2,4-Difluoroiodobenzene: Your Key to Advanced Organic Synthesis
Unlock complex molecular structures with this essential fluorinated aromatic building block.
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2,4-Difluoroiodobenzene
A crucial intermediate in modern organic synthesis, 2,4-Difluoroiodobenzene (CAS 2265-93-2) is a versatile compound valued for its unique combination of fluorine and iodine substituents on a benzene ring. This chemical intermediate is instrumental in constructing complex organic molecules, facilitating advancements in pharmaceuticals, materials science, and specialty chemicals.
- Leverage this compound for the synthesis of 1,2,4-tris(1H-pyrazolyl)benzene, a critical step often involving reactions with pyrazole under specific catalytic conditions.
- Explore its utility as a versatile building block in organic synthesis, enabling the creation of intricate molecular architectures with precision.
- Benefit from its high purity (typically 98%+) for reliable and reproducible synthetic outcomes in your research and development.
- Utilize this aryl halide in the preparation of key derivatives like 3-(2,4-difluorophenyl)-2-propyn-1-ol and other specialized compounds.
Key Advantages
Synthetic Versatility
As a prime chemical intermediate, 2,4-Difluoroiodobenzene offers diverse reaction pathways, making it invaluable for crafting novel compounds essential for various industries.
Fluorine Chemistry
The presence of fluorine atoms imparts unique electronic and physical properties, crucial for developing advanced materials and pharmaceuticals, highlighting its role in fluorinated aromatic intermediates.
Reliable Sourcing
Access a consistent supply of this compound for your research, ensuring that your projects, from lab-scale to pilot production, are well-supported.
Key Applications
Pharmaceutical Synthesis
This compound is a vital component in the advanced pharmaceutical synthesis of drug candidates and active pharmaceutical ingredients (APIs).
Materials Science
Its unique structure makes it suitable for developing novel materials, particularly in areas like OLEDs and other photoelectric applications, showcasing its role in specialty organic building blocks.
Agrochemical Development
The fluorinated nature of this molecule can contribute to the efficacy and stability of new agrochemical compounds.
Research & Development
Serves as a fundamental building block for academic and industrial research, enabling exploration of new chemical reactions and compound libraries.