• 1. Temperature- and frequency-dependent dielectric response and energy-storage performance in high (100)-oriented Sc doped (Na0.85K0.15)0.5Bi0.5TiO3 films
  Yunyi Wu,Yonghong Hu,Xiaohui Wang,Caifu Zhong,Longtu Li RSC Adv. 2017 7 51485
• 2. Electrical properties of sol–gel derived MPB 0.37BiScO3–0.63PbTiO3 thin films deposited on iridium oxide electrodes
  Jingzhong Xiao,Aiying Wu,Paula M. Vilarinho,A. R. Ramos,E. Alves J. Mater. Chem. 2009 19 5572
• 3. MFM-300(Sc): a chemically stable Sc(iii)-based MOF material for multiple applications
  Valeria B. López-Cervantes,Juan L. Obeso,Ana Ya?ez-Aulestia,Alejandro Islas-Jácome,Carolina Leyva,Eduardo González-Zamora,Elí Sánchez-González,Ilich A. Ibarra Chem. Commun. 2023 59 10343
• 4. Sc(iii)-Based metal–organic frameworks
  Nishesh Kumar Gupta,Génesis Osorio-Toribio,Magali Hernández,Edmundo G. Percástegui,Enrique Lima,Ilich A. Ibarra Chem. Commun. 2022 58 4116
• 5. Thickness- and temperature-dependent structural and electromechanical properties of (100)-oriented Sc-doped (Na0.85K0.15)0.5Bi0.5TiO3 ferroelectric films
  Yunyi Wu,Yonghong Hu,Xiaohui Wang,Caifu Zhong,Longtu Li RSC Adv. 2017 7 44136

• Solvents and Organic Chemicals Organic Compounds Organic acids and derivatives Carboxylic acids and derivatives Carboxylic acids

Professional Introduction to Scandium Acetate (CAS No. 3804-23-7)

Scandium acetate, chemically identified by the CAS number 3804-23-7, is a versatile compound that has garnered significant attention in the field of chemical and pharmaceutical research. This coordination compound, featuring the scandium(III) cation coordinated with acetate anions, exhibits unique properties that make it valuable in various applications, from catalysis to material science. The growing interest in Scandium acetate is largely driven by its role in advancing innovative technologies and its potential in addressing contemporary scientific challenges.

The chemical structure of scandium acetate can be described as a coordination complex where the scandium(III) ion, Sc3?, is surrounded by acetate ions (CH?COO?). This arrangement leads to a stable complex with distinct characteristics. The coordination geometry of scandium in this compound typically follows an octahedral or tetragonal structure, depending on the reaction conditions and ligand environment. Such structural features are crucial for understanding its reactivity and applications in synthetic chemistry.

In recent years, research has highlighted the importance of Scandium acetate in catalytic processes. Its ability to act as a Lewis acid catalyst has been exploited in various organic transformations, including cross-coupling reactions and polymerization processes. For instance, studies have demonstrated its efficacy in facilitating the formation of carbon-carbon bonds under mild conditions, which is highly desirable for green chemistry approaches. The use of scandium-based catalysts has shown promise in reducing the need for hazardous reagents and lowering energy consumption, aligning with global sustainability goals.

Beyond catalysis, Scandium acetate has found applications in material science, particularly in the development of advanced materials with enhanced properties. Its incorporation into metal-organic frameworks (MOFs) has been explored for gas storage and separation applications. The unique size and charge characteristics of scandium ions allow them to interact with guest molecules in a controlled manner, making MOFs functional for specific industrial needs. Additionally, scandium-doped materials have shown improved luminescent properties, which are valuable in optoelectronic devices.

The pharmaceutical industry has also shown interest in Scandium acetate due to its potential biological activities. While not widely used as a therapeutic agent itself, scandium complexes have been studied for their ability to modulate biological processes. For example, research suggests that certain scandium compounds may exhibit anti-inflammatory properties by interacting with cellular pathways. However, further studies are needed to fully understand their safety and efficacy before any clinical applications can be considered.

The synthesis of Scandium acetate typically involves the reaction of scandium salts with acetic acid or sodium acetate under controlled conditions. The purity of the final product is crucial for its intended applications, necessitating careful purification steps such as recrystallization or column chromatography. Advances in synthetic methodologies have improved the yield and purity of scandium acetate, making it more accessible for research and industrial use.

The environmental impact of using Scandium acetate is another consideration that has been addressed in recent studies. While scandium is not classified as a toxic metal, its accumulation in ecosystems could pose risks if not managed properly. Efforts are being made to develop sustainable methods for its extraction and utilization to minimize environmental footprint. For instance, recycling strategies are being explored to recover scandium from spent materials, ensuring a more circular economy approach.

In conclusion, Scandium acetate (CAS No. 3804-23-7) is a multifaceted compound with significant potential across multiple scientific disciplines. Its role in catalysis, material science, and pharmaceutical research underscores its importance as a chemical building block for innovation. As research continues to uncover new applications and refine synthetic techniques, the utility of scandium acetate is expected to expand further, contributing to advancements that benefit society and the environment.

• 15417-46-6(Chromium, bis(acetato-kO)hydroxy-)
• 2845-03-6(Acetic-1-14C acid(6CI,7CI,8CI,9CI))
• 17217-83-3(Acetic-18O2 acid(6CI,8CI,9CI))
• 1066-30-4(Chromium(III) acetate)
• 17593-70-3(Acetic acid, chromiumsalt (8CI,9CI))
• 107745-70-0(Acetic Acid-13C2, D3)
• 119510-26-8(VoSol (9CI))
• 1112-02-3(Acetic-2,2,2-d3 Acid)
• 25013-82-5(Acetic acid,chromium(3+) salt, monohydrate (8CI,9CI))
• 285977-76-6(Acetic-2-13C-2,2,2-d3acid-d (9CI))