High Purity 9-Fluorenylmethanol: A Versatile Intermediate for Pharmaceutical and Materials Science Applications
Unlock innovation with our high-purity 9-Fluorenylmethanol, a crucial building block for advanced chemical synthesis.
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9-Fluorenylmethanol
9-Fluorenylmethanol (CAS: 24324-17-2) is a highly pure white crystalline powder essential for various chemical applications. Its primary use as a pharmaceutical intermediate facilitates the development of new drugs, while its versatile reactivity makes it a key component in organic synthesis and chiral catalysis. This compound is instrumental in creating enantiomerically pure compounds crucial for drug efficacy and safety.
- Leverage its role as a pharmaceutical intermediate for new drug development, contributing to breakthroughs in healthcare.
- Utilize 9-fluorenylmethanol for chiral catalysis to produce enantiomerically pure compounds, vital for pharmaceutical efficacy.
- Explore the application of 9-fluorenylmethanol in organic synthesis for creating complex molecules across various industries.
- Discover its utility in polymer science for manufacturing high-performance materials with enhanced thermal and mechanical properties.
Key Advantages
Exceptional Purity
Achieve reliable results with our high-purity 98% white crystalline powder, ensuring consistent performance in sensitive reactions, supporting 9-fluorenylmethanol pharmaceutical intermediate needs.
Versatile Applications
From pharmaceutical synthesis to advanced polymer development, this compound offers broad utility, enabling innovation across diverse scientific fields by supporting organic synthesis.
Quality Assurance
Benefit from stringent quality control, with certifications like ISO, GMP, and FDA, guaranteeing the reliability and safety of our product for your research and manufacturing processes.
Key Applications
Pharmaceutical Synthesis
As a key pharmaceutical intermediate, it aids in the synthesis of active pharmaceutical ingredients (APIs), crucial for producing life-saving medications and advancing drug discovery.
Organic Synthesis
Its reactive nature makes it invaluable in organic chemistry for building complex molecular structures, serving as a critical building block for fine chemicals.
Chiral Catalysis
Employed as a chiral auxiliary, it enables the selective production of specific stereoisomers, which is vital for the development of enantiomerically pure drugs.
Materials Science
Its incorporation into polymers can lead to the development of advanced materials with tailored properties, impacting fields from electronics to high-performance coatings.