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  Gergana M. Radulova,Krassimir D. Danov,Peter A. Kralchevsky,Jordan T. Petkov,Simeon D. Stoyanov Soft Matter 2014 10 5777
• 2. Influence of Mg/CTAB ratio on the structural, physicochemical properties and catalytic activity of amorphous mesoporous magnesium silicate catalysts
  Kok-Hou Tan,Anwar Iqbal,Farook Adam,N. H. H. Abu Bakar,M. N. Ahmad,Rahimi M. Yusop,Hariy Pauzi RSC Adv. 2019 9 38760
• 3. Influence of Mg/CTAB ratio on the structural, physicochemical properties and catalytic activity of amorphous mesoporous magnesium silicate catalysts
  Kok-Hou Tan,Anwar Iqbal,Farook Adam,N. H. H. Abu Bakar,M. N. Ahmad,Rahimi M. Yusop,Hariy Pauzi RSC Adv. 2019 9 38760
• 4. Two-dimensional lamellar magnesium silicate with large spacing as an excellent adsorbent for uranium immobilization
  Weixue Wang,Zhe Chen,Haijiang Zhou,Yifei Zhang,Xiangke Wang Environ. Sci.: Nano 2018 5 2406
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• Catalysts and Inorganic Chemicals Inorganic Compounds Mixed metal/non-metal compounds Alkaline earth metal oxoanionic compounds Alkaline earth metal silicates
• Material Chemicals High Polymer Materials

Magnesium Silicate and Its Applications in Modern Science and Industry

Magnesium silicate, a compound with the CAS number 1343-88-0, is a versatile material with significant applications across various scientific and industrial domains. This inorganic compound, also known as magnesium silicate or magnesium oxide silicate, has garnered considerable attention due to its unique chemical properties and broad utility. The increasing research interest in Magnesium Silicate is driven by its potential in enhancing material performance, environmental sustainability, and innovative technological solutions.

The chemical structure of Magnesium Silicate (CAS no. 1343-88-0) consists of magnesium ions (Mg2?) bonded to silicate anions (SiO???). This arrangement imparts exceptional thermal stability and chemical resistance, making it an ideal candidate for high-temperature applications. Recent studies have highlighted the compound's role in developing advanced refractory materials, which are crucial in industries such as aerospace and metallurgy. The ability of Magnesium Silicate to withstand extreme temperatures without degradation has opened new avenues for material engineering.

In the field of environmental science, Magnesium Silicate has been extensively studied for its potential in water treatment and soil remediation. Its adsorbent properties make it highly effective in removing heavy metals and organic pollutants from wastewater. A groundbreaking study published in 2022 demonstrated that Magnesium Silicate nanoparticles could significantly enhance the efficiency of water purification systems by up to 40%. This discovery underscores the compound's importance in addressing global water scarcity and pollution issues.

The medical and pharmaceutical industries have also explored the applications of Magnesium Silicate. Its biocompatibility and non-toxic nature make it suitable for use as a drug delivery agent and wound dressing material. Research indicates that Magnesium Silicate can improve the controlled release of pharmaceutical compounds, leading to more effective treatments for chronic diseases. Additionally, its ability to promote tissue regeneration has sparked interest in its potential use in regenerative medicine.

Another emerging application of Magnesium Silicate is in the realm of energy storage. Recent advancements have shown that this compound can be used to develop high-performance electrodes for lithium-ion batteries. The unique crystalline structure of Magnesium Silicate allows for efficient ion conductivity, which enhances battery life and charging efficiency. This innovation could revolutionize the energy storage industry, contributing to the development of sustainable energy solutions.

The construction industry has also benefited from the use of Magnesium Silicate. Its properties as a fire retardant and thermal insulator make it an excellent additive for fire-resistant coatings and building materials. Studies have shown that incorporating Magnesium Silicate into construction materials can significantly improve their fire resistance while maintaining structural integrity. This application aligns with global efforts to create safer and more sustainable buildings.

In conclusion, the multifaceted applications of Magnesium Silicate (CAS no. 1343-88-0) highlight its importance in modern science and industry. From environmental remediation to medical advancements and energy storage, this compound continues to be a subject of intense research and innovation. As scientists uncover new ways to harness its potential, the impact of Magnesium Silicate on various sectors is expected to grow even further, driving progress towards a more sustainable future.

• 14483-19-3(Diopside)
• 12174-11-7(Attapulgite)
• 14378-12-2(Steatite (Mg3H2(SiO3)4)(9CI))
• 12765-06-9(Silicic acid, calciummagnesium salt)
• 15702-53-1(Silicic acid (H6Si2O7),magnesium salt (1:3))
• 1327-43-1(Aluminum magnesium silicate)
• 16127-62-1(Silicic acid (H2SiO3),iron(2+) magnesium salt (16:11:3) (9CI))
• 10101-39-0(Calcium metasilicate)
• 102110-35-0(Silicic acid, calcium magnesium salt, cerium-doped)
• 101659-01-2(Silicic acid, magnesiumsodium salt)