Diethyl Allylphosphonate (CAS 1067-87-4) is a chemical compound that garners significant attention due to its straightforward synthesis routes and a broad spectrum of applications across various scientific and industrial domains. Understanding how this organophosphorus compound is synthesized and where it finds its utility provides valuable insights for researchers and manufacturers looking to procure or utilize this versatile chemical.

The synthesis of Diethyl Allylphosphonate is commonly achieved through reactions like the Michaelis-Arbuzov synthesis. A typical procedure involves reacting triethyl phosphite with allyl bromide under controlled heating conditions. This method, well-documented and refined over time, allows for the efficient production of Diethyl Allylphosphonate, often with high yields and purity, such as u226598% GC. The availability of detailed synthesis protocols from chemical literature and supplier documentation aids in its reproduction and large-scale production. For those looking to buy, understanding these synthesis details can inform quality assessment.

The applications of Diethyl Allylphosphonate are as diverse as the fields it serves. In organic synthesis, it functions as a key reagent for forming carbon-carbon bonds and in various coupling reactions. Its ability to participate in copolymerization makes it valuable for creating advanced polymer materials with tailored properties. The price point and availability from chemical suppliers, particularly those based in China, make it an accessible component for both laboratory-scale research and industrial manufacturing.

Furthermore, its utility extends to critical sectors like agrochemicals and pharmaceuticals. As an intermediate, it aids in the development of pesticides, herbicides, and complex pharmaceutical molecules, contributing to advancements in agriculture and medicine. The specific chemical properties of Diethyl Allylphosphonate, such as its boiling point and density, are well-characterized, facilitating its integration into established synthesis workflows.

Its role in creating phosphonated polymers, enhancing flame retardancy and thermal stability, is another significant application. These improved materials are crucial for safety and performance in industries ranging from construction to electronics. The consistent supply of Diethyl Allylphosphonate from manufacturers ensures that these material advancements can be realized efficiently. For any chemical procurement needs, considering the established synthesis methods and diverse applications of this compound is a wise approach.