Understanding (R)-(+)-N,N-Dimethyl-1-ferrocenylethylamine: A Key Pharmaceutical Intermediate
Explore the chemical properties, diverse applications, and significance of this chiral ferrocene derivative in modern chemistry.
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(R)-1-(Dimethylamino)ethyl]ferrocene
This chiral organometallic compound, identified by CAS number 31886-58-5, plays a crucial role in various chemical and pharmaceutical processes. Its unique structure, featuring a ferrocene group attached to an ethylamine moiety, lends it distinctive chemical properties. As a versatile pharmaceutical intermediate, it is integral to the synthesis of complex organic molecules and advanced materials.
- Leverage the unique structure of ferrocene derivatives for innovative chemical research, exploring new reaction pathways and methodologies.
- Utilize this compound as a key intermediate in the synthesis of chiral drugs, contributing to advancements in the pharmaceutical industry and drug discovery.
- Explore potential applications in material science, where its properties could be harnessed to develop novel materials like chiral catalysts or enantioselective sensors.
- Benefit from the detailed chemical properties and specifications, including its brown liquid appearance and molecular formula C14H19FeN, aiding in precise application.
Key Advantages
Enhanced Chiral Synthesis
The inherent chirality of (R)-(+)-N,N-Dimethyl-1-ferrocenylethylamine makes it an indispensable reactant in the preparation of chiral N-phosphoryl y-aminoboronates, crucial for stereochemistry-dependent biological activities.
Drug Discovery Advancement
Its role as a key intermediate in the synthesis of chiral drugs positions it as a valuable asset in drug discovery and development, enabling the creation of novel drugs with improved efficacy and selectivity.
Versatility in Chemical Research
This compound serves as a starting material in chemical research for synthesizing various complex organic molecules, supporting the development of new chemical reactions and methodologies.
Key Applications
Pharmaceutical Intermediate Synthesis
A critical building block for the synthesis of various active pharmaceutical ingredients (APIs), particularly those requiring chiral specificity.
Chiral Catalysis
Used in developing chiral catalysts for asymmetric synthesis, enabling enantioselective transformations in organic chemistry.
Material Science
Explored for potential uses in advanced materials, such as enantioselective sensors and functionalized nanoparticles.
Organic Chemistry Research
Serves as a versatile reagent and starting material for synthesizing complex organic molecules and exploring novel synthetic routes.