9,9-Dimethylxanthene CAS 19814-75-6: A Versatile Intermediate for Organic Synthesis and Advanced Materials
Unlock new possibilities in chemical synthesis and material innovation with 9,9-Dimethylxanthene, a premium intermediate from a trusted supplier in China. Discover its broad applications and exceptional quality.
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9,9-Dimethylxanthene
9,9-Dimethylxanthene is a critical organic intermediate renowned for its unique tricyclic structure and valuable properties. As a leading manufacturer in China, we provide this compound that serves as an indispensable building block in advanced organic synthesis. Its versatility makes it essential for creating complex molecular architectures with precision, supporting breakthroughs in catalysis and the development of novel materials.
- As a key component in organic synthesis, 9,9-dimethylxanthene derivatives are crucial for innovation in organic synthesis.
- The unique structural features of 9,9-dimethylxanthene make it ideal for use in catalysis, as highlighted by its downstream product, Xantphos.
- This compound is a vital pharmaceutical intermediate, contributing to the synthesis of biologically active compounds and drug discovery programs.
- Explore the diverse applications of 9,9-dimethylxanthene in advanced materials, including its use in developing fluorescent probes and for organic synthesis.
Advantages Brought by the Product
High Purity and Quality
We ensure exceptional purity, meeting the stringent requirements for pharmaceutical intermediates and advanced organic synthesis, making it a reliable choice for your research.
Versatile Building Block
Utilize 9,9-dimethylxanthene as a cornerstone in complex molecular architecture, enabling precise and efficient creation of novel compounds.
Broad Application Spectrum
From catalysis to material science and pharmaceuticals, this compound offers a wide range of applications, supporting innovation across industries.
Key Applications
Organic Synthesis
Serve as a fundamental building block in the synthesis of complex organic molecules, driving progress in various chemical research fields.
Catalysis
Its derivatives, like Xantphos, are crucial as ligands in transition metal catalysis, widely used in palladium-catalyzed coupling reactions.
Material Science
Applications include the development of fluorescent probes, OLED materials, and components for photovoltaic cells, pushing the boundaries of material innovation.
Pharmaceuticals
Act as a scaffold for biologically active compounds, contributing to improved binding affinities and pharmacokinetic properties in drug discovery.