PI13667 Trimethylsulfoxonium bromide (CAS No.: 25596-24-1)

Trimethylsulfoxonium bromide Description

Trimethylsulfoxonium bromide (C3H9BrOS) is utilised in organic synthesis as a precursor for ylide formation, facilitating epoxidation and cyclopropanation reactions. Its formulation as a powder with high chemical purity ensures controlled reactivity, making it suitable for precise reagent applications. The compound has a defined molecular weight and consistent batch characteristics vital for reproducible laboratory processes.

Trimethylsulfoxonium bromide Characteristics

*The above product information is based on theoretical data and is for reference only. Actual specifications may vary.

Trimethylsulfoxonium bromide Applications

Organic Synthesis
- Used as a ylide precursor in the Corey–Chaykovsky reaction to initiate epoxidation, enabling controlled formation of oxygenated cyclic compounds by leveraging its defined reactivity.
- Applied as a cyclopropanation reagent in the synthesis of carbocycles, offering predictable performance for structural modifications.

Pharmaceutical Research
- Serves as a reagent in the synthesis of bioactive molecules, aiding in the construction of complex molecular frameworks with high specificity, which benefits optimisation in drug development.

Trimethylsulfoxonium bromide Packing

Trimethylsulfoxonium bromide is packaged in sealed, moisture-resistant vials to prevent contamination and exposure to humidity. The packaging includes secondary protection such as inert liners to maintain reagent stability. Storage recommendations call for an ambient, temperature-controlled environment. Custom packaging solutions, including bulk and labelled options, are available for specific laboratory or industrial requirements.

Additional Information

Sulfoxonium salts, including trimethylsulfoxonium bromide, are widely recognised in synthetic organic chemistry for their role as stable ylide sources. Their reactivity in forming new carbon–carbon bonds allows chemists to construct complex architectures efficiently. The compound's defined physical and chemical parameters play a crucial role in achieving reproducible reactions.

Understanding the synthesis and handling of such reagents is integral to advancing organic methodologies. Detailed quality control measures, including chromatographic and spectroscopic techniques, are often employed to ensure batch consistency, which is essential for both academic research and industrial applications.