oxides like those of tungsten and scandium in order to add strength and ductility; ultimately creating an entirely new glass type which has proven both chemically resistant as well as thermal shock proof – making it suitable for armored windows, night vision devices and heat-seeking missile nose cones.

Researchers discovered that alumina glass could be made with similar techniques to traditional silica glasses, yet has greater plasticity due to being an amorphous material with gaps in its atomic structure allowing energy dissipation by moving around without cracking; traditional silica glasses on the other hand tend to be brittle because their atoms cannot move freely under stress and instead break apart into fragments.

As part of its manufacturing process, alumina powder is spray-granulated with polyvinyl alcohol to form a green body which can then be transformed into various types of glass and ceramics. Granules then undergo heat treatments either via dry pressing or injection casting and can then be further processed through sanding and molding for additional processing steps before finally being subjected to annealing treatment which increases hardness and toughness in alumina glass products.

Alumina is an increasingly popular additive in glass production due to its ability to increase mechanical strength and thermal shock resistance. Furthermore, its insoluble nature means it remains free of acidic conditions while its wear-resistance makes it suitable for containers or high-intensity discharge lamps.

It’s brittle

Glass is notoriously fragile because its mechanical energy cannot dissipate effectively when deformed, instead being concentrated at microscopic defects and creating localized concentrations of stress and sharp cracks that propagate quickly and lead to shattering. Alumina glass offers potential solutions by blunting crack tip propagation as they spread, lessening their chances of fracture and ultimately leading to better glass strength and shatter resistance.

Alumina offers many desirable properties that make it a desirable component in glass production, including its ductility. Alumina increases tensile strength, surface tension and luster as well as lengthening working range, decreasing devitrification tendencies and increasing resistance to acid attack. Furthermore, it features low vapor pressure, expansion rate and is relatively free from impurities compared to alternative materials used.

Though expensive, adding alumina to a glass formulation for its many advantages makes it worth while. Because alumina is insoluble in silicate glasses, however, it must usually be added as an alkali source in soda-lime-silicates (SLSs) and borosilicates as an alkaline source to raise melting temperatures while improving physical slurry properties such as suspension adhesion shrinkage control, as well as help with sintering.

Alumina ceramics, which are highly thermal and chemical resistant insulating materials, have numerous applications across a range of fields – such as optical lenses and windows, night vision devices, nose cones for heat-seeking missiles and body armor with UHMWPE backing to offer sufficient ballistic protection from rifle threats. Alumina ceramics also play a key role in some body armor designs; their combination with aramid fiber backing offers sufficient ballistic protection.

Alumina can be utilized in many different products, including refractories, ceramics and abrasives. Alumina is one of the most frequently produced forms of aluminium oxide in industrial manufacturing with over 115 million tonnes produced every year. Alumina also serves as raw material in many metallurgical processes as well as chemical industry uses including producing lubricants polishing compounds and glass production.

Tampere University of Technology researchers in Finland have successfully synthesized microscopic films of alumina that are highly flexible, stretching by as much as 8% before breaking. This figure dwarfs silica’s 2-2% stretchability limit and proves that alumina is significantly more ductile than previously believed.

It’s ductile

Contrasting with silica glass’s brittle qualities, alumina glass boasts high ductility. This can be attributed to its higher concentration of aluminum oxide which makes it more flexible. Furthermore, its lower melting point than silica makes working with it simpler, and makes shaping alumina into various shapes an integral aspect of glass manufacturing.

Alumina glass has many applications in aerospace materials and glass-ceramics. It possesses unique properties, including low coefficient of expansion and high tensile strength; good chemical resistance; extreme hardness; optical transparency and low electric conductivity – features which make the material popularly used in aircraft windows/car windshields/night vision devices/nose cones of heat-seeking missiles.

Glass can be processed into numerous products, from containers and bottles to insulators and thin film coatings. It can also be melted to form thick slabs or thin film coatings; and even blown into tubes for fiber optic communication networks and solar cell applications. Alumina also finds use as part of ceramic refractories or polishing materials, as an abrasive substance or even fire retardants.

Glass-making is an intricate process. Ingredients must be selected carefully in order to produce an ideal mixture of refractory and non-refractory components. Sand used to form glass must contain appropriate percentages of magnesia, silica, titania or zinc. Alkali and soda must also be in appropriate proportions as these additions can affect melting temperature and viscosity; consequently affecting its ductility.

Researchers once believed that glass’s chemical composition determined whether it would be brittle or ductile; however, recent experiments have demonstrated otherwise. According to Erkka Frankberg at Tampere University of Technology in Finland and his colleagues, structure plays a more pivotal role. They discovered alumina glass can be flexible under unrestrained loading conditions; this finding could aid scientists in creating flexible glasses which don’t shatter on impact.

It’s amorphous

Alumina glass is an amorphous type of glass created from aluminosilicates containing aluminum oxide. Alumina glass is an extremely tough material and can withstand significant strain. This toughness is due to its unique atomic structure that dissipates energy through reforming bonds rather than cracking, unlike silica which contains gaps that prevent its atoms from shifting when stress hits.

Amorphous alumina is hard to produce, and scientists have struggled to comprehend its physical properties. Yet molecular dynamics simulations provide a powerful way of studying its structures and properties; molecular dynamics simulations allow scientists to study these features with great detail – including vibrational analysis of cation groups within its structures as well as stability issues that arise during glass-forming processes – providing essential insight into why such substances exhibit exceptional ductility.

Raman spectroscopy can provide another useful method for characterizing alumina. It reveals the formation of crystalline phases within glass-ceramics and sheds light onto their use as network modifiers and charge compensators, changes in polymerization degree, phase separation occurrences as well as water distribution within aluminosilicate glasses.

Alumina FTIR spectra range from 380 to 630 cm-1 depending on its phase and preparation method, with peak wavelengths indicative of threefold-coordinated oxygen ions or out-of-plane motions in its molecules having an influence over mechanical properties.

Researchers have developed an innovative process for mass producing microscopic alumina films. Based on anodizing aluminum in acidic solutions, this technique allows them to anodize it with different chemical compositions, pore sizes, and microstructures for different chemical applications; from decorative coloration to shatterproof screens.

Porous anodic alumina is an indispensable material in both nanotechnology and glass science applications, providing precise atomically precise models for glass transition. By changing electrolyte species and voltage, its atomistic properties can be identified and studied further.