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• 2. Phase evolution in lithium disilicate glass–ceramics based on non-stoichiometric compositions of a multi-component system: structural studies by 29Si single and double resonance solid state NMR
  Christine Bischoff,Hellmut Eckert,Elke Apel,Volker M. Rheinberger,Wolfram H?land Phys. Chem. Chem. Phys. 2011 13 4540
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• Catalysts and Inorganic Chemicals Inorganic Compounds Mixed metal/non-metal compounds Alkali metal oxoanionic compounds Alkali metal silicates
• Catalysts and Inorganic Chemicals Inorganic Compounds Salt
• Catalysts and Inorganic Chemicals Inorganic Compounds

Lithium Metasilicate: A Comprehensive Overview

Lithium metasilicate, also known as CAS No. 10102-24-6, is a versatile compound with significant applications in various industries. This compound, represented by the chemical formula LiSiO?, is a lithium silicate with unique properties that make it highly valuable in fields such as ceramics, glass production, and electronics. The compound is synthesized through a series of chemical reactions involving lithium compounds and silicates, resulting in a stable and reactive material.

One of the key features of lithium metasilicate is its ability to act as a fluxing agent in high-temperature processes. This property has been extensively studied in recent research, where scientists have explored its role in improving the melting behavior of glass and ceramic formulations. For instance, a 2023 study published in the Journal of Materials Science highlighted how lithium metasilicate can reduce the melting point of glass without compromising its mechanical properties. This finding has significant implications for the glass manufacturing industry, where energy efficiency and cost reduction are critical concerns.

In addition to its role in glass production, lithium metasilicate has gained attention for its potential in advanced ceramics. Researchers have found that incorporating lithium metasilicate into ceramic formulations can enhance their thermal stability and mechanical strength. A 2023 paper in the Ceramic Engineering International journal demonstrated that lithium metasilicate-based ceramics exhibit superior resistance to thermal shock, making them ideal for use in high-temperature applications such as aerospace components and industrial furnaces.

The synthesis of lithium metasilicate has also been a topic of recent research. Traditionally, the compound is produced through solid-state reactions involving lithium carbonate (Li?CO?) and silicon dioxide (SiO?). However, recent studies have explored alternative methods, such as sol-gel synthesis and hydrothermal processing, to produce lithium metasilicate with improved purity and particle size distribution. These advancements have opened new avenues for its application in nanotechnology and electronic materials.

Another area where lithium metasilicate has shown promise is in the field of catalysis. Researchers have investigated its potential as a catalyst support due to its high surface area and chemical stability. A 2023 study published in Applied Catalysis B: Environmental demonstrated that lithium metasilicate-based catalysts can effectively degrade organic pollutants under UV light irradiation, offering a sustainable solution for water purification.

Moreover, lithium metasilicate has been explored for its role in energy storage technologies. Recent research has focused on its application as an electrolyte additive in lithium-ion batteries. Studies have shown that incorporating lithium metasilicate into battery electrolytes can improve ion conductivity and enhance the overall performance of the battery system.

In terms of environmental applications, lithium metasilicate has been studied for its ability to sequester heavy metals from contaminated water. A 2023 paper in Environmental Science & Technology reported that lithium metasilicate can effectively adsorb heavy metal ions such as lead (Pb2?) and cadmium (Cd2?), making it a promising material for water treatment applications.

Despite its numerous advantages, the use of lithium metasilicate is not without challenges. One major concern is its limited availability and high production costs. Researchers are currently exploring ways to optimize its synthesis process to make it more cost-effective and scalable for industrial applications.

In conclusion, lithium metasilicate (CAS No. 10102-24-6) is a multifaceted compound with a wide range of applications across various industries. Its unique chemical properties and versatility make it an invaluable material for advancing technologies in ceramics, glass production, catalysis, energy storage, and environmental remediation. As research continues to uncover new potential uses for this compound, it is expected to play an even more significant role in shaping future innovations.

• 1343-98-2(Silicic acid)
• 12627-14-4(Silicic acid, lithiumsalt)
• 12068-40-5(Silicic acid (H2SiO3),aluminum lithium salt (2:1:1))
• 7699-41-4(Metasilicic acid)
• 1344-96-3(CALCIUM SILICATE HYDRATE)
• 13983-17-0(Calcium metasilicate)
• 15593-90-5(Silicate (SiO32-)(8CI,9CI))
• 1319-31-9(Tobermorite(Ca5H2(SiO3)6.4H2O))
• 10279-57-9(Silica glass)
• 12627-13-3(Silicate)