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• 2. Evidence of rutile-to-anatase photo-induced electron transfer in mixed-phase TiO2 by solid-state NMR spectroscopy?
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• 3. Dissociative electron attachment to HGaF4 Lewis–Br?nsted superacid
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• 4. EWOD-driven droplet microfluidic device integrated with optoelectronic tweezers as an automated platform for cellular isolation and analysis?
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• 5. Evolution and characterization of a benzylguanine-binding RNA aptamer?
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Trichlorooxobis(triphenylphosphine)-rhenium (CAS No. 17442-18-1): Properties, Applications, and Research Insights

Trichlorooxobis(triphenylphosphine)-rhenium (CAS No. 17442-18-1) is a highly specialized organometallic compound that has garnered significant attention in both academic and industrial research. This compound, often abbreviated as ReOCl3(PPh3)2, features a central rhenium atom coordinated with three chlorine atoms, one oxo group, and two triphenylphosphine ligands. Its unique structure makes it a valuable candidate for various catalytic and material science applications.

The chemical properties of Trichlorooxobis(triphenylphosphine)-rhenium are characterized by its stability under ambient conditions and its reactivity in specific chemical environments. The compound is typically a yellow to orange crystalline solid, soluble in organic solvents such as dichloromethane and toluene. Its molecular weight is approximately 792.18 g/mol, and it exhibits a distinct infrared spectrum due to the presence of the Re=O bond, which is a key feature in its identification and characterization.

One of the most prominent applications of ReOCl3(PPh3)2 is in the field of homogeneous catalysis. Researchers have explored its use in oxidation reactions, where the rhenium center acts as a catalyst to facilitate the transfer of oxygen atoms. This property is particularly relevant in the synthesis of fine chemicals and pharmaceuticals, where selective oxidation is a critical step. Additionally, the compound's ability to undergo ligand exchange reactions makes it a versatile tool in the development of new catalytic systems.

In recent years, the demand for sustainable and green chemistry solutions has driven interest in Trichlorooxobis(triphenylphosphine)-rhenium as a potential catalyst for environmentally friendly processes. For instance, its use in the epoxidation of alkenes has been investigated as a greener alternative to traditional methods that rely on hazardous oxidants. This aligns with the growing trend of eco-friendly chemical synthesis, a topic frequently searched by professionals in the field.

The material science community has also shown interest in ReOCl3(PPh3)2 due to its potential in the development of advanced materials. Its ability to form complexes with other ligands allows for the design of novel materials with tailored electronic and optical properties. This has implications for applications such as organic light-emitting diodes (OLEDs) and molecular sensors, areas that are currently trending in scientific literature and online searches.

From a synthetic chemistry perspective, the preparation of Trichlorooxobis(triphenylphosphine)-rhenium involves the reaction of rhenium pentachloride with triphenylphosphine in the presence of a reducing agent. The process requires careful control of reaction conditions to ensure high yield and purity. Detailed protocols for its synthesis are often sought after by researchers, making this a relevant topic for inclusion in professional discussions.

The market dynamics for ReOCl3(PPh3)2 are influenced by its niche applications and the limited number of suppliers. As a result, it is considered a high-value compound, often used in small quantities for specialized research. The growing interest in rhenium-based catalysts and materials has led to increased demand, prompting suppliers to expand their production capabilities. This trend is reflected in the rising number of online queries related to the purchasing and sourcing of this compound.

In conclusion, Trichlorooxobis(triphenylphosphine)-rhenium (CAS No. 17442-18-1) is a versatile and valuable compound with significant potential in catalysis and material science. Its unique properties and applications make it a subject of ongoing research and commercial interest. As the scientific community continues to explore sustainable and innovative solutions, compounds like ReOCl3(PPh3)2 will undoubtedly play a pivotal role in shaping the future of chemistry.

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